The ABB IRB 6600 - 175/2.55 is a powerful industrial robot designed for various applications, including spot welding, material handling, and machine tending. It boasts a 175 kg payload capacity with a 2.55-meter reach, making it ideal for handling heavy parts. The robot is equipped with the BaseWare OS, ensuring comprehensive control over motion, programming, and communication features. It also offers various safety features, such as Active Brake System and Electronically Stabilised Path, ensuring safe operation and protecting personnel and equipment.
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Product Manual Industrial Robot IRB 6600 - 225/2.55 IRB 6600 - 175/2.8 IRB 6600 - 175/2.55 IRB 6650 - 200/2.75 IRB 6650 - 125/3.2 M2000A Product Specification 3HAC 14064-1/M2000/Rev 2 IRB 6600 - 175/2.55 IRB 6600 - 225/2.55 IRB 6600 - 175/2.8 IRB 6650 - 125/3.2 IRB 6650 - 200/2.75 The information in this document is subject to change without notice and should not be construed as a commitment by ABB Automation Technology Products AB, Robotics. ABB Automation Technology Products AB, Robotics assumes no responsibility for any errors that may appear in this document. In no event shall ABB Automation Technology Products AB, Robotics be liable for incidental or consequential damages arising from use of this document or of the software and hardware described in this document. This document and parts thereof must not be reproduced or copied without ABB Automation Technology Products AB, Robotics’s written permission, and contents thereof must not be imparted to a third party nor be used for any unauthorized purpose. Contravention will be prosecuted. Additional copies of this document may be obtained from ABB Automation Technology Products AB, Robotics at its then current charge. © Copyright 2001 ABB. All rights reserved. Article number: 3HAC 14064-1 Issue: M2000/Rev. 2 ABB Automation Technology Products AB Robotics SE-721 68 Västerås Sweden Product Specification IRB 6600 CONTENTS Page 1 Description ....................................................................................................................... 3 1.1 Structure.................................................................................................................. 3 Different robot versions ......................................................................................... 4 Definition of version designation........................................................................... 4 1.2 Safety/Standards ..................................................................................................... 6 1.3 Installation .............................................................................................................. 10 External Mains Transformer .................................................................................. 10 Operating requirements.......................................................................................... 10 Mounting the manipulator...................................................................................... 10 1.4 Load diagrams ........................................................................................................ 13 Maximum load and moment of inertia for full and limited axis 5 (centre line down) movement......................................................................... 24 Mounting equipment .............................................................................................. 25 Holes for mounting extra equipment ..................................................................... 26 1.5 Maintenance and Troubleshooting ......................................................................... 30 1.6 Robot Motion.......................................................................................................... 31 Performance according to ISO 9283...................................................................... 34 Velocity .................................................................................................................. 34 1.7 Cooling fan for axis 1-3 motor (option 113-115) ................................................... 34 1.8 SpotPack and DressPack ........................................................................................ 35 Description of DressPack....................................................................................... 37 Description of Water and Air unit.......................................................................... 39 Description of Power Unit ..................................................................................... 40 1.9 Description of Variants and Options for SpotPack................................................. 41 1.10 Examples of SpotPacks ........................................................................................ 59 1.11 Servo Gun (option) ............................................................................................... 62 1.12 Track Motion ........................................................................................................ 68 2 Specification of Variants and Options........................................................................... 69 3 Accessories ....................................................................................................................... 79 4 Index ................................................................................................................................. 81 Product Specification IRB 6600 M2000 1 Product Specification IRB 6600 2 Product Specification IRB 6600 M2000 Description 1 Description 1.1 Structure A new world of possibilities opens up with ABB’s IRB 6600 robot family. It comes in five versions, 175kg /2.55m, 225kg /2.55 m, 175kg /2.8m, 125kg/3.2m, and 200kg/2.75m handling capacities. The IRB 6600 is ideal for process applications, regardless of industry. Typical areas can be spotwelding, material handling and machine tending. We have added a range of software products - all falling under the umbrella designation of Active Safety - to protect not only personnel in the unlikely event of an accident, but also robot tools, peripheral equipment and the robot itself. The robot is equipped with the operating system BaseWare OS. BaseWare OS controls every aspect of the robot, like motion control, development and execution of application programs, communication etc. See Product Specification S4Cplus. For additional functionality, the robot can be equipped with optional software for application support - for example spot welding, communication features - network communication - and advanced functions such as multi-tasking, sensor control, etc. For a complete description on optional software, see the Product Specification RobotWare Options. Axis 3 Axis 4 Axis 5 Axis 6 Axis 2 Axis 1 Figure 1 The IRB 6600 manipulators have 6 axes. Product Specification IRB 6600 M2000 3 Description Different robot versions The IRB 6600 is available in five versions. The following different robot types are available: Standard: IRB 6600 - 175 kg / 2.55 m IRB 6600 - 225 kg / 2.55 m IRB 6600 - 175 kg / 2.8 m IRB 6650 - 125 kg / 3.2 m IRB 6650 - 200 kg / 2.75 m Definition of version designation IRB 6600 Mounting - Handling capacity / Reach Prefix Description Mounting - Floor-mounted manipulator Handling capacity yyy Indicates the maximum handling capacity (kg) Reach x.x Indicates the maximum reach at wrist centre (m) Manipulator weight IRB 6600-175/2,55 IRB 6600-225/2,55 IRB 6600-175/2,8 IRB 6650-125/3.2 IRB 6650-200/2.75 Airborne noise level: The sound pressure level outside the working space 1700 kg 1700 kg 1700 kg 1725 kg 1700 kg < 73 dB (A) Leq (acc. to Machinery directive 98/37/EEC) Power consumption at max load: ISO Cube: 2.6 kW Normal robot movements: 3.8 kW 4 Product Specification IRB 6600 M2000 Description 1142 IRB 6600-2,55 ; IRB 6650-2.75 1392 IRB 6600-2,8 1592 IRB 6650-3.2 IRB 6600 2445 IRB 6650 2240 IRB 6600 1280 IRB 6650 6600-400/2.55 R 580 R 690 with fork lift Figure 2 View of the manipulator from the side and above (dimensions in mm). Allow 200 mm behind the manipulator foot for cables. Product Specification IRB 6600 M2000 5 Description 1.2 Safety/Standards The robot conforms to the following standards: EN 292-1 Safety of machinery, terminology EN 292-2 Safety of machinery, technical specifications EN 954-1 Safety of machinery, safety related parts of control systems EN 60204 Electrical equipment of industrial machines IEC 204-1 Electrical equipment of industrial machines ISO 10218, EN 775 Manipulating industrial robots, safety ANSI/RIA 15.06/1999 Industrial robots, safety requirements ISO 9787 Manipulating industrial robots, coordinate systems and motions IEC 529 Degrees of protection provided by enclosures EN 50081-2 EMC, Generic emission EN 61000-6-2 EMC, Generic immunity ANSI/UL 1740-1996 (option) Standard for Industrial Robots and Robotic Equipment CAN/CSA Z 434-94 (option) Industrial Robots and Robot Systems - General Safety Requirements The robot complies fully with the health and safety standards specified in the EEC’s Machinery Directives. The Service Information System (SIS) The service information system gathers information about the robot’s usage and by that determines how hard the robot has been used. The usage is characterised by the speed, the rotation angles and the load of every axis. With this data collection, the service interval of every individual robot of this generation can be predicted, optimising and planning ahead service activities. The collection data is available via the teach pendant or the network link to the robot. The Process Robot Generation is designed with absolute safety in mind. It is dedicated to actively or passively avoid collisions and offers the highest level of safety to the operators and the machines as well as the surrounding and attached equipment. These features are presented in the active and passive safety system. The Active Safety System The active safety system includes those software features that maintain the accuracy of the robot’s path and those that actively avoid collisions which can occur if the robot leaves the programmed path accidentally or if an obstacle is put into the robot’s path. The Active Brake System (ABS) All robots run with an active brake system that supports the robots to maintain the programmed path even in an emergency situation. 6 Product Specification IRB 6600 M2000 Description The ABS is active during all stop modes, braking the robot to a stop with the power of the servo drive system along the programmed path. After a specific time the mechanical brakes are activated ensuring a safe stop even in case of a failure of the drive system or a power interruption. The maximal applicable torque on the most loaded axis determines the stopping distance. The stopping process is in accordance with a class 1 stop. While programming the robot in manual mode a class 0 stop, with mechanical brakes only, applies. The Self Tuning Performance (STP) The Process Robot Generation is designed to run at different load configurations, many of which occur within the same program and cycle. The robot’s installed electrical power can thus be exploited to lift heavy loads, create a high axis force or accelerate quickly without changing the configuration of the robot. Consequently the robot can run in a “power mode” or a “speed mode” which can be measured in the respective cycle time of one and the same program but with different tool loads. This feature is based on QuickMoveTM. The respective change in cycle time can be measured by running the robot in NoMotionExecution with different loads or with simulation tools like RobotStudio. The Electronically Stabilised Path (ESP) The load and inertia of the tool have a significant effect on the path performance of a robot. The Process Robot Generation is equipped with a system to electronically stabilise the robot’s path in order to achieve the best path performance. This has an influence while accelerating and braking and consequently stabilises the path during all motion operations with a compromise of the best cycle time. This feature is secured through TrueMoveTM. Over-speed protection The speed of the robot is monitored by two independent computers. Restricting the working space The movement of each axis can be restricted using software limits. As options there are safeguarded space stops for connection of position switches to restrict the working space for the axes 1-3. Axes 1-3 can also be restricted by means of mechanical stops. Collision detection (option) In case an unexpected mechanical disturbance occurs, like a collision, electrode sticking, etc., the robot will detect the collision, stop on the path and slightly back off from its stop position, releasing tension in the tool. The Passive Safety System The Process Robot Generation has a dedicated passive safety system that by hardware construction and dedicated solutions is designed to avoid collisions with surrounding equipment. It integrates the robot system into the surrounding equipment safely. Compact robot arm design The shape of the lower and upper arm system is compact, avoiding interference into the working envelope of the robot. Product Specification IRB 6600 M2000 7 Description The lower arm is shaped inward, giving more space under the upper arm to re-orientate large parts and leaving more working space while reaching over equipment in front of the robot. The rear side of the upper arm is compact, with no components projecting over the edge of the robot base even when the robot is moved into the home position. Moveable mechanical limitation of main axes (option) All main axes can be equipped with moveable mechanical stops, limiting the working range of every axis individually. The mechanical stops are designed to withstand a collision even under full load. Position switches on main axes (option) All main axes can be equipped with position switches. The double circuitry to the cam switches is designed to offer personal safety according to the respective standards. The Internal Safety Concept The internal safety concept of the Process Robot Generation is based on a two-channel circuit that is monitored continuously. If any component fails, the electrical power supplied to the motors shuts off and the brakes engage. Safety category 3 Malfunction of a single component, such as a sticking relay, will be detected at the next MOTOR OFF/MOTOR ON operation. MOTOR ON is then prevented and the faulty section is indicated. This complies with category 3 of EN 954-1, Safety of machinery safety related parts of control systems - Part 1. Selecting the operating mode The robot can be operated either manually or automatically. In manual mode, the robot can only be operated via the teach pendant, i.e. not by any external equipment. Reduced speed In manual mode, the speed is limited to a maximum of 250 mm/s (600 inch/min.). The speed limitation applies not only to the TCP (Tool Centre Point), but to all parts of the robot. It is also possible to monitor the speed of equipment mounted on the robot. Three position enabling device The enabling device on the teach pendant must be used to move the robot when in manual mode. The enabling device consists of a switch with three positions, meaning that all robot movements stop when either the enabling device is pushed fully in, or when it is released completely. This makes the robot safer to operate. Safe manual movement The robot is moved using a joystick instead of the operator having to look at the teach pendant to find the right key. Emergency stop There is one emergency stop push button on the controller and another on the teach pendant. Additional emergency stop buttons can be connected to the robot’s safety chain circuit. Safeguarded space stop The robot has a number of electrical inputs which can be used to connect external safety equipment, such as safety gates and light curtains. This allows the robot’s safety functions to be activated both by peripheral equipment and by the robot itself. 8 Product Specification IRB 6600 M2000 Description Delayed safeguarded space stop A delayed stop gives a smooth stop. The robot stops in the same way as at a normal program stop with no deviation from the programmed path. After approx. 1 second the power supplied to the motors is shut off. Hold-to-run control “Hold-to-run” means that you must depress the start button in order to move the robot. When the button is released the robot will stop. The hold-to-run function makes program testing safer. Fire safety Both the manipulator and control system comply with UL’s (Underwriters Laboratory) tough requirements for fire safety. Safety lamp (option) As an option, the robot can be equipped with a safety lamp mounted on the manipulator. This is activated when the motors are in the MOTORS ON state. Product Specification IRB 6600 M2000 9 Description 1.3 Installation All versions of IRB 6600 are designed for floor mounting. Depending on the robot version, an end effector with max. weight of 175 to 225 kg including payload, can be mounted on the mounting flange (axis 6). See Load diagram for IRB 6600 generation robots on page 14, page 16, page 18, page 20 and page 22. Extra loads (valve packages, transformers) can be mounted on the upper arm with a maximum weight of 50 kg. On all versions an extra load of 500 kg can also be mounted on the frame of axis 1. Holes for mounting extra equipment on page 26. The working range of axes 1-3 can be limited by mechanical stops. Position switches can be supplied on axes 1-3 for position indication of the manipulator. External Mains Transformer The robot system requires a 400 - 475 VAC power supply. Therefore an external transformer will be included when a mains voltage other than 400-475V is selected. Operating requirements Protection standards Standard and Foundry Manipulator IP67 Cleanroom standards Cleanroom class 100 for manipulator according to: • DIN EN ISO 14644: Cleanrooms and associated controlled environments • US Federal Standard 209 e - Air-clean-classes Explosive environments The robot must not be located or operated in an explosive environment. Ambient temperature Manipulator during operation For the controller: standard option +5oC (41oF) to +50oC (122oF) +45oC (113oF) +52oC (126oF) Complete robot during transportation and storage, -25oC (13oF) to +55oC (131oF) for short periods (not exceeding 24 hours) up to +70oC (158oF) Relative humidity Complete robot during transportation and storage Max. 95% at constant temperature Complete robot during operation Max. 95% at constant temperature Mounting the manipulator Maximum load in relation to the base coordinate system. 10 Endurance load in operation Max. load at emergency stop Force xy Force z ±10.1 kN 18.0 ±13.8 kN ±20.7 kN 18.0 ±22.4 kN Torque xy Torque z ±27.6 kNm ±7.4 kNm ±50.6 kNm ±14.4 kNm Product Specification IRB 6600 M2000 88 ± 0.3 Description Recommended screws for fastening the manipulator to a base plate: M24 x 120 8.8 with 4 mm flat washer Torque value 775 Nm Figure 3 Hole configuration (dimensions in mm). Product Specification IRB 6600 M2000 11 Description B 5 325 D B 37,5 o A C 15 o A C o 10 50 522 1 A 0.1 A A-A 1.5 B-B C-C D Two guiding pins required, dimensions see Figure 5 Figure 4 Option Base plate (dimensions in mm). 12 Product Specification IRB 6600 M2000 Description Protected from corrosion Figure 5 Guide sleeve (dimensions in mm) 1.4 Load diagrams The load diagrams include a nominal payload inertia, J0 of 15 kgm2, and an extra load of 50 kg at the upper arm housing, see Figure 6. At different arm load, payload and moment of inertia, the load diagram will be changed. For an accurate load diagram, please use the calculation program, ABBLoad for 6600 on: • inside.abb.com/atrm, click on Products --> Robots --> IRB 6600 or • http://www.abb.com/roboticspartner, click on Product range --> Robots --> IRB 6600. Centre of gravity 50 kg 400 200 Figure 6 Centre of gravity for 50 kg extra load at arm housing (dimensions i mm). Product Specification IRB 6600 M2000 13 Description Load diagram for IRB 6600-175/2.55 0,80 80 kg 0,70 100 kg 0,60 120 kg Z-distance (m) 0,50 135 kg 0,40 150 kg 175 kg 0,30 180 kg 185 kg 0,20 200 mm 0,10 0,00 0,00 0,10 0,10 0,20 0,30 0,40 0,50 L-distance (m ) Figure 7 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity). 14 Product Specification IRB 6600 M2000 Description Load diagram for IRB 6600-175/2.55 “Vertical Wrist” (±10o) L “Vertical wrist” Load diagram "Vertical Wrist" (±10°) 10o 10o IRB 6600 - 175/2.55 Armload: 50kg Z 200 mm L-distance (m) 0,0 0,2 0,20 0,4 0,40 0,6 0,60 Pay load 0,8 0,80 1,0 1,00 1,2 1,20 1,4 1,40 0,0 0,2 0,20 210 kg 190 kg 0,40 0,4 Z-distance (m) 150 kg 0,60 0,6 100 kg 0,80 0,8 75 kg 1,00 1,0 1,20 1,2 1,40 1,4 Figure 8 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity) at “Vertical Wrist” (±10o), J0 =15 kgm2. For wrist down (0o deviation from the vertical line). Max load = 215 kg, Zmax = 0,310m and Lmax = 0,133m Product Specification IRB 6600 M2000 15 Description Load diagram for IRB 6600-225/2.55 0,90 100 kg 0,80 0,70 120 kg 0,60 Z-distance (m) 150 kg 0,50 175 kg 200 kg 0,40 215 kg 220 kg 0,30 225 kg 230 kg 0,20 200 mm 0,10 0,00 0,00 0,10 0,10 0,20 0,20 0,30 0,40 0,50 0,60 L-distance (m) Figure 9 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity). 16 Product Specification IRB 6600 M2000 Description Load diagram for IRB 6600-225/2.55 “Vertical Wrist” (±10o) L “Vertical wrist” Load diagram "Vertical Wrist" (±10°) Pay load 10o 10o IRB 6600 - 225/2.55 Armload: 50kg 200 mm Z L-distance (m) 0,00 0,20 0,40 0,60 0,80 1,00 1,20 1,40 0,00 0,20 260 kg 235 kg 0,40 200 kg Z-distance (m) 0,60 150 kg 0,80 100 kg 1,00 1,20 1,40 1,60 Figure 10 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity) at “Vertical Wrist” (±10o). For wrist down (0o deviation from the vertical line). Max load = 270 kg, Zmax = 0,359m and Lmax = 0,124m Product Specification IRB 6600 M2000 17 Description Load diagram for IRB 6600-175/2.8 1,10 1,00 80 kg 0,90 100 kg 0,80 Z-distance (m) 0,70 120 kg 0,60 150 kg 0,50 170 kg 0,40 175 kg 0,30 180 kg 185 kg 0,20 200 mm 0,10 0,00 0,00 0,10 0,10 0,20 0,20 0,30 0,40 0,50 0,60 0,70 L-distance (m ) Figure 11 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity).. 18 Product Specification IRB 6600 M2000 Description Load diagram for IRB 6600-175/2.8 “Vertical Wrist” (±10o) L “Vertical wrist” Pay load 200 mm 10o 10o L-distance (m ) 0,00 0,20 0,40 0,60 0,80 1,00 1,20 1,40 Z 0,00 0,20 210 kg 190 kg 0,40 Z-distance (m) 170 kg 125 kg 0,60 100 kg 0,80 1,00 1,20 Figure 12 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity) at “Vertical Wrist” (±10o). For wrist down (0o deviation from the vertical line) Max load = 215 kg, Zmax = 0,382m and Lmax = 0,116m Product Specification IRB 6600 M2000 19 Description Load diagram for IRB 6650-125/3.2 1,10 1,00 80 kg 0,90 90 kg 0,80 100 kg 0,70 Z-distance (m) 110 kg 0,60 115 kg 0,50 120 kg 0,40 125 kg 0,30 130 kg 0,20 200 mm 0,10 0,00 0,00 0,10 0,20 0,20 0,30 0,40 0,50 0,60 0,70 L-distance (m) Figure 13 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity).. 20 Product Specification IRB 6600 M2000 Description Load diagram for IRB 6650-125/3.2 “Vertical Wrist” (±10o) L “Vertical wrist” Load diagram "Vertical Wrist" (±10°) Pay load 10o 10o IRB 6650 - 125/3.20 Armload: 50kg 200 mm L-distance (m) Z 0,0 0,2 0,20 0,4 0,40 0,6 0,60 0,8 0,80 1,0 1,00 1,2 1,20 1,4 1,40 1,6 1,60 0,0 150 kg 0,20 0,2 135 kg 0,40 0,4 120 kg Z-distance (m) 110 kg 0,6 0,60 100 kg 0,8 0,80 1,0 1,00 1,2 1,20 1,40 1,4 1,60 1,6 Figure 14 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity) at “Vertical Wrist” (±10o). For wrist down (0o deviation from the vertical line) Max load = 150 kg, Zmax = 0,462m and Lmax = 0,156m Product Specification IRB 6600 M2000 21 Description Load diagram for IRB 6650-200/2.75 0,90 0,80 100 kg 0,70 120 kg 135 kg 0,60 Z-distance (m) 150 kg 0,50 175 kg 195 kg 0,40 200 kg 0,30 205 kg 210 kg 0,20 200 mm 0,10 0,00 0,00 0,10 0,10 0,20 0,30 0,40 0,50 0,60 L-distance (m) Figure 15 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity). 22 Product Specification IRB 6600 M2000 Description Load diagram for IRB 6650-200/2.75 “Vertical Wrist” (±10o) L “Vertical wrist” Pay load 10o 10o Load diagram "Vertical Wrist" (±10°) IRB 6650 - 200/2.75 Armload: 50kg Z 200 mm L-distance (m) 0,0 0,2 0,20 0,4 0,40 0,6 0,60 0,8 0,80 1,0 1,00 1,2 1,20 1,4 1,40 0,0 235 kg 0,20 0,2 210 kg Z-distance (m) 0,4 0,40 175 kg 0,60 0,6 125 kg 0,80 0,8 100 kg 1,0 1,00 1,2 1,20 1,4 1,40 Figure 16 Maximum permitted load mounted on the robot tool flange at different positions (centre of gravity) at “Vertical Wrist” (±10o). For wrist down (0o deviation from the vertical line) Max load = 245 kg, Zmax = 0,345m and Lmax = 0,098m Product Specification IRB 6600 M2000 23 Description Maximum load and moment of inertia for full and limited axis 5 (centre line down) movement. Note. Load in kg, Z and L in m and J in kgm2 Full movement of axis 5 (±120o): Axis 5 Maximum moment of inertia: Ja5 = Load • ((Z + 0,200)2 + L2) + J0L ≤ 250 kgm2 for: -225/2.55, -175/2.8, -125/3.2 and -200/2.75 ≤ 195 kgm2 for: -175/2.55 Axis 6 Maximum moment of inertia: Ja6 = Load • L2 + J0Z ≤ 185 kgm2 for: -225/2.55, -175/2.8, -125/3.2 and -200/2.75 ≤ 145 kgm2 for: -175/2.55 Z X Centre of gravity J0L = Maximum own moment of inertia around the maximum vector in the X-Y-plane J0Z = Maximum own moment of inertia around Z Figure 17 Moment of inertia when full movement of axis 5. Limited axis 5, centre line down: Axis 5 Maximum moment of inertia: Ja5 = Load • ((Z + 0,200)2 + L2) + J0L ≤ 275kgm2 for: -225/2.55, -175/2.8, -125/3.2 and -200/2.75 ≤ 215 kgm2 for: -175/2.55 Axis 6 Maximum moment of inertia: Ja6 = Load • L2 + J0Z ≤ 250 kgm2 for: -225/2.55, -175/2.8, -125/3.2 and -200/2.75 ≤ 195 kgm2 for: -175/2.55 Centre of gravity J0L = Maximum own moment of inertia around the maximum vector in the X-Y-plane J0Z = Maximum own moment of inertia around Z X Z Figure 18 Moment of inertia when axis 5 centre line down. 24 Product Specification IRB 6600 M2000 Description Mounting equipment Extra loads can be mounted on the upper arm housing, the lower arm, and on the frame. Definitions of distances and masses are shown in Figure 19 and Figure 20. The robot is supplied with holes for mounting extra equipment (see Figure 21). Maximum permitted arm load depends on centre of gravity of arm load and robot payload. Upper arm Permitted extra load on upper arm housing plus the maximum handling weight (See Figure 19): M1 ≤50 kg with distance a ≤500 mm, centre of gravity in axis 3 extension. / a M1 Mass centre M1 Figure 19 Permitted extra load on upper arm. Frame (Hip Load) Permitted extra load on frame is JH = 200 kgm2 Recommended position (see Figure 20). JH = JH0 + M4 • R2 where JH0 R M4 is the moment of inertia of the equipment is the radius (m) from the centre of axis 1 is the total mass (kg) of the equipment including bracket and harness (≤500 kg) 527 457 R 790 1195 View from above View from the rear Figure 20 Extra load on the frame of IRB 6600 (dimensions in mm). Product Specification IRB 6600 M2000 25 Description Mounting of hip load The extra load can be mounted on the frame. Holes for mounting see Figure 21 and Figure 22. When mounting on the frame all the four holes (2x2, ∅16) on one side must be used. 520 IRB 6600 725 IRB 6650 400 IRB 6600 500 IRB 6650 Holes for mounting extra equipment Figure 21 Holes for mounting extra equipment on the upper and the lower arm, and the frame (dimensions in mm). 26 Product Specification IRB 6600 M2000 Description Figure 22 Holes for mounting of extra load on the upper arm (dimensions in mm). Product Specification IRB 6600 M2000 27 Description IRB 6600-175/2.55 1,6 0,04 A 12 H7 Depth 15 A 15 A 2 ) o (12x 30 R B B A A-A 0,02 CD 99 100 H7 Depth 8 min 160 0,02 A B-B M12 ( 11x ) 0,2 A B Figure 23 Robot tool flange (dimensions in mm). 28 Product Specification IRB 6600 M2000 Description IRB 6600-225/2.55 IRB 6600-175/2.8 IRB 6650-125/3.2 IRB 6650-125/3.2 1 2 0,04 A 1,6 A 12 H7 Depth 15 15 A 1,6 B B B A 0,02 C D A-A 0,02 A 100 H7 Depth 8 min M12 ( 11x ) 0,2 A B 160 B-B Figure 24 Robot tool flange (dimensions in mm). Product Specification IRB 6600 M2000 29 Description 1.5 Maintenance and Troubleshooting The robot requires only a minimum of maintenance during operation. It has been designed to make it as easy to service as possible: - Maintenance-free AC motors are used. - Oil is used for the gear boxes. - The cabling is routed for longevity, and in the unlikely event of a failure, its modular design makes it easy to change. The following maintenance is required: - Changing filter for the transformer/drive unit cooling every year. - Changing batteries every third year. The maintenance intervals depend on the use of the robot. For detailed information on maintenance procedures, see Maintenance section in the Product Manual. 30 Product Specification IRB 6600 M2000 Description 1.6 Robot Motion Type of motion Range of movement Axis 1 Axis 2 Axis 3 Axis 4 Axis 5 Axis 6 +180o +85o +70o +300o +120o +300o Rotation motion Arm motion Arm motion Wrist motion Bend motion Turn motion to -180o to -65o to -180o to -300o to -120o to -300o IRB 6600-175/2.55 IRB 6600-225/2.55 Figure 25 The extreme positions of the robot arm specified at the wrist centre (dimensions in mm). Product Specification IRB 6600 M2000 31 Description IRB 6600-175/2.8 Figure 26 The extreme positions of the robot arm specified at the wrist centre (dimensions in mm). 32 Product Specification IRB 6600 M2000 Description IRB 6650-125/3.2 Figure 27 The extreme positions of the robot arm specified at the wrist centre (dimensions in mm). IRB 6650-200/2.75 Figure 28 The extreme positions of the robot arm specified at the wrist centre (dimensions in mm). Product Specification IRB 6600 M2000 33 Description Performance according to ISO 9283 At rated maximum load, maximum offset and 1.6 m/s velocity (for IRB 6600-225/2.55, 1.0 m/s velocity) on the inclined ISO test plane, 1 m cube with all six axes in motion. Data for IRB 6650 not yet available. IRB 6600 -175/2.55 Pose accuracy, AP 0.09 mm Pose repeatability, RP 0.18 mm Path repeatability, RT 1.05 mm Pose stabilization time, Pst 0.03 s -225/2.55 0.11 mm 0.18 mm 0.36 mm 0.55 s* -175/2.8 0.13 mm 0.20 mm 0.32 mm 0.21 s * Too close limit Velocity Maximum axis speeds. Axis no. 1 2 3 4 5 6 IRB 6600-175/2.55 IRB 6600-225/2.55 IRB 6600-175/2.8 IRB 6650-200/2.75 IRB 6650-125/3.2 100°/s 90°/s 90°/s 150°/s 120°/s 190°/s 110°/s 90°/s 90°/s 150°/s 120°/s 235°/s 1.7 Cooling fan for axis 1-3 motor (option 113-115) A motor of the robot needs a fan to avoid overheating if the avarage speed over time exceeds the value given in Table 1. The maximum allowed avarage speed is depending on the load. The average speed can be calculated with the following formula: Average speed = Total axis movement, number of degrees, in one cycle 360 x cycle time (minutes) incl. waiting time The maximum allowed average speed for axis 1-3 at the maximum ambient temperature of 50oC according to Table 1. IP 54 for cooling fan. Table 1 Variant 34 Maximum average speed axis 1 (rpm) Maximum average speed axis 2 (rpm) Maximum average speed axis 3 (rpm) IRB 6600-175/2.55 8.1 - 10.5 2.4 - 2.6 4.7 - 6.1 IRB 6600-225/2.55 7.8 - 10.1 2.1 - 2.3 3.1 - 4.0 IRB 6600-175/2.8 7.8 - 10.1 2.1 - 2.3 3.1 - 4.0 IRB 6650-125/3.2 4.9 - 6.3 2.1 - 2.3 3.1 - 4.0 IRB 6650-200/2.75 7.8 - 10.1 2.1 - 2.3 3.1 - 4.0 Product Specification IRB 6600 M2000 Description 1.8 SpotPack and DressPack The different robot types can be equipped with the option SpotPack for IRB6600/6650. The SpotPack IRB6600/6650 is designed for spot welding and handling applications. The function package supplies the transformer gun or the robot gripper with necessary media, such as compressed air, cooling water and electrical power. SpotPack IRB6600/6650 can be delivered in three standard versions developed for three different applications: • SpotPack IRB6600/6650 Type S is designed for transformer guns carried by the robot manipulator. • SpotPack IRB6600/6650 Type HS is designed for transformer guns mounted on a pedestal. • SpotPack IRB6600/6650 Type H is designed for material handling, using the same DressPack as type HS. SpotPack IRB 6600 / 6650 Robot carried Gun Type S Product Specification IRB 6600 M2000 Pedestal Gun Type HS Material Handling Type H 35 Description The SpotPack for IRB6600/6650 is modular based and contains the main modules shown in the schematic picture below. Option description specifies different module combinations. Robot gun/gripper Upper arm harness Lower arm harness Power unit Water and air unit Control Cabinet Pedestal gun Floor harness Figure 29 SpotPack IRB6600/6650 main modules. The modules Upper arm harness, Lower arm harness and Floor harness are in different combinations described as DressPack. The DressPack for upper and lower arm harness contains signals, process media (water and air) and power feeding (for Spotwelding power) for customer use. The floor harness for DressPack contains customer signals. To form a complete SpotPack also a Water and Air unit with hoses, Power unit with power cable and signal cables between these units are required. 36 Product Specification IRB 6600 M2000 Description Description of DressPack The DressPack contains the maximum wire and media capacity as described below. The number of signals that are available in each case depends on the choice of different option combinations (see option description). The interface connectors for the signals are also specified under each option description. Material handling application The cables and hose which are used to form the DressPack for the Material Handling application has the following specification and capacity: Table 2 Type Pcs Area Allowed capacity Customer Power (CP) Utility Power Protective Earth 2+2 1 0,5 mm2 1,0 mm2 500 VAC, 5 A rms 500 VAC 19 4 0,23 mm2 0,23 mm2 50 VAC/DC, 1 A rms 50 VAC/DC, 1 A rms Customer Bus (CBus) Bus signals Bus signals Bus signals Bus utility signals 2 2 4 4 0,18 mm2 0,18 mm2 0,18 mm2 0,23 mm2 Profibus 12 Mbit/s spec* Can/DeviceNet spec* Interbus spec* 50 VAC/DC, 1 A rms Media Air (PROC 1) 1 12,5 mm inner diameter Max. pressure 16 bar / 230 PSI Customer Signals (CS) Signals twisted pair Signals twisted pair and separate shielded * Quad twisted under separate screen. Can also be used for very sinsitive signals Product Specification IRB 6600 M2000 37 Description Spot Welding application The cables and hoses used for the DressPack for the Spot Welding application has the following specification and capacity: Table 3 Type Pcs Area Allowed capacity Customer Power (CP) Servo motor power Utility Power Protective Earth 3 2+2 1 1,5 mm2 0,5 mm2 1,5 mm2 600 VAC, 12 A rms 500 VAC, 5 A rms 500 VAC 19* 4 0,23 mm2 0,23 mm2 50 VAC/DC, 1 A rms 50 VAC/DC, 1 A rms 2 2 4 4 0,18 mm2 0,18 mm2 0,18 mm2 0,23 mm2 Profibus 12 Mbit/s spec** Can/DeviceNet spec** Interbus spec** 50 VAC/DC, 1 A rms 2 1 35mm2 35mm2 600 VAC*** 2 1 25mm2 25mm2 600 VAC**** 3-4 12,5 mm inner diameter Max. air pressure 16 bar / 230 PSI. Max water pressure 10 bar / 145 PSI Customer Signals (CS) Signals twisted pair Signals twisted pair and separate shielded Customer Bus (CBus) Bus signals Bus signals Bus signals Bus utility signals Welding power (WELD) Lower arm harness Lower arm harness protective earth Upper arm harness Upper arm harness protective earth Media Water/Air (PROC 3-4) * If servo gun application (S or HS) is used some signals will be occupied for motor control. ** Quad twisted under separate screen. Can also be used for very sensitive signals. *** 150 A rms at + 20°C (68F) ambient temp, 120 A rms at + 50°C (122F) ambient temp **** 135 A rms at + 20°C (68F) ambient temp, 100 A rms at + 50°C (122F) ambient temp 38 Product Specification IRB 6600 M2000 Description Description of Water and Air unit The Water and Air unit contains components for water and air distribution and control within the SpotPack. The water and air unit is via the process software controlled from the robot controller. Wiring is made via the power unit. The capacity and functionality depends on the choice of different option combinations, see option description. The unit is mounted at the manipulator base. Control cables to the unit has quick connectors in both ends and has the same cable length as the one specified for the robot control cable. The unit is only used for the spot welding applications. Table 4 Type Pcs Specification Connections for media Incoming water Outgoing water Incoming air Extra air outlet 1 1 1 1 Parker PushLock fitting, M22 (conical angle 24°)* Parker PushLock fitting, M22 (conical angle 24°)* Parker PushLock fitting, M22 (conical angle 24°)* 1/2" connection. ** * Max air pressure 16 bar / 230 PSI, max water pressure 10 bar / 145 PSI. (Parker Pushlock reference 3C382-15-8BK, brass version) ** Plugged at delivery (to be used for tip-dresser or other equipment). (Fitting 1/2" BSP 1,5). Signals for water and air unit: Electrical connections to robot I/O board are made via the splitbox on the water and air unit. Total 6 x M12 connections (4 pins) are available. The number in use depends on option choices but minimum 2 are in use within the SpotPack. Free connections can be used for customer purpose like tip-dresser control (Max 0,5 amp, 24 DC Volt). Product Specification IRB 6600 M2000 39 Description Description of Power Unit The Power unit contains components for power distribution and control within the SpotPack. The power unit with the welding controller built in, is controlled from the robot controller via the process software.. Wiring is made between robot controller (I/O-board and internal cabling in the DressPack) and the power unit. The capacity and functionality depends by the choice of different option combinations. All cables are connected on the left hand side of the power unit. The unit is placed on top of the robot controller. The unit is only used for the spot welding applications. Two basic versions are available, Type S for Spotwelding with robot handled gun and Type HS for Spotwelding with pedestal gun. Table 5 Type Pcs Area Allowed capacity Connections for power unit Incoming power from line 1 __ VAC, __A 50/60 Hz Outgoing power to robot 1 Floor cable Floor cable protective earth 2 1 Cable gland min __ mm/max __ mm cable* Cable gland min __ mm/max __ mm cable* 35mm2 35mm2 Signals Water and Air unit Pedestal gun 1 1 Modular Harting connector*** 50 VAC/DC, 1 A rms Modular Harting connector*** 50 VAC/DC, 1 A rms * __ VAC, __A 50/60 Hz 600 VAC** 600 VAC Incoming power connection made by customer. For incoming power recommendations see Installation and Maintenance manual. ** 150 A rms at + 20°C (68F) ambient temp and 120 A rms at + 50°C (122F) ambient temp *** The connector type at the power unit is Han compact, HD insert.. Protection class for the power unit is IP54. 40 Product Specification IRB 6600 M2000 Description 1.9 Description of Variants and Options for SpotPack The following specification describes all main parts with main data for the SpotPack and Dresspack IRB 6600/6650. Required options for SpotPack IRB 6600/6650 different types To enable the spot welding function package SpotPack IRB 6600/6650 to perform as intended, general standard robot options for the three different types are required. These standard options are described under other chapters but are also mentioned in this chapter. SpotPack Type S standard requires the following general robot options: Option 122 Option 201 Option 251 Option 206 Option 553 No upper cover on robot control cabinet 1pc. Digital 24 VDC I/O 16 inputs/ 16 outputs. Internal connection of I/O Internal connection of safety signals SpotWare (software option for pneumatic guns) SpotPack Type HS standard requires following general robot options: Option 122 Option 201 Option 251 Option 206 Option 553 No upper cover on robot control cabinet 1pc. Digital 24 VDC I/O 16 inputs/ 16 outputs. Internal connection of I/O Internal connection of safety signals SpotWare (software option for pneumatic guns) SpotPack Type H standard requires no general robot options. 1.9.1 Required options for SpotPack IRB 6600/6650 different types with servo gun To enable the spot welding function package SpotPack IRB 6600/6650 to run with a servo controlled gun, some additional (additional to those described in chapter 2.1) servo drive options for the two different types are required. These standard options are described under other chapters but are also mentioned below in this chapter. SpotPack Type S with servo requires the following additional options: Option 381 Option 702 Option 681-684 Option 625 Drive unit type DDU-U Robot Gun. Connection of servo gun (7-30 m) SpotWare Servo (software option for servo guns) (replaces option 553). Also option 631, Servo tool change, should be added if servo gun tool change is required. (The option 561, Servo Tool Control, could be an alternative to 625 if the application software is designed by the customer. Option 561 is not used in the SpotPack as this is intended to be a ready to use package). Product Specification IRB 6600 M2000 41 Description SpotPack Type HS with servo requires the following additional options: Option 381 Option 702 Option 686-689 Option 625 42 Drive unit type DDU-U Stationary Gun. Connection of servo gun (7 - 30 m) SpotWare Servo (software option for servo guns) replaces option 553). (The option 561, Servo Tool Control, could be an alternative to 625 if the application software is designed by the customer. Option 561 is not used in the SpotPack as this is intended to be a ready to use package). Product Specification IRB 6600 M2000 Description 1.9.2 DressPack options Dress Pack options includes options for Upper arm harness, Lower arm harness and Floor harness. These are described separated below but are designed and meant to be seen as a complete package for either Material handling or Spot welding application. The Upper Arm Harness consists of a process cable package and supports, clamps, brackets and a retractor arm. The process cable package contains special designed cables and hoses that have been long term tested. The cables and hoses are partly placed in a protective hose to extend the lifetime. The Upper Arm Harness is designed to follow the robot arm movements and minimise damages to the harness or the robot manipulator. The interface to the lower arm harness is located well protected below the motor for axis 3. The complete harness is tested and proven to be well suited for both spot welding applications and other applications with the same type of movements and very high requirements. The cable and hose package has a 1000-mm free length at axis 6 for connection to a spot welding gun or a gripper. A tension arm unit keeps hose package in the right position for the robot arm movement approved for the SpotPack. An arm protection will prevent wear on the protective hose and on the robot itself. Please note that when the robot is operating, some multiply axis movement might end up with an overstraining of the hose package. These movements must be avoided. For more information see the Installation and Maintenance Manual. Process Cable package Harness support axis 6 Tension arm unit Arm protection Figure 30 Mechanical equipment upper arm harness. Note. The upper arm harness specification is based on the sselection of lower arm harness. The Lower Arm Harness consists of a process cable package and supports, clamps and brackets. The process cable package, containing special designed cables and hoses, has been long term tested. The process cable package is routed along the lower arm to minimise space required and to give no limitation in the robot working envelope. The cables and hoses are partly placed in a protective hose to extend the lifetime. Product Specification IRB 6600 M2000 43 Description The lower arm harness is connected to the upper arm harness at the connection point under the axis 3 motor. The interface plate at the manipulator base is the place where the floor harness and the process media are connected. The Floor Harness consists of signal cables for customer signals. The floor harness is connected to the lower arm harness at the interface plate at the manipulator base and to the left side of the robot control cabinet. The signal connection inside the robot control cabinet depends on chosen options. As example will servo gun option, bus option and parallel option mean different connections. Process cable package For material handling and spot welding the DressPack can be chosen in different configurations. The part of the DressPack changing between different options are basically the process cable package and the brackets etc are the same. Initially general configurations for the process cable package is specified. With this as a base, the details of the application signals and media are added. Option 056 Connection to manipulator No floor cables for the DressPack are chosen. The connector at the base for interfacing is specified in installation and maintenance manual. Terminal connections could be found in the circuit diagrams. Option 057 Connection to cabinet Floor cables for the DressPack are chosen. Number of cables and cable type depends on chosen options. The length of the process cable package at the floor is specified under the options below: - Option 675-678 for parallel communication - Option 660-663 for bus communication with Can/DeviceNet - Option 665-668 for bus communication with Profibus - Option 670-673 for bus communication with Interbus The connection inside the cabinet depends on communication type. - If parallel communication is chosen, signals are found at terminals inside the cabinet (XT5.1, XT5.2 and XT6) - If bus communication is chosen, signals are routed both to valid bus card. The remaining are found at terminals inside the cabinet (XT5.1, XT5.2 and XT6). 44 Product Specification IRB 6600 M2000 Description Communication Option 2063 Parallel communication The process cable package has been chosen for parallel communication. The number as well as the type of signals are defined under Material handling application (Option 2204,2205) and Spot welding application (Option 2200). Option 2064 Bus communication The process cable package has been chosen for bus communication. This alternative includes both the signals for the bus communication as well as some parallel signals. The number as well as the type of signals are defined under Material handling application (Option 2204,2205) and also Spot welding application (Option 2200). This option can not be combined with servo gun application. The type of bus are defined by choice of floor cabling (see also option 057) Option 2204 Material Handling axis 1 to axis 3 The Lower arm harness for the Material Handling has been chosen. This includes the process cable package as well as brackets, connectors etc to form a complete dressing package from manipulator base until connectors on axis 3. Depending on the choice above the process cable package will have different content. See tables below. For all process cable packages some of the content is common. These common parts for Material Handling application are shown in Table 6 below. Unique parts for different option combinations are shown in Table 7, Table 8, Table 9 and Table 10. These tables are valid for option 2204 and 2205. Table for Common content Material Handling (with option 2063/2064) Table 6 Type Pcs at Connection point Note Allowed capacity 1 12,5 m inner diameter Max pressure 16 bar / 230 PSI Media Air (PROC 1) Product Specification IRB 6600 M2000 45 Description Table for Material Handling with option 2063 with or without Servo gun option 701 Table 7 Type Customer Power (CP) Utility Power Protective earth Customer Signals (CS) Signals twisted pair Signals twisted pair and separate shielded Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 2+2 1 500 VAC, 5 A rms 500 VAC 19 4 19 4 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen ** At manipulator base or axis 3 interface (or axis 6 under option 2205) Table for Material Handling with option 2064 and Can/DeviceNet Table 8 Type Customer Power (CP) Utility Power Protective earth Customer Bus (CBus) Bus signals Bus signals Signals twisted pair Utility signals Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 2+2 1 500 VAC, 5 A rms 500 VAC 4 4 2 2 4 4 Can/DeviceNet spec 50 VAC, 1 A rms 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen ** At manipulator base or axis 3 interface (or axis 6 under option 2205) 46 Product Specification IRB 6600 M2000 Description Table for Material Handling with option 2064 and Interbus Table 9 Type Customer Power (CP) Utility Power Protective earth Customer Bus (CBus) Bus signals Bus signals Signals twisted pair Utility signals Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 2+2 1 500 VAC, 5 A rms 500 VAC 4 3 4 1 4 3 Interbus spec 50 VAC, 1 A rms 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen ** At manipulator base or axis 3 interface (or axis 6 under option 2205) Table for Material Handling with option 2064 and Profibus Table 10 Type Customer Power (CP) Utility Power Protective earth Customer Bus (CBus) Bus signals Bus signals Signals twisted pair Utility signals Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 2+2 1 500 VAC, 5 A rms 500 VAC 4 4 2 2 4 4 Profibus 12Mbit/s spec 50 VAC, 1 A rms 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen ** At manipulator base or axis 3 interface (or axis 6 under option 2205) Option 2205 Material Handling axis 3 to axis 6 The Upper arm harness for the Material Handling has been chosen. This includes the process cable package as well as brackets, connectors etc to form a complete dressing package from interface at axis 3 to the connectors at axis 6. Depending on the earlier choice (see option 2204) the process cable package will have different content. For content see Table 6, Table 7, Table 8, Table 9 and Table 10. The connector type at the manipulator base, at axis 3 and axis 6 is specified in the Installation and maintenance manual. Product Specification IRB 6600 M2000 47 Description Option 2200 Spot Welding to axis 3, and option 2201 Spot Welding to axis 6 The Lower arm harness and the Upper arm harness for Spot Welding has been chosen. This includes the process cable package as well as brackets, connectors etc to form a complete dressing package from manipulator base to the connectors on axis 6. Depending on the earlier choice above the process cable package will have different content. See tables below. For further details see Installation and maintenance manual and circuit diagrams For all process cable packages some of the content are common. These common parts for Spot Welding application are shown in table 11 below. Unique parts for different option combinations are showed in Table 12, Table 13, Table 14, Table 15 and Table 16. Table for common content Spot Welding (with option 2063/2064) Table 11 Type Welding Power (WP) Lower arm harness Lower arm harness protective earth Upper arm harness Upper arm harness protective earth Media Water/Air (PROC 1-3) Pcs at Connection point* Note Allowed capacity 2 1 35 mm2 35 mm2 600 VAC** 2 1 25 mm2 25 mm2 600 VAC*** 3 12,5 mm inner diameter Max. air pressure 16 bar/ 230 PSI. Max. water pressure 10 bar/145 PSI * ** At manipulator base or axis 6. 150 A rms at + 20°C (68F) ambient temp, 120 A rms at + 50°C (122F) ambient temp *** 135 A rms at + 20°C (68F) ambient temp, 100 A rms at + 50°C (122F) ambient temp 48 Product Specification IRB 6600 M2000 Description Table for Spot Welding with option 2063 Table 12 Type Customer Power (CP) Utility Power Protective earth Customer Signals (CS) Signals twisted pair Signals twisted pair and separate shielded Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 2+2 1 500 VAC, 5 A rms 500 VAC 19* 4* 19* 4* 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen. ** At manipulator base or axis 6. Table for Spot Welding with option 2063 and servo gun option 702 Table 13 Type Customer Power (CP) Servo motor Power Utility Power Protective earth Customer Signals (CS) Signals twisted pair Signals twisted pair and separate shielded Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 3 2+2 1 600 VAC, 12 A rms 500 VAC, 5 A rms 500 VAC 4* 4* 4* 4* 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen. Signals needed for servo gun motor control are not specified above. ** At manipulator base or axis 6. Product Specification IRB 6600 M2000 49 Description Table for Spot Welding with option 2064 and CAN/DeviceNet Table 14 Type Customer Power (CP) Utility Power Protective earth Customer Bus (CBus) Bus signals Bus signals Signals twisted pair Utility signals Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 2+2 1 500 VAC, 5 A rms 500 VAC 4 4 2 2 4 4 CAN/DeviceNet spec 50 VAC, 1 A rms 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen. ** At manipulator base or axis 6. Table for Spot Welding with option 2064 and Interbus Table 15 Type Customer Power (CP) Utility Power Protective arth Customer Bus (CBus) Bus signals Bus signals Signals twisted pair Utility signals Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 2+2 1 500 VAC, 5 A rms 500 VAC 4 3 4 1 4 3 Interbus spec 50 VAC, 1 A rms 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen. ** At manipulator base or axis 6. 50 Product Specification IRB 6600 M2000 Description Table for Spot Welding with option 2064 and Profibus Table 16 Type Customer Power (CP) Utility Power Protective earth Customer Bus (CBus) Bus signals Bus signals Signals twisted pair Utility signals Pcs at Terminal* Pcs at Connection point** Allowed capacity 2+2 1 2+2 1 500 VAC, 5 A rms 500 VAC 4 4 2 2 4 4 Profibus 12Mbit/s spec 50 VAC, 1 A rms 50 VAC, 1 A rms 50 VAC, 1 A rms * Terminals inside the cabinet if option 057 is chosen ** At manipulator base or axis 3 interface (or axis 6 under option 2205) Option 2065 Extended media The process cable package from foot to axis 6 can be extended with an extra media hose. This could only be chosen in combination Spot welding application (with option 2200, all variants shown in Table 12, Table 13, Table 14, Table 15 and Table 16). This option has the following specification: - Hose 1/2" (Proc 4) with connection (Parker Pushlock reference 3C382-158BK, brass version) both at foot and at axis 3. At axis 6 with free end. Option 2070 Connection kit, Axis 6 robot side SW The process cable package from manipulator base to axis 6 (option 2200) ends with free end for media and for weld power cable. If this option is chosen a kit for connections will be supplied. This has to be assembled by the customer when hoses and power cable has been cut to required length. The kit contains: - 4 Hose fittings, Parker Push lock type with conical angel 24 Degrees (Parker Pushlock reference 3C382-15-8BK, brass version). - 1 Multi contact connector (Female). Product Specification IRB 6600 M2000 51 Description 1.9.3 Power Unit The standard Power unit for SpotPack contains the electric components and circuits needed for spot welding. The power unit cabinet is designed to be placed on top of the robot control cabinet, see picture below, and secured with four attachment plates. The power unit should be seen as a main part of the complete SpotPack (type S and HS) and normally not handled as a separate unit. The electrical circuits of the power unit consist of weld power circuit and control circuits to control the welding. Weld power circuit The welding power for the welding gun is fed through a circuit breaker and welding thyristor (for AC welding) or inverter (for MFDC welding) and further out to the welding power cable. The welding power cable is connected directly to the thyristor/ inverter. Control Circuits Power 240 V AC and 24 V DC for the control circuits is fed from the robot cabinet. Also the safety circuits in the robot cabinet is used to interlock the welding timer. A welding timer (Bosch), integrated with the air cooled thyristor or inverter, controls the welding current. The welding timer includes control program which gives possibility to program different weld sequence. The programming is normally done on a PC that is connected directly to the welding timer. The interface between the robot system and the welding timer is handled via a digital signal interface. Example of signals are weld start, weld ready, weld program choice and error. Also cross connections, of interface signals and interlocking between the robot system (I/O-boards), the water and air unit, signals to DressPack and pedestal / stationary gun (type HS), are done within the power unit. For further information see Installation and Maintenance manual and separate manuals for the Bosch equipment. Programming device for the welding timer is not included. Option 2087 Power unit, AC welding type S The basic power unit for type S is equipped for a robot handled AC Spotwelding gun and with the following components: - Cable gland for incoming power (X100) - Circuit Breaker type ABB SACE, T1 160 A - Welding Timer and Thyristor type Bosch PST 6100.100L 76kVA - Fuse terminal for 24 V distribution - Connector to Water and air unit, Modular Harting. (XS103) - Cable gland for outgoing power (X101). (For power cable see option 2095/ 2096) For further information see Installation and Maintenance manual, circuit diagrams and separate manuals for the Bosch equipment. 52 Product Specification IRB 6600 M2000 Description Option 2088 Power unit, AC welding type HS The basic power unit for type HS is equipped for a stationary / pedestal mounted AC Spotwelding gun and with the following components: - Cable gland for incoming power (X100) - Circuit Breaker type ABB SACE, T1160 A - Welding Timer and Thyristor type Bosch PST 6100.100L76kVA - Fuse terminal for 24 V distribution - Connector to Water and air unit, Modular Harting. (XS103) - Connector to pedestal gun, Modular Harting (XS 104). (For process cables to Stationary gun see option 2117, 2118 and 2119) - Cable gland for outgoing power (X101). For power cable (see option 2095/ 2096) For further information see Installation and Maintenance manual, circuit diagrams and separate manuals for the Bosch equipment. Option 2090 MFDC welding S and HS This option replaces the thyristor unit in option 2087 or 2088, with a MFDC inverter type Bosch PSI 6100.100L. This option requires forced air cooling (option 2091). Option 2091 Forced air cooling This option adds a cooling fan with housing placed on the rear of the power unit. This forces air on the cooling surface for the thyristor or MFDC converter. For the MFDC converter this is mandatory. For the AC thyristor the need of the forced air cooling depends on the load and the ambient temperature. For further information see separate manuals for the Bosch equipment. Option 2092 Earth fault protection This option adds an earth fault protection to the circuit breaker. This protection could be used for AC welding or MFDC welding. The sensitivity of the earth fault protection could be adjusted. If and earth fault occurs the circuit breaker is tripped. For further information see Installation and Maintenance manual, circuit diagrams and separate specifications of the earth fault protection. Option 2093 Contactor for weld power This option adds a contactor with necessary wiring and relays inside the power unit. This contactor could be used to disconnect power to the gun at for example tool change. Option 2095 Weld power cable, 7m This option includes floor cable of 7 m length for weld power. This is connected at terminals inside the control cabinet and with an MC connector at manipulator base. The cable has an allowed capacity of 150 A rms at + 20°C (68F) ambient temp and 120 A rms at + 50°C (122F) ambient temp. Product Specification IRB 6600 M2000 53 Description Option 2096 Weld power cable, 15 m This option includes floor cable of 15 m length for weld power. See description for option 2095. Option 2117 Process cable to stationary gun, 7m This option includes floor cable of 7 m length for process signals to the pedestal/ stationary gun. This cable is connect to the Power unit (option 2088) with a modular harting. The cable ends also with a modular harting where the customer could connect control signals for the gun. For further information about connector and available signals see Installation and Maintenance manual and circuit diagrams. Option 2118 Process cable to stationary gun, 15m This option includes floor cable of 15 m length for weld power. See description for option 2117. Option 2119 Process cable to stationary gun, 30m This option includes floor cable of 30 m length for weld power. See description for option 2117. 1.9.4 Water and Air Unit The water and air unit is the connection point for cooling water and compressed air to the spot welding gun. All standard features and options are the same for types S and HS. Water and air unit is not included for type H. The standard water and air unit is mounted at the base of the robot. The standard water and air unit consists of four main assemblies: - Water in circuit - Water return circuit - Air supply circuit - Split box Cables and hoses required for Water and Air unit are defined and described under each option for water and air unit. Water in circuit The function of the water in circuit is to open / close the cooling water supply to the Spot welding gun. An electrically controlled valve with indication led is used. The valve is controlled by a digital signal from the robot control system. The circuit start from left with an Parker Puchlock 33482-8-8BK fitting for ½” hose (hose assembled by customer), manual shut off valve for the cooling water flow, electrical shut off valve and ends with a Parker Pushlock adapter. (Suitable for a Parker Puchlock DIN 20 078 A, we recommend a Parker Pushlock 39C82-15-8BK fitting). From this point the water is led to the gun/robot. 54 Product Specification IRB 6600 M2000 Description Water return circuit The water return circuit monitors the flow of the returning cooling water from the Spot welding gun. The flow switch detects if the water flow is too low in the cooling water circuit. The flow switch gives a digital signal to the robot control system, which automatically shuts the electrical shut off valve in the water in circuit off if the flow is too low. The system and the supply of cooling water are then automatically stopped to minimise any risk of damage to the system. The water return circuit is delivered with a pre-set flow limit, set to approx. 3,5 litres per minute. The water return circuit started from right with a Parker Pushlock adapter (Suitable for a Parker Puchlock DIN 20 078 A, we recommend a Parker Pushlock 39C82-15-8BK fitting), flowswitch with a switching point between 2-12 litres per minute. It’s also equipped with a flow control valve; the flow control can adjust the water flow to a wanted flow level. The flow-value can be monitored through a small window on the flow control valve. This will serve as a rough function check in the approximate flow range of 2-8 litres per minute. The circuit end’s with a check-valve that will stop any reversing water flow, manual shut off valve and an Parker Puchlock 33482-8-8BK fitting for ½” hose (hose assembled by customer). From this point the water is led to the factory water system. Air supply circuit The air supply circuit provides the robot and option: proportional valve with air supply. The air supply circuit started with a Parker Puchlock 39C82-15-8BK fitting (hose assembled by customer). Manually operated shut off valve to vent the system through a silencer, air filter 25 microns and a water separator equipped with a metal bowl protection, distribution block containing plugged air outlet ports. The air supply circuit ends with a Parker Pushlock adapter. (Suitable for a Parker Puchlock DIN 20 078 A, we recommend a Parker Pushlock 39C82-15-8BK fitting). Maximum flow capacity is 3000 litres per minute at 6.3 bar and P = 1.0 bar. Maximum allowed pressure is 16 bar. Split box With the split box, the 24VDC supply and signals are connected and distributed to the different units on the water and air unit, see picture below. The design makes disconnection of separate items for service and repair on the water and air unit very easy. The split box has a protection class IP68. Brand: Woodhead, Brad Harrison. The split box has six connections prepared for the following units. - Electric water shut off valve - Flow switch 1 - Flow switch 2 (Option 2177 Second Water Return) - Pressure switch (Option 2179 Pressure switch and Regulator for air) - Proportional valve (Option 2181 Electrical proportional valve for air) - Spare Product Specification IRB 6600 M2000 55 Description The cable and cable length between the Split box and the Power unit has to be specified (see option 2183, 2184 and 2185). El. shut off XS 101.1 Flow switch 1 XS 101.2 Flow switch 2 Air pressure switch Proportonal Valve Option Option Option Spare XS 101.3 XS 101.4 XS 101.5 XS 101.6 24V, parallel interface Figure 31 Block diagram split box on Water and Air Unit Option 2174 Water and Air unit, type S The basic water and air unit for type S is equipped for a robot handled gun and with the following components: - Water in circuit - Water return circuit - Air supply circuit - Split box - 1/2 " hose between air supply circuit and manipulator base (PROC 1) - 1/2 " hose between water in circuit and manipulator base (PROC 2) - 1/2 " hose between water return circuit and manipulator base (PROC 3) Option 2175 Water and Air unit, type HS The basic water and air unit for type HS is equipped for a pedestal/stationary gun and with the following components: - Water in circuit - Water return circuit - Air supply circuit - Split box - 1/2" hose between air supply circuit and manipulator base (PROC 1) 56 Product Specification IRB 6600 M2000 Description Hoses between water in circuit and water return circuit are not supplied. These have to be arranged by the customer. Option 2177 Second water return When the water pressure drop is to high because of too long hoses or because of any other reason, an additional water return circuit can be the best solution to solve this problem. For this extra water return circuit this option is required. It contains an extra flow switch to monitor the water coming from the second circuit. Two cooling water circuits also have the advantage of a more even cooling of the two sides of the Spotwelding gun compared to a single circuit system. For more information see under Flow switch in water return circuit. Please note that this option can not be combined with option 2181, Electrical proportional valve for air normally used together with a pneumatic robot mounted welding gun. The additional used water hose in this option is normally used for compressed air for pneumatic moved welding guns. Additional 1/2" water hose (PROC 4) to manipulator base is included. Option 2192 Digital flow meter, One water return If a digital flow meter is requested instead of a flow switch, this option should be chosen. This option is valid for one water return (if two water return see option 2193). This option means that the flow switch and the flow control valve with visible flow indication is replaced by the digital flow meter and a flow control valve without visible flow indication (not required as adjustments could be seen on the digital flow meter). The digital flow meter gives the following advantages compared to flow switch: - The biggest advantage is that the flow switch is mechanical function safe, that means if something damage the flow switch you will notice that immediacy - The actual flow could be seen direct on the display - The flow switch level and the tolerance could be set with high tolerance - The flow value could been monitored at distance with a remote display. Option 2193 Digital flow meter, Two water returns If the option second water return (option 2177) is chosen and the digital flow meter is requested this option should be chosen. For more information see option 2192. Option 2179 Pressure switch and regulator for air Option 2179, Filter regulator and pressure switch includes a manually operated pressure regulator to set the incoming pressure to the Spot welding gun. The pressure can be monitored on the included pressure gauge. This option also includes a Pressure Switch to monitor the air pressure and to give a signal to the control system if the pressure becomes to low. The 2179 include same components as Air Supply Circuit except that the filter changes to a filter regulator plus we add pressure gauge 0-16 bar and pressure Switch with belonging cable to splitbox. Product Specification IRB 6600 M2000 57 Description Option 2181 Electrical proportional valve for air The option includes a proportional valve with integrated control circuit and connection cable to the splitbox. The proportional valve controls the pinching force of the pneumatic spot welding gun and is designed to obtain optimal performance during long operation time. The proportional valve is controlled by the weldtimer in the Power unit. The included distribution block can be used for two additional non-regulated compressed air circuits. An analogue signal 0-10V, controls the proportional valve and the air pressure is in the range of 0-12 bar. Option 2183 Cable to split box, 7m This option includes floor cable of 7 m length for signals to the split box sitting on the water and air unit. This cable is connect to the Power unit (option 2087/2088) with a modular harting (Han Compact with insert type HD). The cable ends also with a quick connector at the split box end. Option 2184 Cable to split box, 15m This option includes floor cable of 15 m length for the split box. See description for option 2183. Option 2185 Cable to split box, 30m This option includes floor cable of 30 m length for the split box. See description for option 2183. 58 Product Specification IRB 6600 M2000 Description 1.10 Examples of SpotPacks To support the understanding of how the different options could be combined to complete SpotPacks some examples are shown below. Note that these are examples of possible configurations and that each case has to be analysed based on the unique production conditions. Example 1: DressPack for Material Handling with Can/DeviceNet Option no Name / Note DressPack options 057 Connection to cabinet. Includes floor cables with signals to terminals inside controller 2064 Communication, Bus communication 2204 Material Handl. Axis 1 to 3 Lower arm harness to get the signals to axis 3 2205 Material Handl. Axis 3 to 6 Upper arm harness to get the signals to axis 6 660 Connection to cabinet, cable length, CAN/DeviceNet / 7m Specifies floor cable length and type of bus Example 2: SpotPack for SpotWelding with pneumatic gun and parallel interface Option no Name / Note General options 122 No upper cover on robot control cabinet 201 1pc. Digital 24 VDC I/O 16 inputs/ 16 outputs 251 Internal connection of I/O 206 Internal connection of safety signals 553 SpotWare (software option for pneumatic guns) DressPack and SpotPack options 057 Connection to cabinet Includes floor cables with signals to terminals inside controller 2063 Communication, Parallel communication 2200 SpotWelding to axis 6 Lower arm and Upper arm harness to get the signals to axis 6 2065 Extended media SW Additional hose for regulated air via option 2181 675 Connection to cabinet, cable length, Parallel / 7m Specifies floor cable length with parallel interface Product Specification IRB 6600 M2000 59 Description 2087 Power unit, AC welding type S AC welding with robot handled gun 2095 Weld power cable / 7m. Specifies power cable for welding 2174 Water and air unit / Type S 2181 Electrical proportional valve for air Programmable pressure for pneumatic gun 2183 Cable to split box / 7m Specifies floor cable length to split box Example 3: SpotPack for SpotWelding with servo gun gun and parallel interface. Option no Name / Note General options 122 No upper cover on robot control cabinet 201 1pc. Digital 24 VDC I/O 16 inputs/ 16 outputs 251 Internal connection of I/O 206 Internal connection of safety signals Servo gun options 381 Drive unit type DDU-V 702 Robot Gun 681 Connection of servo gun 7m 625 SpotWare Servo (software option for servo guns) DressPack and SpotPack options 60 057 Connection to cabinet Includes floor cables with signals to terminals inside controller 2063 Communication, Parallel communication 2200 SpotWelding to axis 6 Lower arm and Upper arm harness to get the signals to axis 6 675 Connection to cabinet, cable length, Parallel / 7m Specifies floor cable length with parallel interface 2087 Power unit, AC welding type S AC welding with robot handled gun 2090 MFDC welding S and HS Replaces AC welding with MFDC welding 2091 Forced air cooling. Air cooling of MFDC converter 2095 Weld power cable / 7m Specifies power cable for welding Product Specification IRB 6600 M2000 Description 2174 Water and air unit / Type S. 2183 Cable to split box / 7m Specifies floor cable length to split box Example 4: SpotPack for SpotWelding with pedestal servo gun and Interbus interface to robot handled gripper. Option no Name / Note General options 122 No upper cover on robot control cabinet 201 1pc. Digital 24 VDC I/O 16 inputs/ 16 outputs. 251 Internal connection of I/O 206 Internal connection of safety signals Servo gun options 381 Drive unit type DDU-V 701 Stationary Gun. 686 Stationary Servo gun 7m 625 SpotWare Servo (software option for servo guns) DressPack and SpotPack options 057 Connection to cabinet Includes floor cables with signals to terminals inside controller 2064 Communication, Bus communication. 2200 SpotWelding to axis 6 Lower arm and Upper arm harness to get the signals to axis 6 670 Connection to cabinet, cable length, Interbus / 7m Specifies floor cable length with Interbus interface 248 Interbus Master/Slave, Copper wire. Interbus board in cabinet 2087 Power unit, AC welding type HS AC welding with pedestal gun 2095 Weld power cable / 7m Specifies power cable for welding 2117 Process cable to stationary gun, 7m Communication cable to stationary/pedestal gun 2175 Water and air unit / Type HS. 2183 Cable to split box / 7m Specifies floor cable length to split box Product Specification IRB 6600 M2000 61 Description 1.11 Servo Gun (option) The robot can be supplied with hardware and software for Stationary Gun, Robot Gun, Stationary and Robot Gun, Twin Staionary Guns, Stationary Gun and Track Motion or Robot Gun and Track Motion. For configuration and specification of hardware and software respectively, see each section below. 1.11.1 Stationary Gun (SG) M1 M2 CB1 D1 option 381 D2 DDU-V (options 641-644) option 701 M7C1B1.CFG options 686-689 Figure 32 Configuration of Stationary Gun. Options according to Table 17 are required to complete the delivery. For further details see corresponding Product Specification. Table 17 Option 62 Description Product Spec. 381 DDU in a separate box and cable to cabinet S4Cplus 686-689 Cables (7-30m) between DDU and SG S4Cplus 701 Cables inside the manipulator and manipulator foot to SG S4Cplus 625 Software SpotWare Servo RobotWare Options Product Specification IRB 6600 M2000 Description 1.11.2 Robot Gun (RG) option 702 M1 M2 CB1 D1 D2 option 381 option 702 options 2063 DDU-V options 697-699 (options 641-644) Figure 33 Configuration of Robot Gun. Options according to Table 18 below are required to complete the delivery. For further details see corresponding Product Specification. Table 18 Option Description Product Spec. 381 DDU in a separate box and cable to cabinet S4Cplus 697-699 Extended cables (7-30m) between DDU and RG S4Cplus 702 Cabling inside the controller and the manipulator S4Cplus 2063 Parallel communication including Servo IRB 6600 625 Software SpotWare Servo RobotWare Options Product Specification IRB 6600 M2000 63 Description 1.11.3 Stationary and Robot Gun (SG + RG) M1 M2 CB1 options 697-699 options 2063 D1 M1 M2 CB2 D2 D1 D2 option 382 option 703 DDU-VW SMB M7C1B1.CFG (options 641-644) options 686-689 Figure 34 Configuration of Stationary and Robot Gun. Options according to Table 19 below are required to complete the delivery. For further details see corresponding Product Specification. Table 19 Option 64 Description Product Spec. 382 DDU in separate box and cable to the cabinet S4Cplus 686-689 Cables (7-30m) between DDU and SG S4Cplus 697-699 Extended cables (7-30m) between DDU and RG S4Cplus 703 SMB box with cabling S4Cplus 2063 Parallel communication inclusive of Servo IRB 6600 625 Software SpotWare Servo RobotWare Options Product Specification IRB 6600 M2000 Description 1.11.4 Twin Stationary Guns (SG + SG) M1 M2 CB1 D1 M1 M2 CB2 D2 D1 option 382 D2 DDU-VW (options 641-644) M7C1B1.CFG SG 1 options 686-689 SMB SG 2 option 704 Figure 35 Configuration of Twin Stationary Guns. Options according to Table 20 below are required to complete the delivery. For further details see corresponding Product Specification. Table 20 Option Description Product Spec. 382 DDU in separate box and cable to the cabinet S4Cplus 686-689 Cables (7-30m) between DDU and SGs S4Cplus 704 SMB box with cablings S4Cplus 625 Software SpotWare Servo RobotWare Options Product Specification IRB 6600 M2000 65 Description 1.11.5 Stationary Gun and Track Motion (SG + TM) M1 M2 M1 CB1 D1 M2 CB2 D2 D1 option 382 D2 DDU-VW (options 641-644) SMB M7C1B1.CFG options 686-689 option 705 Figure 36 Configuration of Stationary Gun and Track Motion. Options according to Table 21 below are required to complete the delivery. For further details see corresponding Product Specification. Note! Track Motion SMB box and cables to the control cabinet are included in the IRBT 6003S delivery. Table 21 Option 66 Description Product Spec. 382 DDU in separate box and cable to the cabinet S4Cplus 686-689 Cables (7-30m) between DDU and SG S4Cplus 705 Cable between the cabinet and TM, and cable between TM and SG S4Cplus Incl. in TM delivery SMB box with cablings Cable between DDU and TM IRBT 6003S 625 Software SpotWare Servo RobotWare Options Product Specification IRB 6600 M2000 Description 1.11.6 Robot Gun and Track Motion (RG + TM) M1 M2 CB1 D1 M1 M2 CB2 D2 D1 option 382 D2 option 706 options 2063 DDU-VW SMB M7C1B1.CFG (options 641-644) options 697-699 Figure 37 Configuration of Robot Gun and Track Motion. Options according to Table 22 below are required to complete the delivery. For further details see corresponding Product Specification. Note! Track Motion SMB box, cables to the control cabinet and cable between SMB and DDU are included in the IRBT 6003S delivery. Table 22 Option Description Product Spec. 382 DDU in a separate box and cable to the cabinet S4Cplus 697-699 Extended cables (7-30m) between DDU and RG S4Cplus 706 Cable between the cabinet and TM, and between SMB and the manipulator S4Cplus 2063 Parallel communication inclusive of Servo IRB 6600 Incl. in TM delivery SMB box with cablings Cable between DDU and TM IRBT 6003S 625 Software SpotWare Servo RobotWare Options Product Specification IRB 6600 M2000 67 Description 1.12 Track Motion The robot can be supplied with a Track Motion, see Product Specification IRBT 6003S. For configuration and specification of hardware see Figure 38. M1 M2 CB1 D1 M1 M2 CB2 D2 D1 option 2204 or 2200 or 383 option 383 D2 DDU-W M7C1B1.CFG TM delivery (options 641-644) Figure 38 Configuration of Track Motion. Options according to Table 23 below are required to complete the delivery. For further details see corresponding Product Specification. Table 23 Option 68 Description Product Spec. 383 DDU in a separate box and cable to the cabinet S4Cplus 2204 or 2200 Cable from manipulator foot to SMB 7-axis IRB 6600 TM delivery Cable between DDU and TM IRBT 6003S Product Specification IRB 6600 M2000 Specification of Variants and Options 2 Specification of Variants and Options The different variants and options for the IRB 6600 are described below. The same numbers are used here as in the Specification form. For controller options, see Product Specification S4Cplus, and for software options, see Product Specification RobotWare Options. 1 MANIPULATOR VARIANTS 022 023 024 025 027 IRB 6600-175/2.8 IRB 6600-225/2.55 IRB 6600-175/2.55 IRB 6650-125/3.2 IRB 6650-200/2.75 Manipulator colour 330 Standard The manipulator is painted in ABB orange. 352 RAL code Colours according to RAL-codes. Protection 035 Standard (IP 67) 036 Foundry Robot adapted for foundry or other harsh environments. The robot has the FoundryPlus protection which means that the whole manipulator is steam washable. The excellent corrosion protection is obtained by a special coating. The connectors are designed for severe environment, and bearings, gears and other sensitive parts are highly protected. PROCESS CABLE PACKAGE For more information see chapter 1.9.2 DressPack options. 2204 Material Handling from base to axis 3 Requires Communication Parallel or Bus option 2063/2064. See Figure 39, and Description of DressPack on page 37, Table 2, Table 7, Table 8, Table 9 and Table 10. 2205 Material Handling from axis 3 to axis 6 Requires Material Handling from base to axis 3, option 2204, and Communication Parallel or Bus, option 2063/2064. See Figure 39, and Description of DressPack on page 37, Table 2, Table 7, Table 8, Table 9 and Table 10. Product Specification IRB 6600 M2000 69 Specification of Variants and Options 2200 Spot Welding from base to axis 3 Requires Communication Parallel or Bus option 2063/2064. See Figure 40, and Description of DressPack on page 37, Table 3, Table 11, Table 12, Table 13, Table 14, Table 15 and Table 16. 2201 Spot Welding from axis 3 to axis 6 Requires Spot Welding from base to axis 3, option 2200, and communication Parallel or Bus, options 2063/2064. See Figure 40, and Description of DressPack on page 37, Table 3, Table 11, Table 12, Table 13, Table 14, Table 15 and Table 16. option 2204 option 2205 From base to axis 3 From axis 3 to axis 6 Figure 39 Material Handling from base to axis 3, and Material Handling fromaxis 3 to axis 6. option 2200 option 2201 Figure 40 Spot Welding from base to axis 3 , and Spot Welding from axis 3 to axis 6. Communication 2063 Parallel Includes customer power CP, customer signals CS and Air for MH-process cable package. Includes CP, CS, Air and two Media hoses for SW-process cable package. 2064 Bus Includes CP, CS, Air and CAN/DeviceNet or Interbus for MH-process cable package. Includes CP, CS, Air, two Media hoses and CAN/DeviceNet or Interbus for SW-cable package. 70 2065 Extended Media SW Requires communication Parallel or Bus. Includes one Media hose. Only for option 2200 Spot Welding from base to axis 3, and option 2201 Spot Welding from axis 3 to axis 6. Product Specification IRB 6600 M2000 Specification of Variants and Options R1.SW1 R3.FB7 R1.SW2/3 R1.MP R1.SMB R1.PROC1 1 x 1/2” R1.CP/CS Figure 41 Location of MH connections on the foot. R2.CP/CS R2.PROC1 1 x 1/2” R2.MP 5/6 Figure 42 Location of MH connections on axis 3. R1.WELD 3 x 35mm2 R1.CP/CS R1.SW1 R3.FB7 R1.MP R1.SMB R1.SW2/3 R1.PROC1-3 3 x 1/2” Ext. Media SW (option 2065) Figure 43 Location of SW connections on the base. Product Specification IRB 6600 M2000 71 Specification of Variants and Options Connection to 056 Manipulator The signals are connected directly to the manipulator base to one heavy duty industrial housing with a Harting modular connector R1.CP/CS see Figure 41 and Figure 43). The cables from the manipulator base are not supplied. 057 Cabinet The signals CP/CS are connected to 12-pole screw terminals, Phoenix MSTB 2.5/12-ST-5.08, in the controller. The cable between R1.CP/CS and the controller is supplied. For information about the limited number of signals available, see chapter 1.9.2 DressPack options. Connection to cabinet (Cable lengths) Parallel/CANDeviceNet/Interbus/Profibus 675/660/670/665 7m 676/661/671/666 15m 678/663/673/668 30m Robot Servo Gun Extended/Stationary Servo Gun 699/686 697/687 698/689 7m 15m 30m EQUIPMENT 691 Safety lamp A safety lamp with an orange fixed light can be mounted on the manipulator. The lamp is active in MOTORS ON mode. The safety lamp is required on a UL/UR approved robot. 092 Fork lift device Lifting device on the manipulator for fork-lift handling. Note. When Cooling Fan for axis 1 motor unit is used, this must be disassembled in order to use fork lift device. 087 Base plate Can also be used for IRB 7600. See chapter 1.3 Installation, for dimension drawing. 091 Brake release cover A cover for the break release buttons. 113 Cooling fan for axis 1 motor (IP 54) Cannot be combined with Cooling fan for axis 2 motor option 114. For in use recommendations see 1.7 Cooling fan for axis 1-3 motor (option 113-115). See Figure 44. Not for protection Foundry. 72 Product Specification IRB 6600 M2000 Specification of Variants and Options 114 Cooling fan for axis 2 motor (IP 54) For in use recommendations see 1.7 Cooling fan for axis 1-3 motor (option 113-115). Not for protection Foundry. 115 Cooling fan for axis 3 motor (IP 54) For in use recommendations see 1.7 Cooling fan for axis 1-3 motor (option 113-115). See Figure 44. Not for protection Foundry. 088 Upper arm covers Included in protection Foundry. See Figure 45. Option 115 Option 113 Figure 44 Cooling fan for axis 1 motor and axis 3 motor. Option 088 Figure 45 Upper arm covers. Product Specification IRB 6600 M2000 73 Specification of Variants and Options 089 Insulated tool flange The electrically insulated tool flange, according to European Standard EN 60204-1, withstands dangerous voltage (in case of an electrical fault in the spot welding equipment mounted on the Insulated tool flange) of 500V DC during 30 seconds in non water applications without passing it further to the electronics in the manipulator and the controller. Not available together with Protection Foundry, option 036. Connection holes and all dimensions are the same as for the standard tool flange except for the distance from c/c 5th axis to the end surface of the Insulated tool flange. The distance is 0,7 mm longer compared to the standard tool flange, see Figure 46. The countersinked holes for the fastening bolts to the gear box are larger, and the bolts are insulated from the tool flange, see Figure 46. Note The Insulated tool flange option can be ordered in combination with the Absolute Accuracy option, and the robot will then be factory calibrated. When the Insulated tool flange is mounted after the robot delivery, the robot must be re-calibrated for absolute accuracy. 200,7 0,3 Insulated tool flange Figure 46 Insulated tool flange (dimensions in mm). CONNECTION KITS The connectors fit to the connectors at the manipulator base, axis 3 and 6 respectively. The kit consists of connectors, pins and sockets. 2220 R1.CP/CS and PROC1 For the Customer Power/Customer Signal connector and one Process connector on the manipulator base. Sockets for bus communication are included. 2221 R1.WELD and PROC2-4 For the Weld connector and three Process connectors on the manipulator base. 2222 R1.SW1 and SW2/3 For the position switch asis 1 connector and the position axis 2/3 connector on the manipulator base. 74 Product Specification IRB 6600 M2000 Specification of Variants and Options 2223 R3.FB7 For the 7-axis connector on the manipulator base. 2224 R2.CP/CS and PROC1 For the Customer Power/Customer Signal connector and one Process connector at axis 3. Pins for bus communication are included. 2225 R2.WELD and PROC2-4 For the Weld connector and three Process connectors at axis 3. 2070 WELD and PROC1-4 axis 6 Weld connector and four Process connectors at axis 6, the manipulator side. POSITION SWITCHES Position switches indicating the position of the three main axes. Rails with separate adjustable cams are attached to the manipulator. The cams, which have to be adapted to the switch function by the user, can be mounted in any position in the working range for each switch. No machining operation of the cams is necessary for the adaptation, simple hand tools can be used. For axis 1, there are three redundant position zones available, each with two independent switches and cams. For axes 2 and 3, two chanals position zones are available, each with two independent switches and cams. For axis 1 it is possible to mount a second set of position switches, doubling the number of redundant zones to six. Each position zone consists of two switches mechanically operated by separate cams. Each switch has one normally open and one normally closed contact. See Product Specification S4Cplus. The design and components fulfill the demands to be used as safety switches. These options may require external safety arrangements, e.g. light curtains, photocells or contact mats. The switches can be connected either to the manipulator base (R1.SW1 and R1.SW2/ 3, (see Figure 41 and Figure 43), or to the controller. In the controller the signals are connected to screw terminal XT8 Phoenix MSTB 2.5/12-ST-5.08. Switch type Balluff Multiple position switches BNS, according to EN 60947-5-1 and EN 60947-5-2. Connection to 075 Manipulator Connection on the manipulator base with one/two FCI 23-pin connector. 076 Cabinet Connection on the cabinet wall. Limit switch cables are included. Not available for second set of position switches, which have to be connected at the manipulator base. 071 Position switches axis 1 Three redundant position zones are available, each with two independent switches and cams. Product Specification IRB 6600 M2000 75 Specification of Variants and Options Connection of switches axis 1 (cable lengths) 078 7m 079 15m 081 30m 072 Position switches axis 2 Two redundant position zones are available, each with two independent switches and cams. 073 Position switches axis 3 Two redundant position zones are available, each with two independent switches and cams. Connection of switches axes 2 and 3 (cable lengths) 083 7m 084 15m 086 30m Working Range Limit To increase the safety of the robot, the working range of axes 1, 2 and 3 can be restricted by extra mechanical stops. Axis 1, 7,5 degrees 061 Four stops, two which allow the working range to be restricted in increments of 15o and two stops of 7,5o. 062 Axis 1, 15 degrees Two stops which allow the working range to be restricted in increments of 15o. 063 Axis 2 Six stops which allow the working range to be restricted in increments of 15o at both end positions. Each stop decreases the motion by 15o. 064 Axis 3 Six stops which allow the working range to be restricted in increments of 20o at both end positions. Each stop decreases the motion by 20o. SPOTPACK Power Unit For more information see chapter 1.9.3 Power Unit 2087 Power unit AC welding type S 2088 Power unit AC welding type HS 2090 MFDC welding S and HS 2091 Forced air cooling 2092 Contactor for welding power 76 Product Specification IRB 6600 M2000 Specification of Variants and Options Weld power cable 2095 7m 2096 15m Process cable to Stationary Gun 2117 7m 2118 15m 2119 30m Water and Air Fore more information see chapter 1.9.4 Water and Air Unit 2174 Water and Air unit type S 2175 Water and Air unit type HS 2177 Second water return 2192 Digital flow meter, one water return 2193 Digital flow meter, two water returns 2179 Pressure switch and regulator for air 2181 Electrical proportional valve for air Cable to split box 2183 7m 2184 15m 2185 30m Product Specification IRB 6600 M2000 77 Specification of Variants and Options 78 Product Specification IRB 6600 M2000 Accessories 3 Accessories There is a range of tools and equipment available, specially designed for the robot. Basic software and software options for robot and PC For more information, see Product Specification S4Cplus, and Product Specification RobotWare Options. Robot Peripherals - Track Motion - Tool System - Motor Units - Spot welding system for transformer gun Tools Brake release box Includes six brake release buttons and 24V battery unit which can be connected to R1.BU on the manipulator frame. The brake release box can be ordered from ABB Automation Technology Products, Robotics, department S. Calibration Cube This calibration tool can be ordered from ABB Automation Technology Products, Robotics, department S. Product Specification IRB 6600 M2000 79 Accessories 80 Product Specification IRB 6600 M2000 Index 4 Index A accessories 79 Active Brake System 6 C Collision detection 7 colours 69 cooling device 4 E Electronically Stabilised Path 7 emergency stop 8 enabling device 8 equipment mounting 25 permitted extra load 25 F fire safety 9 fork lift device 72 motion 31 mounting extra equipment 25 robot 10 mounting flange 28, 29 N noise level 4 O operating requirements 10 options 69 overspeed protection 7 P Passive Safety System 7 payload 10 position switches 8, 10, 75 protection 69 protection standards 10 R hold-to-run control 9 hole configuration 11 holes for mounting extra equipment 26 humidity 10 range of movement 31 reduced speed 8 Robot Gun 63 Robot Gun and Track Motion 67 Robot Peripherals 79 robot tool flange 28, 29 robot versions 4 I S installation 10 Internal Safety Concept 8 safeguarded space stop 8 delayed 9 safety 6 Safety category 3 8 safety lamp 9, 72 Self Tuning Performance 7 service 30 Service Information System 6 space requirements 4 standards 6 Stationary and Robot Gun 64 Stationary Gun 62 Stationary Gun and Track Motion 66 structure 3 H L lifting device 72 limit switches 8, 10, 75 load 10 load diagrams 13 M maintenance 30 manipulator colour 69 mechanical interface 28, 29 Product Specification IRB 6600 M2000 81 Index T temperature 10 troubleshooting 30 Twin Stationary Guns 65 V variants 69 W weight 4 working space restricting 7, 10, 76 Z zone switches 8 82 Product Specification IRB 6600 M2000 Product Specification S4Cplus CONTENTS Page 1 Description ....................................................................................................................... 3 1.1 Structure.................................................................................................................. 3 1.2 Safety/Standards ..................................................................................................... 5 1.3 Operation ................................................................................................................ 7 Operator’s panel ..................................................................................................... 9 1.4 Memory .................................................................................................................. 11 Available memory .................................................................................................. 11 1.5 Installation .............................................................................................................. 12 Operating requirements.......................................................................................... 12 Power supply.......................................................................................................... 12 Configuration ......................................................................................................... 13 1.6 Programming .......................................................................................................... 13 Movements............................................................................................................. 14 Program management ............................................................................................ 14 Editing programs.................................................................................................... 15 Testing programs.................................................................................................... 15 1.7 Automatic Operation .............................................................................................. 15 1.8 The RAPID Language and Environment................................................................ 16 1.9 Exception handling ................................................................................................. 17 1.10 Maintenance and Troubleshooting ....................................................................... 17 1.11 Robot Motion........................................................................................................ 18 Motion concepts..................................................................................................... 18 Coordinate systems ................................................................................................ 18 Stationary TCP....................................................................................................... 20 Program execution ................................................................................................. 20 Jogging ................................................................................................................... 20 Singularity handling............................................................................................... 20 Motion Supervision................................................................................................ 20 External axes .......................................................................................................... 21 Big Inertia .............................................................................................................. 21 Soft Servo............................................................................................................... 21 1.12 External Axes ....................................................................................................... 21 1.13 I/O System ............................................................................................................ 23 Types of connection ............................................................................................... 24 ABB I/O units (node types) ................................................................................... 24 Distributed I/O ....................................................................................................... 25 Signal data.............................................................................................................. 26 Product Specification S4Cplus M2000/BaseWare OS 4.0 1 Product Specification S4Cplus System signals........................................................................................................ 27 1.14 Communication .................................................................................................... 29 2 Specification of Variants and Options........................................................................... 31 3 Index................................................................................................................................. 51 2 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description 1 Description 1.1 Structure The controller contains the electronics required to control the manipulator, external axes and peripheral equipment. The controller also contains the system software, i.e. the BaseWare OS (operating system), which includes all basic functions for operation and programming. Controller weight 250 kg Controller volume: 950 x 800 x 620 mm Airborne noise level: The sound pressure level outside the working space < 70 dB (A) Leq (acc. to Machinery directive 98/37/EEC) Teach pendant Operator´s panel Mains switch Disk drive Figure 1 The controller is specifically designed to control robots, which means that optimal performance and functionality is achieved. Product Specification S4Cplus M2000/BaseWare OS 4.0 3 Description Air distance to wall 200 200 800 Cabinet extension 800 Option 124 820 Extended cover 500 Option 123 250 950 980 * Lifting points for forklift 500 * Castor wheels, Option 126 71 52 623 Figure 2 View of the controller from the front, from above and from the side (dimensions in mm). 4 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description 1.2 Safety/Standards The robot conforms to the following standards: EN 292-1 Safety of machinery, terminology EN 292-2 Safety of machinery, technical specifications EN 954-1 Safety of machinery, safety related parts of control systems EN 60204 Electrical equipment of industrial machines IEC 204-1 Electrical equipment of industrial machines ISO 10218, EN 775 Manipulating industrial robots, safety ANSI/RIA 15.06/1999 Industrial robots, safety requirements ISO 9787 Manipulating industrial robots, coordinate systems and motions IEC 529 Degrees of protection provided by enclosures EN 50081-2 EMC, Generic emission EN 61000-6-2 EMC, Generic immunity ANSI/UL 1740-1996 (option) Standard for Industrial Robots and Robotic Equipment CAN/CSA Z 434-94 (option) Industrial Robots and Robot Systems - General Safety Requirements The robot complies fully with the health and safety standards specified in the EEC’s Machinery Directives. The robot controller is designed with absolute safety in mind. It has a dedicated safety system based on a two-channel circuit which is monitored continuously. If any component fails, the electrical power supplied to the motors shuts off and the brakes engage. Safety category 3 Malfunction of a single component, such as a sticking relay, will be detected at the next MOTOR OFF/MOTOR ON operation. MOTOR ON is then prevented and the faulty section is indicated. This complies with category 3 of EN 954-1, Safety of machinery - safety related parts of control systems - Part 1. Selecting the operating mode The robot can be operated either manually or automatically. In manual mode, the robot can only be operated via the teach pendant, i.e. not by any external equipment. Reduced speed In manual mode, the speed is limited to a maximum of 250 mm/s (600 inch/min.). The speed limitation applies not only to the TCP (Tool Centre point), but to all parts of the robot. It is also possible to monitor the speed of equipment mounted on the robot. Three position enabling device The enabling device on the teach pendant must be used to move the robot when in manual mode. The enabling device consists of a switch with three positions, meaning that all robot movements stop when either the enabling device is pushed fully in, or when it is released completely. This makes the robot safer to operate. Product Specification S4Cplus M2000/BaseWare OS 4.0 5 Description Safe manual movement The robot is moved using a joystick instead of the operator having to look at the teach pendant to find the right key. Over-speed protection The speed of the robot is monitored by two independent computers. Emergency stop There is one emergency stop push button on the controller and another on the teach pendant. Additional emergency stop buttons can be connected to the robot’s safety chain circuit. Safeguarded space stop The controller has a number of electrical inputs which can be used to connect external safety equipment, such as safety gates and light curtains. This allows the robot’s safety functions to be activated both by peripheral equipment and by the robot itself. Delayed safeguarded space stop A delayed stop gives a smooth stop. The robot stops in the same way as at a normal program stop with no deviation from the programmed path. After approx. 1 second the power supplied to the motors shuts off. Collision detection In case an unexpected mechanical disturbance like a collision, electrode sticking, etc. occurs, the robot will stop and slightly back off from its stop position. Restricting the working space The movement of each axis can be restricted using software limits. There are safeguarded space stops for connection of limit switches to restrict the working space. For some robots the axes 1-3 can also be restricted by means of mechanical stops. Hold-to-run control “Hold-to-run” means that you must depress the start button in order to move the robot. When the button is released the robot will stop. The hold-to-run function makes program testing safer. Fire safety Both the manipulator and control system comply with UL’s (Underwriters Laboratory) tough requirements for fire safety. Safety lamp As an option, the robot can be equipped with a safety lamp mounted on the manipulator. This is activated when the controller is in the MOTORS ON state. 6 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description 1.3 Operation All operations and programming can be carried out using the portable teach pendant (see Figure 3) and operator’s panel (see Figure 5). . Hold-to-run Menu keys Motion keys Display P5 P4 7 4 1 Window keys 1 2 P1 8 5 2 0 9 6 3 Joystick Enabling device P2 P3 Function keys Emergency stop button Navigation keys Cable 10 m Figure 3 The teach pendant is equipped with a large display, which displays prompts, information, error messages and other information in plain English. Information is presented on a display using windows, pull-down menus, dialogs and function keys. No previous programming or computer experience is required to learn how to operate the robot. All operations can be carried out from the teach pendant, which means that an additional keyboard is not required. All information, including the complete programming language, is in English or, if preferred, some other major language. (Available languages, see options on page 35). Display Displays all information during programming, to change programs, etc. 16 text lines with 40 characters per line. Motion keys Select the type of movement when jogging. Navigation keys Used to move the cursor within a window on the display and enter data. Menu keys Display pull-down menus, see Figure 4. Function keys Select the commands used most often. Window keys Display one of the robot’s various windows. These windows control a number of different functions: - Jog (manual operation) - Program, edit and test a program - Manual input/output management Product Specification S4Cplus M2000/BaseWare OS 4.0 7 Description - File management - System configuration - Service and troubleshooting - Automatic operation User-defined keys (P1-P5) Five user-defined keys that can be configured to set or reset an output (e.g. open/close gripper) or to activate a system input. Hold-to-run A push button which must be pressed when running the program in manual mode with full speed. Enabling device A push button which, when pressed halfway in, takes the system to MOTORS ON. When the enabling device is released or pushed all the way in, the robot is taken to the MOTORS OFF state. Joystick The joystick is used to jog (move) the robot manually; e.g. when programming the robot. Emergency stop button The robot stops immediately when the button is pressed in. Menu keys File Edit View 1 Goto ... Inputs/Outputs 2 Goto Top 3 Goto Bottom Name Value I/O list di1 di2 grip1 grip2 clamp3B feeder progno 1 1 0 1 0 1 1 13 Menu 4(6) Line indicator Cursor 0 Function keys Figure 4 Window for manual operation of input and output signals. Using the joystick, the robot can be manually jogged (moved). The user determines the speed of this movement; large deflections of the joystick will move the robot quickly, smaller deflections will move it more slowly. The robot supports different user tasks, with dedicated windows for: - Production 8 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description - Programming - System setup - Service and installation Operator’s panel MOTORS ON button and indicating lamp Operating mode selector Emergency stop If pressed in, pull to release Duty time counter Indicates the operating time for the manipulator (released brakes) MOTORS ON Continuous light Fast flashing light (4Hz) = Ready for program execution = The robot is not calibrated or the revolution counters are not updated Note: The motors have been switched on Slow flashing light (1 Hz) = One of the safeguarded space stops is active Note: The motors have been switched off Operating mode selector Using a key switch, the robot can be locked in two (or three) different operating modes depending on chosen mode selector: Automatic mode = Running production Manual mode at reduced speed = Programming and setup Max. speed 250 mm/s (600 inches/min.) Optional: 100% Manual mode = Testing at full program speed at full speed Equipped with this mode, the robot is not approved according to ANSI/UL Figure 5 The operating mode is selected using the operator’s panel on the controller. Product Specification S4Cplus M2000/BaseWare OS 4.0 9 Description Both the operator’s panel and the teach pendant can be mounted externally, i.e. separated from the cabinet. The robot can then be controlled from there. The robot can be remotely controlled from a computer, PLC or from a customer’s panel, using serial communication or digital system signals. For more information on how to operate the robot, see the User’s Guide. 10 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description 1.4 Memory Available memory The controller has two different memories: - a fixed DRAM memory of size 32 MB, used as working memory - a flash disk memory, standard 64 MB, used as mass memory. Optional 128 MB. The DRAM memory is used for running the system software and the user programs and it is thus divided into three areas: - system software - system software execution data - user RAPID programs, about 5.5 MB, see Figure 6 (when installing different options, the user program memory will decrease, at most by about 0.7 MB). The flash disk is divided into four main areas: - a base area of 5 MB, with permanent code for booting - a release area of 20 MB, where all the code for a specific release is stored - a system specific data area of 10 MB, where all the run time specific data including the user program for a system is stored at backup - a user mass memory area which can be used for storing RAPID programs, data, logs etc. The flash disk is used for backup, i.e. when a power failure occurs or at power off, all the system specific data including the user program, see Figure 6, will be stored on the flash disk and restored at power on. A backup power system (UPS) ensures the automatic storage function. DRAM memory 32 MB Flash disk memory 64/128 MB Boot 5 MB System soft ware Release storage 20 MB Data User RAPID program 5.5 MB System data and user program 10 MB Power on restore Power off store Mass memory area available for the user Figure 6 Available memory. Product Specification S4Cplus M2000/BaseWare OS 4.0 11 Description Several different systems, i.e. process applications, may be installed at the same time in the controller, of which one can be active. Each such application will occupy another 10 MB of the flash memory for system data. The release storage area will be in common as long as the process applications are based on the same release. If two different releases should be loaded, the release storage area must also be doubled. For RAPID memory consumption, see RAPID Developer’s Manual. As an example, a MoveL or MoveJ instruction consumes 236 bytes when the robtarget is stored in the instruction (marked with ‘*’) and 168 bytes if a named robtarget is used. In the latter case, the CONST declaration of the named robtarget consumes an additional 280 bytes. Additional software options will reduce the available user program memory, most of them however only marginally, i.e. the user program area will still be about 5.5 MB. Only the SpotWare option will reduce memory significantly, i.e. down to about 4.8 MB depending on the number of simultaneous welding guns. 1.5 Installation The controller is delivered with a standard configuration for the corresponding manipulator, and can be operated immediately after installation. Its configuration is displayed in plain language and can easily be changed using the teach pendant. Operating requirements Protection standards Controller electronics IEC529 IP54 Explosive environments The controller must not be located or operated in an explosive environment. Ambient temperature Controller during operation with option 473 Controller during transportation and storage, for short periods (not exceeding 24 hours) +5oC (41oF) to +45oC (113oF) +52oC (125oF) -25oC (13oF) to +42oC (107oF) up to +70oC (158oF) Relative humidity Transportation, storage and operation Max. 95% at constant temperature Vibration Controller during transportation and storage Bumps Controller during transportation and storage 10-55 Hz: 55-150 Hz: Max. ±0.15 mm Max. 20 m/s2 Max. 100 m/s2 (4-7 ms) Power supply Mains voltage 12 Mains voltage tolerance 200-600 V, 3p (3p + N for certain options +10%,-15% Mains frequency 48.5 to 61.8 Hz Product Specification S4Cplus M2000/BaseWare OS 4.0 Description Rated power: IRB 140, 1400, 2400 IRB 340, 14001, 24001,4400, 6400, 940 IRB 6600 IRB 7600 External axes cabinet Computer system backup capacity at power interrupt 4.5 kVA (transformer size) 7.8 kVA (transformer size) 6 kVA 7.1 kVA 7.2 kVA (transformer size) 20 sec (rechargeable battery) Configuration The robot is very flexible and can, by using the teach pendant, easily be configured to suit the needs of each user: Authorisation Most common I/O Instruction pick list Instruction builder Operator dialogs Language Date and time Power on sequence EM stop sequence Main start sequence Program start sequence Program stop sequence Change program sequence Working space External axes Brake delay time I/O signal Serial communication Password protection for configuration and program window User-defined lists of I/O signals User-defined set of instructions User-defined instructions Customised operator dialogs All text on the teach pendant can be displayed in several languages Calendar support Action taken when the power is switched on Action taken at an emergency stop Action taken when the program is starting from the beginning Action taken at program start Action taken at program stop Action taken when a new program is loaded Working space limitations Number, type, common drive unit, mechanical units Time before brakes are engaged Logical names of boards and signals, I/O mapping, cross connections, polarity, scaling, default value at start up, interrupts, group I/O Configuration For a detailed description of the installation procedure, see the Product Manual Installation and Commissioning. 1.6 Programming Programming the robot involves choosing instructions and arguments from lists of appropriate alternatives. Users do not need to remember the format of instructions, since they are prompted in plain English. “See and pick” is used instead of “remember and type”. 1. Enlarged transformer for external axes Product Specification S4Cplus M2000/BaseWare OS 4.0 13 Description The programming environment can be easily customized using the teach pendant. - Shop floor language can be used to name programs, signals, counters, etc. - New instructions can be easily written. - The most common instructions can be collected in easy-to-use pick lists. - Positions, registers, tool data, or other data, can be created. Programs, parts of programs and any modifications can be tested immediately without having to translate (compile) the program. Movements A sequence of movements is programmed as a number of partial movements between the positions to which you want the robot to move. The end position of a movement is selected either by manually jogging the robot to the desired position with the joystick, or by referring to a previously defined position. The exact position can be defined (see Figure 7) as: - a stop point, i.e. the robot reaches the programmed position or - a fly-by point, i.e. the robot passes close to the programmed position. The size of the deviation is defined independently for the TCP, the tool orientation and the external axes. Stop point Fly-by point User-definable distance (in mm) Figure 7 The fly-by point reduces the cycle time since the robot does not have to stop at the programmed point. The path is speed independent. The velocity may be specified in the following units: - mm/s - seconds (time it takes to reach the next programmed position) - degrees/s (for reorientation of the tool or for rotation of an external axis) Program management For convenience, the programs can be named and stored in different directories. The mass memory can also be used for program storage. These can then be automatically downloaded using a program instruction. The complete program or parts of programs can be transferred to/from the network or a diskette. The program is stored as a normal PC text file, which means that it can be edited using 14 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description a standard PC. Editing programs Programs can be edited using standard editing commands, i.e. “cut-and-paste”, copy, delete, find and change, undo etc. Individual arguments in an instruction can also be edited using these commands. No reprogramming is necessary when processing left-hand and right-hand parts, since the program can be mirrored in any plane. A robot position can easily be changed either by - jogging the robot with the joystick to a new position and then pressing the “ModPos” key (this registers the new position) or by - entering or modifying numeric values. To prevent unauthorised personnel from making program changes, passwords can be used. Testing programs Several helpful functions can be used when testing programs. For example, it is possible to - start from any instruction - execute an incomplete program - run a single cycle - execute forward/backward step-by-step - simulate wait conditions - temporarily reduce the speed - change a position - tune (displace) a position during program execution. For more information, see the User’s Guide and RAPID Reference Manual. 1.7 Automatic Operation A dedicated production window with commands and information required by the operator is automatically displayed during automatic operation. The operation procedure can be customised to suit the robot installation by means of user-defined operating dialogs. Product Specification S4Cplus M2000/BaseWare OS 4.0 15 Description Select program to run: Front A Front B Front C Other Service Figure 8 The operator dialogs can be easily customised. A special input can be set to order the robot to go to a service position. After service, the robot is ordered to return to the programmed path and continue program execution. You can also create special routines that will be automatically executed when the power is switched on, at program start and on other occasions. This allows you to customise each installation and to make sure that the robot is started up in a controlled way. The robot is equipped with absolute measurement, making it possible to operate the robot directly when the power is switched on. For your convenience, the robot saves the used path, program data and configuration parameters so that the program can be easily restarted from where you left off. Digital outputs are also set automatically to the value prior to the power failure. 1.8 The RAPID Language and Environment The RAPID language is a well balanced combination of simplicity, flexibility and powerfulness. It contains the following concepts: - Hierarchical and modular program structure to support structured programming and reuse. - Routines can be Functions or Procedures. - Local or global data and routines. - Data typing, including structured and array data types. - User defined names (shop floor language) on variables, routines and I/O. - Extensive program flow control. - Arithmetic and logical expressions. - Interrupt handling. - Error handling (for exception handling in general, see Exception handling). - User defined instructions (appear as an inherent part of the system). - Backward handler (user definition of how a procedure should behave when stepping backwards). - Many powerful built-in functions, e.g mathematics and robot specific. - Unlimited language (no max. number of variables etc., only memory limited). Windows based man machine interface with built-in RAPID support (e.g. user defined pick lists). 16 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description 1.9 Exception handling Many advanced features are available to make fast error recovery possible. Characteristic is that the error recovery features are easy to adapt to a specific installation in order to minimise down time. Examples: - Error Handlers (automatic recovery often possible without stopping production). - Restart on Path. - Power failure restart. - Service routines. - Error messages: plain text with remedy suggestions, user defined messages. - Diagnostic tests. - Event logging. 1.10 Maintenance and Troubleshooting The controller requires only a minimum of maintenance during operation. It has been designed to make it as easy to service as possible: - The controller is enclosed, which means that the electronic circuitry is protected when operating in a normal workshop environment. - There is a supervision of temperature, fans and battery health. The robot has several functions to provide efficient diagnostics and error reports: - It performs a self-test when power on is set. - Computer status LEDs and console (serial channel) for fault tracing support. - Errors are indicated by a message displayed in plain language. The message includes the reason for the fault and suggests recovery action. - Faults and major events are logged and time-stamped. This makes it possible to detect error chains and provides the background for any downtime. The log can be read on the teach pendant display, stored in a file or printed on a printer. - There are commands and service programs in RAPID to test units and functions. - LEDs on the panel unit indicate status of the safeguarded switches. Most errors detected by the user program can also be reported to and handled by the standard error system. Error messages and recovery procedures are displayed in plain language. For detailed information on maintenance procedures, see Maintenance section in the Product Manual. Product Specification S4Cplus M2000/BaseWare OS 4.0 17 Description 1.11 Robot Motion Motion concepts QuickMoveTM The QuickMoveTM concept means that a self-optimizing motion control is used. The robot automatically optimizes the servo parameters to achieve the best possible performance throughout the cycle - based on load properties, location in working area, velocity and direction of movement. - No parameters have to be adjusted to achieve correct path, orientation and velocity. - Maximum acceleration is always obtained (acceleration can be reduced, e.g. when handling fragile parts). - The number of adjustments that have to be made to achieve the shortest possible cycle time is minimized. TrueMoveTM The TrueMoveTM concept means that the programmed path is followed – regardless of the speed or operating mode – even after an emergency stop, a safeguarded stop, a process stop, a program stop or a power failure. This very accurate path and speed is based on advanced dynamic modelling. Coordinate systems BaseWare includes a very powerful concept of multiple coordinate systems that facilitates jogging, program adjustment, copying between robots, off-line programming, sensor based applications, external axes co-ordination etc. Full support for TCP (Tool Centre Point) attached to the robot or fixed in the cell (“Stationary TCP”). 18 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description Tool Centre Point (TCP) Y Tool coordinates Z Base coordinates X Y Z Axis 3 Axis 2 Y Axis 3 Y X Base coordinates X Axis 1 Z X Axis 1 Y Tool coordinates Z Tool Centre Point (TCP) Z X Z Z User coordinates Object coordinates Y Y Y X World coordinates X X Figure 9 The coordinate systems, used to make jogging and off-line programming easier. The world coordinate system defines a reference to the floor, which is the starting point for the other coordinate systems. Using this coordinate system, it is possible to relate the robot position to a fixed point in the workshop. The world coordinate system is also very useful when two robots work together or when using a robot carrier. The base coordinate system is attached to the base mounting surface of the robot. The tool coordinate system specifies the tool’s centre point and orientation. The user coordinate system specifies the position of a fixture or workpiece manipulator. The object coordinate system specifies how a workpiece is positioned in a fixture or workpiece manipulator. The coordinate systems can be programmed by specifying numeric values or jogging the robot through a number of positions (the tool does not have to be removed). Each position is specified in object coordinates with respect to the tool’s position and orientation. This means that even if a tool is changed because it is damaged, the old program can still be used, unchanged, by making a new definition of the tool. If a fixture or workpiece is moved, only the user or object coordinate system has to be redefined. Product Specification S4Cplus M2000/BaseWare OS 4.0 19 Description Stationary TCP When the robot is holding a work object and working on a stationary tool, it is possible to define a TCP for that tool. When that tool is active, the programmed path and speed are related to the work object. Program execution The robot can move in any of the following ways: - Joint motion (all axes move individually and reach the programmed position at the same time). - Linear motion (the TCP moves in a linear path). - Circle motion (the TCP moves in a circular path). Soft servo - allowing external forces to cause deviation from programmed position can be used as an alternative to mechanical compliance in grippers, where imperfection in processed objects can occur. If the location of a workpiece varies from time to time, the robot can find its position by means of a digital sensor. The robot program can then be modified in order to adjust the motion to the location of the part. Jogging The robot can be manually operated in any one of the following ways: - Axis-by-axis, i.e. one axis at a time. - Linearly, i.e. the TCP moves in a linear path (relative to one of the coordinate systems mentioned above). - Reoriented around the TCP. It is possible to select the step size for incremental jogging. Incremental jogging can be used to position the robot with high precision, since the robot moves a short distance each time the joystick is moved. During manual operation, the current position of the robot and the external axes can be displayed on the teach pendant. Singularity handling The robot can pass through singular points in a controlled way, i.e. points where two axes coincide. Motion Supervision The behaviour of the motion system is continuously monitored as regards position and speed level to detect abnormal conditions and quickly stop the robot if something is not OK. A further monitoring function, Collision Detection, is optional (see option “Load Identification and Collision Detection”). 20 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description External axes Very flexible possibilities to configure external axes. Includes for instance high performance coordination with robot movement and shared drive unit for several axes. Big Inertia One side effect of the dynamic model concept is that the system can handle very big load inertias by automatically adapting the performance to a suitable level. For big, flexible objects it is possible to optimise the servo tuning to minimise load oscillation. Soft Servo Any axis (also external) can be switched to soft servo mode, which means that it will adopt a spring-like behaviour. 1.12 External Axes The robot can control up to six external axes. These axes are programmed and moved using the teach pendant in the same way as the robot’s axes. The external axes can be grouped into mechanical units to facilitate, for example, the handling of robot carriers, workpiece manipulators, etc. The robot motion can be simultaneously coordinated with for example, a linear robot carrier and a work piece positioner. A mechanical unit can be activated or deactivated to make it safe when, for example, manually changing a workpiece located on the unit. In order to reduce investment costs, any axes that do not have to be active at the same time, can share the same drive unit. An external axis is an AC motor (IRB motor type or similar) controlled via a drive unit mounted in the robot cabinet or in a separate enclosure. See Specification of Variants and Options. Resolver Resolver supply Connected directly to motor shaft Transmitter type resolver Voltage ratio 2:1 (rotor: stator) 5.0 V/4 kHz Absolute position is accomplished by battery-backed resolver revolution counters in the serial measurement board (SMB). The SMB is located close to the motor(s) according to Figure 10. For more information on how to install an external axis, see the User’s Guide - External Axes. External axes for robot types IRB 4400 and IRB 6400X: When more than one external axis is used, the drive units for external axis 2 and upwards must be located in a separate cabinet as shown in Figure 10. Product Specification S4Cplus M2000/BaseWare OS 4.0 21 Description External axes for robot types IRB 140, IRB 1400, and IRB 2400: When more than three external axes are used, the drive units for external axis 4 and upwards must be located in a separate cabinet as shown in Figure 10. External axes for robot types IRB 6600 and IRB 7600: The drive units for all external axes must be located in a separate cabinet as shown in Figure 10. Not supplied on delivery Motor channel Serial signals for measurement and drive system Single External Axes SMB Measurement System 1 Not supplied on delivery Multiple External Axes SMB alt. Measurement System 2 Drive System 2 ABB Drives Figure 10 Outline diagram, external axes. 22 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description 1.13 I/O System A distributed I/O system is used, based on the fieldbus standard CAN/DeviceNet. This makes it possible to mount the I/O units either inside the cabinet or outside the cabinet with a cable connecting the I/O unit to the cabinet. Two independent CAN/DeviceNet buses allow various conditions of I/O handling. Both channels can be operating as master or slave. One bus, CAN1, is operating with fixed data rate, and the other, CAN2 (accessible by the software option I/O Plus), with different data rates. tap thick/thin cable S4Cplus multiport-tap R trunk line R node thick/thin cable node node I/O CPU node Daisy chain node node node node R = terminating resistor short drop max. 6m each Figure 11 Example of a general DeviceNet bus. A number of different input and output units can be installed: - Digital inputs and outputs. - Analog inputs and outputs. - Gateway (slave) for Allen-Bradley Remote I/O. - Gateway (slave) for Interbus Slave. - Gateway (slave) for Profibus DP Slave. S4Cplus with the option I/O Plus can be configured for fieldbus units from other suppliers. For more details see the Product Specification RobotWare Options. The inputs and outputs can be configured to suit your installation: - Each signal and unit can be given a name, e.g. gripper, feeder. - I/O mapping (i.e. a physical connection for each signal). - Polarity (active high or low). - Cross connections. - Up to 16 digital signals can be grouped together and used as if they were a single signal when, for example, entering a bar code. - Sophisticated error handling. - Selectable “trust level” (i.e. what action to take when a unit is “lost”). Product Specification S4Cplus M2000/BaseWare OS 4.0 23 Description - Program controlled enabling/disabling of I/O units. - Scaling of analog signals. - Filtering. - Polarity definition. - Pulsing. - TCP-proportional analog signal. - Programmable delays. - Simulated I/O (for forming cross connections or logical conditions without need the for physical hardware). - Accurate coordination with motion. Signals can be assigned to special system functions, such as program start, so as to be able to control the robot from an external panel or PLC. The robot can function as a PLC by monitoring and controlling I/O signals: - I/O instructions are executed concurrent to the robot motion. - Inputs can be connected to trap routines. (When such an input is set, the trap routine starts executing. Following this, normal program execution resumes. In most cases, this will not have any visible effect on the robot motion, i.e. if a limited number of instructions are executed in the trap routine.) - Background programs (for monitoring signals, for example) can be run in parallel with the actual robot program. Requires Multitasking option, see Product Specification RobotWare. Manual functions are available to: - List all the signal values. - Create your own list of your most important signals. - Manually change the status of an output signal. - Print signal information on a printer. I/O signals can for some robots also be routed parallel or serial to connectors on the upper arm of the robot. Types of connection The following types of connection are available: - “Screw terminals” on the I/O units - Industrial connectors on cabinet wall - Distributed I/O-connections inside or on cabinet wall For more detailed information, see Chapter 2, Specification of Variants and Options. ABB I/O units (node types) Several I/O units can be used. The following table shows the maximum number of physical signals that can be used on each unit. Data rate is fixed at 500 Kbit/s. 24 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description Digital Analog Type of unit DSQC Option no. In Out Digital I/O 24 VDC 328 20x 16 16 Internal/External1 Digital I/O 120 VAC 320 25x 16 16 Internal/External Analog I/O 355 22x AD Combi I/O 327 23x 16 16 Relay I/O 332 26x 16 16 Allen-Bradley Remote I/O Slave 350 241 1282 128 Interbus Slave 351 242-285 642 64 Profibus DP Slave 352 243-287 1282 128 100 100 Simulated I/O3 Encoder interface unit4 Encoder interface unit5 354 244 377 249 Voltage inputs Voltage output 4 3 2 Current output 1 Power supply Internal Internal/External1 Internal/External1 30 30 1 1. The digital signals are supplied in groups, each group having 8 inputs or outputs. 2. To calculate the number of logical signals, add 2 status signals for Allen-Bradley Remote I/O unit and 1 for Interbus and Profibus DP. 3. A non physical I/O unit can be used to form cross connections and logical conditions without physical wiring. No. of signals are to be configured. Some ProcessWares include SIM unit. 4. Dedicated for conveyor tracking only. 5. Only for PickMaster 4.0 Distributed I/O The maximum number of logical signals is 1024 in total for the CAN/DeviceNet buses (inputs or outputs, group I/O, analog and digital including field buses) CAN1 Max. total no of units* Data rate (fixed) Max. total cable length Cable type (not included) CAN2 (option) 20 (including SIM units) 20 500 Kbit/s 125/250/500 Kbit/s. 100 m trunk + 39m drop up to 500m According to DeviceNet specification release 1.2 * Max. four units can be mounted inside the cabinet. Product Specification S4Cplus M2000/BaseWare OS 4.0 25 Description Signal data Permitted customer 24 V DC load Digital inputs 24 V DC max. 7,5 A (option 201/203) Optically-isolated Rated voltage: 24 V DC Logical voltage levels: “1” 15 to 35 V “0” -35 to 5 V Input current at rated input voltage: 6 mA Potential difference: max. 500 V Time delays: hardware 5−15 ms software ≤ 3 ms Time variations: ± 2 ms Digital outputs (option 201/203) 24 V DC Optically-isolated, short-circuit protected, supply polarity protection Voltage supply 19 to 35 V Rated voltage 24 V DC Logical voltage levels: “1” 18 to 34 V “0” <7V Output current: max. 0.5 A Potential difference: max. 500 V Time delays: hardware ≤ 1 ms software ≤ 2 ms Time variations: ± 2 ms Relay outputs Digital inputs 120 V AC 26 (option 205) Single pole relays with one make contact (normally open) Rated voltage: 24 V DC, 120 VAC Voltage range: 19 to 35 V DC 24 to 140 V AC Output current: max. 2 A Potential difference: max. 500V Time intervals: hardware (set signal) typical 13 ms hardware (reset signal) typical 8 ms software ≤ 4 ms (option 204) Optically isolated Rated voltage Input voltage range: “1” Input voltage range: “0” Input current (typical): Time intervals: hardware software 120 V AC 90 to 140 V AC 0 to 45 V AC 7.5 mA ≤ 20 ms ≤ 4 ms Product Specification S4Cplus M2000/BaseWare OS 4.0 Description Digital outputs 120 V AC (option 204) Optically isolated, voltage spike protection Rated voltage 120 V AC Output current: max. 1A/channel, 12 A 16 channels or max. 2A/channel, 10 A 16 channels (56 A in 20 ms) min. 30mA Voltage range: 24 to 140 V AC Potential difference: max. 500 V Off state leakage current: max. 2mA rms On state voltage drop: max. 1.5 V Time intervals: hardware ≤ 12 ms software ≤ 4 ms Analog inputs (option 202) Voltage Input voltage: +10 V Input impedance: >1 Mohm Resolution: 0.61 mV (14 bits) Accuracy: +0.2% of input signal Analog outputs Analog outputs (option 202) VoltageOutput voltage: Load impedance: Resolution: CurrentOutput current: Load impedance: Resolution: Accuracy: min. min. +10 V 2 kohm 2.44 mV (12 bits) 4-20 mA 800 ohm 4.88 µA (12 bits) +0.2% of output signal (option 203) Output voltage (galvanically isolated): Load impedance: min. Resolution: Accuracy: Potential difference: Time intervals: hardware software 0 to +10 V 2 kohm 2.44 mV (12 bits) ±25 mV ±0.5% of output voltage max. 500 V ≤ 2.0 ms ≤ 4 ms System signals Signals can be assigned to special system functions. Several signals can be given the same functionality. Digital outputs Motors on/off Executes program Error Automatic mode Emergency stop Restart not possible Run chain closed Product Specification S4Cplus M2000/BaseWare OS 4.0 27 Description Digital inputs Motors on/off Starts program from where it is Motors on and program start Starts program from the beginning Stops program Stops program when the program cycle is ready Stops program after current instruction Executes “trap routine” without affecting status of stopped regular program1 Loads and starts program from the beginning1 Resets error Resets emergency stop System reset Analog output TCP speed signal 1. Program can be decided when configuring the robot. For more information on system signals, see User’s Guide - System Parameters. 28 Product Specification S4Cplus M2000/BaseWare OS 4.0 Description 1.14 Communication The controller has three serial channels for permanent use - two RS232 and one RS422 Full duplex - which can be used for communication point to point with printers, terminals, computers and other equipment. For temporary use, like service, there are two more RS 232 channels. The serial channels can be used at speeds up to 19,200 bit/s (max. 1 channel with speed 19,200 bit/s). The controller has two Ethernet channels and both can be used at 10 Mbit/s or 100 Mbit/s. The communication speed is set automatically. Temporary Main CPU console Ethernet 10 Mbit/s Permanent Ethernet or serial Figure 12 Point-to-point communication. The communication includes TCP/IP with intensive network configuration possibilities like: - DNS, DHCP etc. (including multiple gateway) - Network file system accesses using FTP/NFS client and FTP server - Control and/or monitoring of controllers with RAP protocol makes it possible to use OPC, ActiveX, and other APIs for integration with Window applications - Boot/upgrading of controller software via the network or a portable PC. Figure 13 Network (LAN) communication. Product Specification S4Cplus M2000/BaseWare OS 4.0 29 Description 30 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options 2 Specification of Variants and Options The different variants and options for the controller are described below. The same numbers are used here as in the Specification form. For manipulator options, see Product Specification respectively, and for software options, see Product Specification RobotWare Options. 1 SAFETY STANDARDS EU - Electromagnetic Compatibility 693 The controller complies with the European Union Directive “Electromagnetic Compatibility” 89/336/EEC. This option is required by law for end users in the European Union. UNDERWRITERS LABORATORY 695 UL/CSA The robot is certified by Underwriters Laboratory to comply with the Safety Standard ANSI/UL 1740-1996 “Industrial Robots and Robotic Equipment” and CAN/CSA Z 434-94. UL/UR certification is required by law in some US states and Canada. UL (UL/CSA) means certification of complete product and UR (UL recognized Component) means certification of component or not complete product. Safety lamp (691) Door interlock (145 or 142) Operating mode selector standard 2 modes (193) are mandatory. Not with Cabinet height 950 mm no cover (122), Cabinet height 1200 mm (123), Cabinet height 1750 mm (124), Cabinet variant Prepared for Arcitec (112), Mains connection type CEE17 connector (132, 133), Service outlet type 230V Europe (412). 696 UR (UL Recognized) The robot is certified by Underwriters Laboratory to comply with the Safety Standard UL 1740 “Industrial Robots and Robotic Equipment”. UL/UR certification is required by law in some US states and Canada. UL (UL listed) means certification of complete product and UR (UL Recognized Component) means certification of component or not complete product. Safety lamp (691), Door interlock (145 or 142), Operating mode selector standard 2 modes (193) are mandatory. Not with Cabinet variant Prepared for Arcitec (112), Mains connection type CEE17 connector (132, 133), Service outlet type 230V Europe (412). Product Specification S4Cplus M2000/BaseWare OS 4.0 31 Specification of Variants and Options 2 CONTROL SYSTEM CABINET Variant 111 Standard cabinet with upper cover. 112 Prepared for Arcitec Rotary switch 80A (143) and Circuit breaker standard (147) and Arcitec 4.0 (556) are mandatory. Not with Wheels (126) or Mains connection type CEE17 connector (132, 133) or 6HSB (134) or Mains switch Flange disconnector (142) or Servo disconnector (144) or UL (695) or UR (696). Cabinet Height (wheels not included in height) 121 Standard cabinet 950 mm with upper cover. 122 Standard cabinet 950 mm without upper cover. To be used when cabinet extension is mounted on top of the cabinet after delivery. Not with Door interlock (145) or UL (695) or UR (696). 123 Standard cabinet with 250 mm extension. The height of the cover increases the available space for external equipment that can be mounted inside the cabinet. Not with UL (695). 124 Standard cabinet with 800 mm extension. The extension is mounted on top of the standard cabinet. There is a mounting plate inside. (See Figure 14). The cabinet extension is opened via a front door and it has no floor. The upper part of the standard cabinet is therefore accessible. Not with UL (695) and Servo disconnector (144). 20 665 9 (x4) 690 730 20 705 Figure 14 Mounting plate for mounting of equipment (dimensions in mm) 126 Cabinet on wheels. Increase the height by 30 mm. Not with Prepared for Arcitec (112). 32 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options OPERATOR’S PANEL The operator’s panel and teach pendant holder can be installed in different ways. 181 Standard, i.e. on the front of the cabinet. 182 External, i.e. in a separate operator’s unit. (See Figure 15 for required preparation) All necessary cabling, including flange, connectors, sealing strips, screws, etc., is supplied. External enclosure is not supplied. 183 External, mounted in a box. (See Figure 16) M4 (x4) M8 (x4) o 45 Required depth 200 mm 196 193 180 224 240 223 70 62 140 96 Holes for flange 184 200 Holes for operator’s panel External panel enclosure (not supplied) Holes for teach pendant holder Teach pendant connection Connection to the controller 90 5 (x2) 155 Figure 15 Required preparation of external panel enclosure (all dimensions in mm). Product Specification S4Cplus M2000/BaseWare OS 4.0 33 Specification of Variants and Options M5 (x4) for fastening of box 337 Connection flange 370 Figure 16 Operator’s panel mounted in a box (all dimensions in mm). OPERATOR’S PANEL CABLE 185 15 m 186 22 m 187 30 m DOOR KEYS 461 462 463 464 466 Standard Doppelbart Square outside 7 mm EMKA DB Locking cylinder 3524 OPERATING MODE SELECTOR 193 Standard, 2 modes: manual and automatic. 191 Standard, 3 modes: manual, manual full speed and automatic. Does not comply with UL and UR safety standards. CONTROLLER COOLING 472 Ambient temperature up to 45oC (113oF) Standard design. The computer unit is provided with a passive heat exchanger (cooling fins on the rear part of the box). 473 Ambient temperature up to 52oC (125oF) The computer unit is provided with an active Peltier cooling equipment (replaces the cooling fins from option 472. 34 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options TEACH PENDANT 601 Teach pendant with back lighting, connection cable 10 m. Teach pendant language: 611 612 613 614 615 616 617 618 619 620 621 622 English Swedish German French Spanish Portuguese Danish Italian Dutch Japanese Czech Finnish Extension cable for the teach pendant: 606 10 m An extension cable can be connected between the controller and the teach pendant. The total length of cable between the controller and the teach pendant should not exceed 30 m. Note that the length of the optional operator’s panel cable must be included in the limitation. 607 20 m MAINS VOLTAGE The control system can be connected to a rated voltage of between 200 V and 600 V, 3-phase and protective earthing. A voltage fluctuation of +10% to -15% is permissible. 151 152 153 154 155 156 157 158 200V 220V 400V 440V 475V 500V 525V 600V For all robots except for IRB 6600/7600 the voltage range must be specified. This gives the possibility to select between three different transformers. 162 Voltage range 200, 220, 400, 440V 163 Voltage range 400, 440, 475, 500V 164 Voltage range 475, 500, 525, 600V The robots IRB 7600 (all versions) and IRB 6650-125/3.2 are supplied with an external transformer, see Figure 17, except for the option 155. The mains voltage 475V does not need any drive system transformer. Product Specification S4Cplus M2000/BaseWare OS 4.0 35 Specification of Variants and Options 560 300 398 Figure 17 Transformer unit (dimensions in mm). MAINS CONNECTION TYPE The power is connected either inside the cabinet or to a connector on the cabinet’s left-hand side. The cable is not supplied. If option 133-136 is chosen, the female connector (cable part) is included. 131 Cable gland for inside connection. Diameter of cable: 11-12 mm. 132 CEE17-connector 32 A, 380-415 V, 3p + PE (see Figure 18). Not with Flange disconnector (142) or UL/UR (695/696) or Service outlet power supply (432). Not available for IRB 6600/7600. Figure 18 CEE male connector. 133 32 A, 380-415 V, 3p + N + PE (see Figure 18). Not with Flange disconnector (142) or UL/UR (695/696). Not available for IRB 6600/7600. 134 Connection via an industrial Harting 6HSB connector in accordance with DIN 41640. 35 A, 600 V, 6p + PE (see Figure 19). Cannot be combined with Flange disconnector (142). Figure 19 DIN male connector. MAINS SWITCH 141 Rotary switch 40 A in accordance with the standard in section 1.2 and IEC 337-1, VDE 0113. Customer fuses for cable protection required. 142 Flange disconnector in accordance with the standard in section 1.2. Includes door interlock for flange disconnector and a 20A circuit breaker with interrupt capacity 14 kA. 0058 Flange disconnector in accordance with the standard in section 1.2. Includes door interlock for flange disconnector and a 20A circuit breaker with interrupt 36 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options 143 144 145 147 capacity 65 kA at 400V, 25 kA at 600V. Rotary switch 80 A. Customer fuses for cable protection required. Included in the option Prepared for Arcitec (112). Servo disconnector. This option adds a rotary switch 40 A to the two contactors in the AC power supply for the drive system. The handle can be locked by a padlock, e.g. in an off position. Door interlock for rotary switch. Included in the options UL/CSA/UR (695, 696) and Servo disconnector (144). Circuit breaker for rotary switch. A 16A (option 163 and 164) or 25A (option 162) circuit breaker for short circuit protection of mains cables in the cabinet. Circuit breaker approved in accordance with IEC 898, VDE 0660. Interrupt capacity 6 kA. Product Specification S4Cplus M2000/BaseWare OS 4.0 37 Specification of Variants and Options I/O INTERFACES The standard cabinet can be equipped with up to four I/O units. For more details, see page 23. X6 (CAN 1.2) X7 (CAN 1.3) X8 (CAN 2) Base Connector Unit DSQC 504 CAN 1 NS MS Ph.5-Pol X7 CAN 1.3 X10 SIO1 Test 9-Pol D-sub X15 CAN 1.1 X12 PANEL BOARD X20 DRIVE SYSTEM 2 R E L Ä Ph.5-Pol 8-Pol DB-44 9-Pol D-sub X1 I/O COMPUTER X11 CONSOLE X9 SIO2 X15 (CAN 1.1) Ph.5-Pol 15-Pol D-sub 9-Pol D-sub X9 (COM3, RS422) X8 CAN 2 Ph.5-Pol X5 MEASUREMENT SYSTEM 2 X2 AXIS COMPUTER X6 CAN 1.2 25-Pol D-sub X10 (COM2, RS232) CAN 2 NS MS X4 MEASUREMENT SYSTEM 1 15-Pol D-sub 15-Pol D-sub 15-Pol Female FCI X3 DRIVE SYSTEM 1 X14 EXPANSION BOARD 15-Pol Male FCI 25-Pol D-sub X13 POWER SUPPLY Cabinet view from above I/O Units (X4) Computer system (COM1, RS232) XT 31 (24V I/O) Panel Unit WARNING DSQC 509 Manipulator connections X1-X4 Safety Signals 115/230 VAC REMOVE JUMPERS BEFORE CONNECTING ANY EXTERNAL EQUIPMENT EN MS NS ES1 ES2 GS1 GS2 AS1 AS2 X3 X1-X4 CUSTOMER CONNECTIONS X1 X2 X4 POWER UNIT / POWER CONTROL X5 X8 1 XP5 XP58 1 1 1 X9, BASE CONN UNIT XP6 1 RL2 X7, TEACH PENDANT XT21 Connection to Position switches X6, CONTROL PANEL RL1 XP8 Connection to Customer power Customer signals Figure 20 I/O unit and screw terminal locations. 38 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options 201 Digital 24 VDC I/O: 16 inputs/16 outputs. 202 Analog I/O: 4 inputs/4 outputs. 203 AD Combi I/O: 16 digital inputs/16 digital outputs and 2 analog outputs (0-10V). 204 Digital 120 VAC I/O 16 inputs/16 outputs. 205 Digital I/O with relay outputs: 16 inputs/16 outputs. Relay outputs to be used when more current or voltage is required from the digital outputs. The inputs are not separated by relays. Connection of I/O 251 Internal connection (options 201-204, 221-224, 231-234, 251-254, 261-264) The signals are connected directly to screw terminals on the I/O units in the upper part of the cabinet (see Figure 20). 252 External connection The signals are connected via 64-pole standard industrial connector in accordance with DIN 43652. The connector is located on the left-hand side of the controller. Corresponding customer part is included. 208 Prepared for 4 I/O units The internal CAN/Devicenet cabling to the I/O units exists in two versions, one for up to two I/O units and one for up to four I/O units. The versions are selected to match the number of ordered I/O units. By this option it is possible to get the four unit version even if less than three I/O units are ordered. SAFETY SIGNALS 206 Internal connection The signals are connected directly to screw terminals in the upper part of the cabinet (see Figure 20). 207 External connection The signals are connected via 64-pole standard industrial connector in accordance with DIN 43652. The connector is located on the left-hand side of the controller. Corresponding customer part is included. FIELD BUS AND COMMUNICATION 245 CAN/DeviceNet Connection on the left side to two 5-pole female connectors in accordance with ANSI. (Male connectors are supplied). 240 LAN/Ethernet RJ45 connector to be used for LAN connector. (When the connector is not used, a protective hood covers it). 246 Profibus DP Master/Slave The hardware of the Profibus-DP field bus consists of a master/slave unit, DSQC 510, and distributed I/O units, called slave units. The DSQC 510 unit is mounted in the S4Cplus computer system where it is connected to the PCI bus while the slave units are attached to the field bus network. Product Specification S4Cplus M2000/BaseWare OS 4.0 39 Specification of Variants and Options The slave units can be I/O units with digital and/or analogue signals. They are all controlled via the master part of the DSQC 510 unit. The slave part of the DSQC 510 is normally controlled by an external master on a separate Profibus-DP network. This network is a different one than the network holding the slave units for the master part of the board. The slave part is a digital input and output I/O unit with up to 512 digital input and 512 digital output signals. The signals are connected to the board front (two 9-pole D-sub). 19 units (internal or external) can be connected to the cabinet. Profibus DP M/S CFG Tool (option 270) is required when setting up the master part or when changing the number of signals for the slave part. For more information see Product Specification RobotWare Options. 247/248 Interbus Master/Slave The hardware of the Interbus field bus consists of a Master/Slave unit (DSQC512/529) and distributed I/O units. The master and the slave units are two separate boards connected by a flat cable. The DSQC512/529 unit is connected to the S4Cplus robot controller PCI bus while the I/O units are attached to the field bus net. The I/O units may be digital or analog modules. They are all controlled by the master part of the DSQC512/529 unit. The slave part of the DSQC512/529 unit is normally controlled by an external master on a separate Interbus network. This network is a different one than the network hold ing the I/O units for the master part of the board. The slave part is a digital in- and out put I/O unit with up to 160 digital in- and 160 digital out signals. Two variants are available: 247 for optical fibre connection (DSQC512) 248 for copper wire connection (DSQC529) Interbus M/S CFG Tool (option 271) is required when setting up the master part or when changing the number of signals for the slave part. For more information see Product Specification RobotWare Options. GATEWAY UNITS For more details, see I/O System on page 23. 241 Allen-Bradley Remote I/O Up to 128 digital inputs and outputs, in groups of 32, can be transferred serially to a PLC equipped with an Allen Bradley 1771 RIO node adapter. The unit reduces the number of I/O units that can be mounted in cabinet by one. The field bus cables are connected directly to the A-B Remote I/O unit in the upper part of the cabinet (see Figure 20). Connectors Phoenix MSTB 2.5/xx-ST-5.08 or equivalent are included. 242 Interbus Slave Up to 64 digital inputs and 64 digital outputs can be transferred serially to a PLC equipped with an InterBus interface. The unit reduces the number of I/O units that can be mounted in the cabinet by one. The signals are connected directly to the InterBus slave unit (two 9-pole D-sub) in the upper part of the cabinet. 40 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options 243 Profibus DP Slave Up to 128 digital inputs and 128 digital outputs can be transferred serially to a PLC equipped with a Profibus DP interface. The unit reduces the number of I/O units that can be mounted in the cabinet by one. The signals are connected directly to the Profibus DP slave unit (one 9-pole D-sub) in the upper part of the cabinet. 244 Encoder interface unit for conveyor tracking (DSQC 354) Conveyor Tracking, RobotWare option 540, is the function whereby the robot follows a work object which is mounted on a moving conveyor. The encoder and synchronization switch cables are connected directly to the encoder unit in the upper part of the cabinet (see Figure 20). Screw connector is included. This option is also required for the function Sensor Synch, RobotWare option 547. 249 Encoder interface unit for conveyor tracking (DSQC 377) Only available for IRB 140 and IRB 340, required for PickMaster 4.0. Physically similar to option 344. EXTERNAL I/O UNITS I/O units can be delivered separately. The units can then be mounted outside the cabinet or in the cabinet extension. These are connected in a chain to a connector (CAN 3 or CAN 2, see Figure 20) in the upper part of the cabinet. Connectors to the I/O units and a connector to the cabinet (Phoenix MSTB 2.5/xx-ST-5.08), but no cabling, is included. Dimensions according to Figure 21 and Figure 22. For more details, see I/O System on page 23. 221 Digital I/O 24 V DC: 16 inputs/16 outputs. 222 Analog I/O. 223 AD Combi I/O: 16 digital inputs/16 digital outputs and 2 analog outputs (0-10V). 224 Digital I/O 120 V AC: 16 inputs/16 outputs. 225 Digital I/O with relay outputs: 16 inputs/16 outputs. EXTERNAL GATEWAY UNITS 231 Allen Bradley Remote I/O 232 Interbus Slave 233 Profibus DP Slave 234 Encoder interface unit DSQC 354 for conveyor tracking 235 Encoder interface unit DSQC 377 for conveyor tracking (IRB 140 and IRB 340 only) Product Specification S4Cplus M2000/BaseWare OS 4.0 41 Specification of Variants and Options EN 50022 mounting rail 195 203 49 Figure 21 Dimensions for units 221-225. EN 50022 mounting rail 170 49 115 Figure 22 Dimension for units 231-234. EXTERNAL AXES IN ROBOT CABINET (not available for IRB 340, IRB 6400PE, IRB 6600, IRB 7600) It is possible to equip the controller with drives for external axes. The motors are connected to a standard industrial 64-pin female connector, in accordance with DIN 43652, on the left-hand side of the cabinet. (Male connector is also supplied.) 391 Drive unit C The drive unit is part of the DC-link. Recommended motor type see Figure 23. Not available for IRB 640. 392 Drive unit T The drive unit is part of the DC-link. Recommended motor type see Figure 23. Not available for IRB 640, 6400R. 397 Drive unit U The drive unit is part of the DC-link. Recommended motor types see Figure 23. Not available for IRB 4400, 6400S, 6400PE, 640. For IRB 140, 1400 and 2400 the option consists of a larger transformer, DC link DC4U with integrated U drive unit and one extra axis computer with its connection board. 42 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options No cabling from the drive unit U to cabinet wall is included. For IRB 6400R the option consists of a DC link DC4U with integrated U drive unit with cabling to the cabinet wall. 393 Drive unit GT A separate drive unit including two drives. Recommended motor type see Figure 23. Not available for IRB 4400, 6400R, 6400S 396 Prepared for drives GT The same as 393 but without the GT drive module. The preparation includes; larger transformer, larger DC link DC2, and one additional axis computer with its connection board. Not available for IRB 4400, 640, 6400R, 6400S 398 Prepared for drives GT The same as 396 but without additional axes computer and connection board. 399 Prepared for drives GU The same as 396 but intended for a GU drive module. The preparation includes: larger transformer, larger DC link DC4, and one additional axis computer with its connection board. Not available for IRB 4400, 640, 6400R, 6400S. 394 Drive unit T+GT A combination of 392 and 393. Not available for IRB 4400, 640, 6400R, 6400S 395 Drive unit C+GT A combination of 391 and 393 Not available for IRB 4400, 640, 6400R, 6400S 365 Trackmotion A special wiring for the three motor combination 394 (IRB 140, 1400, 2400 only) to be used when axis 7 is intended for an ABB Trackmotion. The drive unit in the DC link and the Trackmotion measurement board is then connected to the robot axes computer 1 while the drive unit and the measurement board for motor 8 and 9 is connected to axes computer 2. All motor power wiring is routed to one common connector, XS7. 701-706 Servo gun interfacing (IRB 6400R, IRB 6600 and 7600) For further information see the Product Specification IRB 6400R chapter Servo Gun or IRB 6600 chapter Servo Gun (overview), and the Product Specification RobotWare Options (function description). 701 Stationary gun (SG) IRB 6400R The option consists of an encapsulated Serial Measurement Board (SMB) and cabling inside the controller. The cabling between SMB and the controller is selected in the option range 686689. Drive unit 397 is required. IRB 6600/7600 The option includes cabling inside the controller and the manipulator, and a 7m resolver cable between the manipulator and the welding gun pedestal. The customer connector to this cable should be an 8-pin Burndy, wired according to Motor Unit Product Specification S4Cplus M2000/BaseWare OS 4.0 43 Specification of Variants and Options specification. The cable between the controller DDU and the welding gun pedestal is selected in the option range 686-687 (different lengths). The customer connector to this cable should be of Industrial Multi-connector type, corresponding to the manipulator CP/CS (see Product Specification IRB 6600/7600). Besides the necessary motor wiring, it also contains 12 wires for gun I/O, accessible on screw terminals in the cabinet. Drive unit 381 (DDU-V) must be selected. 702 Robot Gun (RG) IRB 6400R The option consists of an encapsulated SMB and cabling inside the controller. It also includes bracket for 6400R foot mounting of the SMB box, and cabling between the SMB box and the manipulator. The cabling between SMB and the controller is selected in th option range 681-684. Drive unit option 397 is required. IRB 6600/7600 The option includes cabling inside the controller and the manipulator. The cable between the controller and the manipulator is selected in the option range 697-699. Besides the necessary motor wiring the cable also contains 22 wires for gun I/O and CAN/DeviceNet fieldbus. The I/O wiring is accessible on screw terminals in the cabinet. Drive unit 381 (DDU-V) must be selected. 703 One SG and one RG IRB 6400R The option is a combination of 701 and 702. A distributed drive unit (DDU) controls the SG motor. The cabling between the SG SMB and the controller is selected in the option range 686-689, and the cabling between the RG SMB and the controller is selected in the option range 681-684. Drive unit options 397 (for the RG) and 380 (for the SG) are required. IRB 6600/7600 The option includes cabling inside the controller and the manipulator. The cable between the controller and the welding gun pedestal is selected in the option range 686-687. The customer connector to this cable should be of Industrial Multi-connector type, corresponding to the manipulator CP/CS (see Product Specification IRB 6600/ 7600). Besides the necessary motor wiring it also contains 12 wires for gun I/O, accessible on screw terminals in the cabinet. The cable between the controller and the manipulator is selected in the option range 697-699. Besides the necessary motor wiring the cable also contains 22 wires for gun I/O and CAN/DeviceNet fieldbus. The option also consists of an SMB box for two resolvers, a serial cable between the box and the controller (the same length as 641-642), and two resolver cables, one 1.5m for the RG and one 7m for the SG. The customer connector to the SG cable should be an 8-pin Burndy, wired according to the Motor Unit specification. The SMB box should be mounted close to the manipulator foot. Dimensions and mounting information can be found in the Product Specification Motor Unit. Drive unit 382 (DDU-VW) must be selected. 44 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options 704 Twin SG IRB 6400R The option is a combination of two options 701. A distributed drive unit controls the second SG motor. The cabling between the SG SMBs and the controller is selected in the option range 686-689. Drive unit options 397 (for one SG) and 380 (for the second SG) are required. IRB 6600/7600 The option includes cabling inside the controller. The two cables between the controller and the pedestals are selected in the option range 686-687. Customer connectors to the cables should be of Industrial Multi-connector type, corresponding to the manipulator CP/CS (see Product Specification IRB 6600/7600). Besides the necessary motor wiring, the cables also contain 12 wires for gun I/O, accessible on screw terminals in the cabinet (SG axis 7), or on the Multi connector inside (SG axis 8) the DDU. The option also consists of an SMB box for two resolvers, a serial cable between the box and the controller (the same length as 686-687), and two 7m resolver cables. The customer connector to the SG cable should be an 8-pin Burndy, wired according to the Motor Unit specification.The SMB box should be mounted close to the manipulator foot. Dimensions and mounting information can be found in the product Specification Motor Unit. Drive unit 382 (DDU-VW) must be selected. 705 SG and Track Motion (T) IRB 6400R The option is a combination of 701 and a track motion IRBT 6002S controlled by a distributed drive unit. The cabling between the SG SMB and the controller is selected in the option range 686-689. Drive unit options 397 (for the SG) and 380 (for the T) are required. IRB 6600/7600 The option includes cabling inside the controller. The cable between the controller and the welding gun pedestal is selected in the option range 686-687. The customer connector to the cable should be of Industrial Multi-connector type, corresponding to the manipulator CP/CS (see Product Specification IRB 6600/7600). Besides the necessary motor wiring the cable also contains 12 wires for gun I/O, accessible on screw terminals in the cabinet. The resolver cable for the SG must be ordered together with the Track Motion. The customer connector to the cable should be an 8-pin Burndy, wired according to the Motor Unit specification. The SMB box and the power cable between the controller and the Track Motion are included in the Track Motion delivery. The serial measurement cable between the controller and the Track Motion are included in option 705 (length according to 641642). Drive unit 382 (DDU-VW) must be selected. Product Specification S4Cplus M2000/BaseWare OS 4.0 45 Specification of Variants and Options 706 RG and T IRB 6400R The option is a combination of 702 and a track motion IRBT 6002S controlled by a distributed drive unit. The cabling between the RG SMB and the controller is selected in the option range 681-684. Drive unit options 397 (for the SG) and 380 (for the T) are required. IRB 6600/7600 The option includes cabling inside the controller. The RG cable between the controller and Track Motion is selected in the option range 697-699 except for the track motor cable which is included in the Track Motion delivery. Besides the necessary motor wiring, the RG cable also contains 22 wires for gun I/O and CAN/DeviceNet fieldbus. The option also consists of a 1.5m resolver cable for the RG to be connected to the Track Motion mounted SMB box. Drive unit 382 (DDU-VW) must be selected. EXTERNAL AXES MEASUREMENT BOARD (not available for IRB 340, IRB 6400PE) The resolvers can be connected to a serial measurement board outside the controller. 387 Serial measurement board as separate unit EXTERNAL AXES - SEPARATE CABINET (not available for IRB 340, IRB 6400PE) An external cabinet can be supplied when there is not space enough in the standard cabinet. The external cabinet is connected to one Harting connector (cable length 7 m) on the left-hand side of the robot controller. Door interlock, mains connection, mains voltage and mains filter according to the robot controller. One transformer and one mains switch are included. 371/372 373 374 375 46 Drive unit GT, for 4 or 6 motors. Recommended motor types see Figure 23. Drive unit ECB, for 3 or 6 motors. Recommended motor types see Figure 23. Drive unit GT + ECB Drive unit GT + GT + ECB Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options Drive unit identity Motor max current Arms Drive unit rated current Arms Suitable motor type W 11.5-57 30 XL V 5.5-26 14.5 XL U 11 - 55A 24A M, L G 6 - 30A 16A S, M, L T 7.5-37 20 S, M, L, XL E 4 - 19A 8,4A S, M C 2,5 - 11A 5A S B 1,5 - 7A 4A S Figure 23 Motor selection table. Motor types according to external axes Motor Unit. 380 Drive unit DDU-U A separate box (H=500mm W=300mm D=250mm) including a DC link DC4 and a drive unit GU where the U part is used (the G part is not connected). The DDU-U is operated from an additional axis computor, included in the option. DDU-U is mainly intended for Servo Gun solutions according to options 703-706 and is available for IRB 4400 and 6400R. 381 Drive unit DDU-V (IRB 6600/7600) 382 Drive unit DDU-VW (IRB 6600/7600) 383 Drive unit DDU-W (IRB 6600/7600) A separate box (H=500mm, W=300mm, D=250mm) including a DC link DC5 and a drive unit VW. The box has 4 keyholes on the back of the encapsulation for fastening. Connection cabling (length 5m) to the controller is included. The DDU-VW is operated from an additional axis computer included in the option, while the DDU-V and -W are operated from the basic robot axes computer. The options also include appropriate cabling inside the manipulator for different resolver configurations, see Product Specification IRB 6600, chapter Servo Gun. E.g. 7 axes applications utilise the built in 7 resolver SMB. The DDU-V and VW are mainly intended for Servo Gun solutions according to options 701-706. The DDU-W is intended for a Track Motion without Servo Gun. Product Specification S4Cplus M2000/BaseWare OS 4.0 47 Specification of Variants and Options EQUIPMENTManipulator cable, external connectors 653 Standard Cable length 641 642 643 644 649 7m 15 m, not available for IRB 140 22 m, not available for IRB 140 30 m, not available for IRB 140 3 m, only available for IRB 140 Manipulator connection (only available for IRB 340) 657 External (not for the SA-version i.e. WashDown) 658 Internal Protection for manipulator cable 845 Each unit length is 2 m. Totally 40 m protection can be specified. SERVICE OUTLET Any of the following standard outlets with protective earthing can be chosen for maintenance purposes. The maximum load permitted is 500 VA (max. 100 W can be installed inside the cabinet). 411 120 V in accordance with American standard; single socket, Harvey Hubble. 412 230 V mains outlet in accordance with DIN VDE 0620; single socket suitable for EU countries. POWER SUPPLY (to the service outlet) 431 Connection from the main transformer. The voltage is switched on/off by the mains switch on the front of the cabinet. 432 Connection before mains switch without transformer. Note this only applies when the mains voltage is 400 V, three-phase with neutral connection and a 230 V service socket. Note! Connection before mains switch is not in compliance with some national standards, NFPL 79 for example. MEMORY Removable mass memory 320 Floppy drive The disk drive normally works well at temperatures up to 40oC (104oF). The disk drive 48 Product Specification S4Cplus M2000/BaseWare OS 4.0 Specification of Variants and Options will not deteriorate at higher temperatures but there will be an increase in the number of reading/writing problems as the temperature increases. Extended mass memory 310 Flash disc 128 Mb. Standard is 64 Mb Product Specification S4Cplus M2000/BaseWare OS 4.0 49 Specification of Variants and Options 50 Product Specification S4Cplus M2000/BaseWare OS 4.0 Index 3 Index A absolute measurement 16 Allen-Bradley Remote I/O 23, 25, 40 analog signals 23, 27 automatic operation 15 B backup computer system backup 13 memory 11 base coordinate system 19 Big Inertia 21 bumps 12 C cabinet wheels 32 CAN/DeviceNet 39 collision detection 6 communication 29 concurrent I/O 24 configuration 12, 13, 23 connection 48 mains supply 36 cooling device 3 coordinate systems 18 cross connections 23 cursor 7 event routine 16 explosive environments 12 extended memory 11 external axes 21 external panel 33 F fire safety 6 flash disk memory 11 fly-by point 14 function keys 7 H hold-to-run 8 hold-to-run control 6 humidity 12 I I/O units 24 I/O-system 23 incremental jogging 20 inputs 23 installation 12 Interbus Slave 23, 25, 40 interrupt 24 J jogging 20 joystick 8 D L diagnostics 17 digital signals 23, 26 display 7 distributed I/O 25 LAN/Ethernet 39 language 13 lighting connection 48 teach pendant 35 E editing position 15 programs 15 emergency stop 6, 7 emergency stop button 8 enabling device 5, 8 display 7 Encoder interface unit 25, 41 M mains supply 36 mains switch 36 mains voltage 35 maintenance 17 manipulator cable 48 length 48 protection 48 Product Specification S4Cplus M2000/BaseWare OS 4.0 51 Index mass memory 11 memory backup 11 extended 11 flash disk 11 mass storage 11 RAM memory 11 menu keys 7 mirroring 15 motion 18 motion keys 7 motion performance 18 Motion Supervision 20 Multitasking 24 N navigation keys 7 noise level 3 O object coordinate system 19 operating mode 9 operating mode selector 9, 34 operating requirements 12 operation 7 operator dialogs 13 operator’s panel 9, 33 options 31 outputs 23 over-speed protection 6 P password 13, 15 performance 18 PLC functionality 24 position editing 15 execution 20 programming 14, 19 position fixed I/O 24 power supply 12 production window 15 Profibus 39 Profibus DP Slave 23, 25, 41 program editing 15 testing 15 52 programming 13 protection standards 12 Q QuickMove 18 R RAPID Language 16 reduced speed 5 S safe manual movements 6 safeguarded space stop 6 delayed 6 safety 5 safety lamp 6 serial communication 29 service 17 service outlets 48 signal data 26 singularity handling 20 Soft Servo 21 space requirements 3 standards 5 stationary TCP 20 stop point 14 structure 3 system signals 27 T TCP 19 teach pendant 7 cable 35 language 35 lighting 35 temperature 12 testing programs 15 tool coordinate system 19 tool’s centre point 19 trap routines 24 troubleshooting 17 TrueMove 18 U user coordinate system 19 user-defined keys 8 Product Specification S4Cplus M2000/BaseWare OS 4.0 Index V variants 31 vibration 12 volume 3 W window keys 7 windows 7 working space restricting 6 world coordinate system 19 Product Specification S4Cplus M2000/BaseWare OS 4.0 53 Index 54 Product Specification S4Cplus M2000/BaseWare OS 4.0 Product Specification RobotWare Options 3HAC 9218-1/Rev.2 BaseWare OS 4.0 The information in this document is subject to change without notice and should not be construed as a commitment by ABB Automation Technology Products AB, Robotics. ABB Automation Technology Products AB, Robotics assumes no responsibility for any errors that may appear in this document. In no event shall ABB Automation Technology Products AB, Robotics be liable for incidental or consequential damages arising from use of this document or of the software and hardware described in this document. This document and parts thereof must not be reproduced or copied without ABB Automation Technology Products AB, Robotics’ written permission, and contents thereof must not be imparted to a third party nor be used for any unauthorized purpose. Contravention will be prosecuted. Additional copies of this document may be obtained from ABB Automation Technology Products AB, Robotics at its then current charge. © ABB Automation Technology Products AB Robotics Article number: 3HAC 9218-1 Rev.2 Issue: BaseWare OS 4.0 ABB Automation Technology Products AB, Robotics SE-721 68 Västerås Sweden Product Specification RobotWare Options CONTENTS Page 1 Introduction ..................................................................................................................... 3 2 BaseWare Options ........................................................................................................... 5 [544] Absolute Accuracy ....................................................................................... 5 [541] Load Identification and Collision Detection (LidCode) .............................. 7 [542] ScreenViewer ............................................................................................... 9 [532] Multitasking ................................................................................................. 11 [531] Advanced Motion ......................................................................................... 12 [530] Advanced Functions ..................................................................................... 14 [537] Developer’s Function ................................................................................... 19 [558] Discrete Application ..................................................................................... 22 [540] Conveyor Tracking ....................................................................................... 23 [533] Electronically Linked Motors ....................................................................... 24 [547] Sensor Synchronization ................................................................................ 25 [539] Sensor Interface ............................................................................................ 26 [561] Servo Tool Control ....................................................................................... 27 [631] Servo Tool Change ....................................................................................... 29 [535] RAP Communication ................................................................................... 31 [543] Ethernet Services .......................................................................................... 32 [534] FactoryWare Interface .................................................................................. 33 [271] Interbus Configuration Tool ......................................................................... 34 [270] Profibus DP Configuration Tool ................................................................... 35 [538] I/O Plus ......................................................................................................... 36 3 ProcessWare..................................................................................................................... 37 [551] ArcWare ........................................................................................................ 37 [552] ArcWare Plus ................................................................................................ 40 [556] Arcitec .......................................................................................................... 41 [553] SpotWare ...................................................................................................... 42 [554] SpotWare Plus .............................................................................................. 44 [625] SpotWare Servo ............................................................................................ 46 [626] SpotWare Servo Plus .................................................................................... 49 [569] DispenseWare ............................................................................................... 51 [571] PalletWare .................................................................................................... 53 4 Index ................................................................................................................................. 57 Product Specification RobotWare Options for BaseWare OS 4.0 1 Product Specification RobotWare Options 2 Product Specification RobotWare Options for BaseWare OS 4.0 Introduction 1 Introduction RobotWare is a family of software products from ABB Automation Technology Product AB, Robotics, designed to make you more productive and lower your cost of owning and operating a robot. ABB Automation Technology Product AB, Robotics has invested many man-years into the development of these products and they represent knowledge and experience based on several thousand robot installations. Within the RobotWare family there are three classes of products: BaseWare OS - This is the operating system of the robot and constitutes the kernel of the RobotWare family. BaseWare OS provides all the necessary features for fundamental robot programming and operation. It is an inherent part of the robot but can be provided separately for upgrading purposes. For the description of BaseWare OS, see Product Specification S4Cplus. BaseWare Options - These products are options that run on top of BaseWare OS of the robot. They represent functionality for robot users that need additional functionality, for example run multitasking, transfer information from file to robot, communicate with a PC, perform advanced motion tasks etc. ProcessWare - ProcessWare products are designed for specific process applications like welding, gluing and painting. They are primarily designed to improve the process result and to simplify installation and programming of applications. These products also run on top of BaseWare OS. Product Specification RobotWare Options for BaseWare OS 4.0 3 Introduction 4 Product Specification RobotWare Options for BaseWare OS 4.0 [544] Absolute Accuracy 2 BaseWare Options [544] Absolute Accuracy Absolute Accuracy (AbsAcc) is a calibration concept, which ensures a TCP absolute accuracy of better than ±1 mm in the entire working range. The user is supplied with robot calibration data (error parameter file) and a certificate that shows the performance (Birth Certificate). The difference between an ideal robot and a real robot can be typically 8 mm, resulting from mechanical tolerances and deflection in the robot structure. Absolute Accuracy option is integrated in the controller algorithms for compensation of this difference, and does not need external equipment or calculation. Features • Compensation of mechanical tolerances. • Compensation of deflection due to load (tool, object and equipment on arm). Applications Any application where Absolute Accuracy is needed to facilitate: - Exchangeability of robots - Off-line programming with minimum touch-up. - On-line programming with accurate linear movement as well as accurate reorientation of tool - Re-use of programs between applications Controller algorithms Inherent mechanical tolerances and deflection due to load in the robot structure decrease the robot’s absolute accuracy. Practical compensation of such errors is a complex and highly non-linear problem. The ABB solution is to compensate positions internally in the controller, resulting in a defined and measurable robot TCP (Tool Center Point) accuracy. A generic robot control model is used for each robot family and robot individuals are described by a set of error parameters, generated during calibration at ABB Automation Technology Products, Robotics. Accuracy of each robot will be ascertained and verified through the “Birth Certificate” which statistically describes the robot accuracy in a large sample of robot positions. Product Specification RobotWare Options for BaseWare OS 4.0 5 [544] Absolute Accuracy Performance Once the Absolute Accuracy parameter file is loaded and activated, the robot can be used. Absolute Accuracy is active in: - Motion function based on robtarget (MoveJ, MoveL, MoveC and ModPos) - Reorientation jogging - Linear jogging (no online compensation as the user defines the physical location, but absolute coordinates are determined for the active pose and shown in jogging window) - Tool definition (4, 5, 6 point tool definition, room fixed TCP, stationary tool) - Workobject definition Absolute Accuracy is inactive in: - Motion function based on a jointtarget (MoveAbsJ). Independent joint - Joint based jogging - External axes - Track motion - Any feature not listed in “Absolute Accuracy is active in” For joint based motions, switching to the jogging window and selecting a cartesian jog mode (Linear, Reorient) will show the correct absolute coordinates. Similarly creation of a robtarget at a point taught by joint based motion will be absolutely accurate. Requirements Each Absolute Accuracy robot is shipped with an error parameter file that is unique to that robot. This file must be loaded into the controller and subsequently activated in order to use Absolute Accuracy. Absolute Accuracy functionality may also be deactivated. Both actions require a cabinet restart. Supported robot types Please contact your local ABB office in order to get the latest list of supported robot types. RAPID instructions included in this option No specific RAPID instructions are included. 6 Product Specification RobotWare Options for BaseWare OS 4.0 [541] Load Identification and Collision Detection (LidCode) [541] Load Identification and Collision Detection (LidCode) This option is available for the following robot families: IRB 140, IRB 1400, IRB 2400, IRB 4400, IRB 6400 (not 640) IRB 7600 and for external manipulators IRBP-L, IRBP-K, IRBP-R and IRBP-A. Load identification is not available for the hanging variants of IRB 1400 and IRB 2400 robots. LidCode contains two very useful features: Load Identification To manually calculate or measure the load parameters accurately can be very difficult and time consuming. Operating a robot with inaccurate load parameters can have a detrimental influence on cycle time and path accuracy. With LidCode, the robot can carry out accurate identification of the complete load data (mass, centre of gravity, and three inertia components). If applicable, tool load and payload are handled separately. The identification procedure consists of limited predefined movements of axes 3, 5 and 6 during approximately three minutes. The starting point of the identification motion pattern can be chosen by the user so that collisions are avoided. The accuracy achieved is normally better than 5%. Collision Detection Abnormal torque levels on any robot axis (not external axes) are detected and will cause the robot to stop quickly and thereafter back off to relieve forces between the robot and environment. Tuning is normally not required, but the sensitivity can be changed from Rapid or manually (the supervision can even be switched off completely). This may be necessary when strong process forces are acting on the robot. The sensitivity (with default tuning) is comparable to the mechanical alternative (mechanical clutch) and in most cases much better. In addition, LidCode has the advantages of no added stick-out and weight, no need for connection to the e-stop circuit, no wear, the automatic backing off after collision and, finally, the adjustable tuning. Two system outputs reflect the activation and the trig status of the function. RAPID instructions included in this option MotionSup ParIdRobValid Changing the sensitivity of the collision detection or activating/deactivating the function. Checking that identification is available for a specific robot type. Product Specification RobotWare Options for BaseWare OS 4.0 7 [541] Load Identification and Collision Detection (LidCode) ParIdPosValid LoadId MechUnitLoad 8 Checking that the current position is OK for identification. Performing identification. Definition of payload for external mechanical units. Product Specification RobotWare Options for BaseWare OS 4.0 [542] ScreenViewer [542] ScreenViewer This option adds a user window to display user defined screens with advanced display functions. The user window can be displayed at any time, regardless of the execution state of the RAPID programs. User defined screens The user defined screens are composed of: • A fixed background with a size of 12 lines of 40 characters each. These characters can be ASCII and/or horizontal or vertical strokes (for underlining, separating or framing). • 1 to 5 function keys. • 1 to 4 pop-up menus containing from 1 to 10 choices. • 1 to 30 display and input fields defined by: - Their position and size. - Their type (display, input). - Their display format (integer, decimal, binary, hexadecimal, text). - A possible boundary with minimum and maximum limits. Example of a user defined screen. The ### represent the fields. SpotTim Program number: ### PHASES SQUEEZE PREHEAT COOLING ## HEAT COLD LASTCOLD POSTHEAT HOLD Next View File | XT | ## | ## | ## | ## | ## | ## | ## | ## | CURENT (A) | START | END | | | #### | | | #### | #### | | | | | | #### | #### | | Prev. (Copy) Heat stepper: ### interpolated: ## | | Tolerance: ###% | Force: ###daN | Forge: ###daN | | Fire chck: ### | | Err allow: ###% | Numb err: ### Valid Advanced Display functions The user defined screens run independently of the RAPID programs. Some events occur on a screen (new screen displayed, menu choice selected, function key pressed, field modified, ...). A list of user screen commands can be associated with any of these events, then when the event occurs, the command list will be executed. Product Specification RobotWare Options for BaseWare OS 4.0 9 [542] ScreenViewer A screen event can occur - When a new screen is displayed (to initialize the screen contents). - After a chosen interval (to refresh a screen). - When a menu choice or a function key is selected (to execute a specific action, or change the screen). - When a new value is entered in a field, or when a new field is selected (to execute some specific action). The commands that can be executed on screen events are - Reading/writing RAPID or I/O data. - Reading/writing fields contents. - Arithmetical (+, -, /, *, div) or logical (AND, OR, NOT, XOR) operations on the data read. - Comparing data read (=, <, >) and carrying out a command or not, depending on the comparison result. - Displaying a different screen. Capacities The user screens can be grouped in a screen package file under a specific name. Up to 8 packages can be loaded at the same time. A certain amount of memory (approx. 50 kbytes) is reserved for loading these screen packages. - The screen package to be displayed is selected using the far right hand menu “View” (which shows a list of the screen packages installed). ScreenMaker ScreenMaker is a complete tool for creating and editing screens for the ScreenViewer on desktop computers running Windows 95/98 or Windows NT. See ScreenMaker Product Specification. 10 Product Specification RobotWare Options for BaseWare OS 4.0 [532] Multitasking [532] Multitasking Up to 10 programs (tasks) can be executed in parallel with the normal robot program. - These additional tasks start automatically at power on and will continue until the robot is powered off, i.e. even when the main process has been stopped and in manual mode. - They are programmed using standard RAPID instructions, except for motion instructions. - They can be programmed to carry out various activities in manual or automatic mode, and depending on whether or not the main process is running. - Communication between tasks is carried out via I/O or global data. - Priorities can be set between the processes. Examples of applications: - The robot is continuously monitoring certain signals even when the robot program has stopped, thus taking over the job traditionally allocated to a PLC. - An operator dialogue is required at the same time as the robot is doing, for example, welding. By putting this operator dialogue into a background task, the operator can specify input data for the next work cycle without having to stop the robot. - The robot is controlling a piece of external equipment in parallel with the normal program execution. Performance When the various processes are programmed in the correct way, no performance problems will normally occur: - When the priorities for the various processes are correctly set, the normal program execution of the robot will not be affected. - Because monitoring is implemented via interrupts (instead of checking conditions at regular intervals), processor time is required only when something actually happens. - All input and output signals are accessible for each process. Note that the response time of Multitasking does not match that of a PLC. Multitasking is primary intended for less demanding tasks. The normal response time is about 5 ms, but in the worst cases, e.g. when the processor is computing new movements, it can be up to 120 ms. The available program memory can be divided up arbitrarily between the processes. However, each process in addition to the main process will reduce the total memory, see Product Specification S4Cplus. Product Specification RobotWare Options for BaseWare OS 4.0 11 [531] Advanced Motion [531] Advanced Motion Contains functions that offer the following possibilities: - Resetting the work area for an axis. - Independent movements. - Contour tracking. - Coordinated motion with external manipulators. Resetting the work area for an axis The current position of a rotating axis can be adjusted a number of complete turns without having to make any movements. Examples of applications: - When polishing, a large work area is sometimes needed on the robot axis 4 or axis 6 in order to be able to carry out final polishing without stopping. Assume that the axis has rotated 3 turns, for example. It can now be reset using this function, without having to physically rotate it back again. Obviously this will reduce cycle times. - When arc welding, the work object is often fitted to a rotating external axis. If this axis is rotated more than one turn during welding, the cycle time can be reduced because it is not necessary to rotate the axis back between welding cycles. Coordinated motion with multi-axis manipulators Coordinated motion with multi-axis manipulators or robot carriers (gantries) requires the Advanced Motion option. Note that simultaneous coordination with several single axis manipulators, e.g. track motion and workpiece manipulator, does not require Advanced Motion. Note! There is a built-in general method for defining the geometry for a manipulator comprising two rotating axes (see User’s Guide, Calibration). For other types of manipulators/robot carriers, comprising up to six linear and/or rotating axes, a special configuration file is needed. Please contact your nearest local ABB office. Contour tracking Path corrections can be made in the path coordinate system. These corrections will take effect immediately, also during movement between two positions. The path corrections must be entered from within the program. An interrupt or multitasking is therefore required to activate the correction during motion. Example of application: - A sensor is used to define the robot input for path correction during motion. The input can be defined via an analog input, a serial channel or similar. Multitasking or interrupts are used to read this information at specific intervals. Based on the input value, the path can then be adjusted. 12 Product Specification RobotWare Options for BaseWare OS 4.0 [531] Advanced Motion Independent movements A linear or rotating axis can be run independently of the other axes in the robot system. The independent movement can be programmed as an absolute or relative position. A continuous movement with a specific speed can also be programmed. Examples of applications: - A robot is working with two different stations (external axes). First, a work object located at station 1 is welded. When this operation is completed, station 1 is moved to a position where it is easy to change the work object and at the same time the robot welds the work object at station 2. Station 1 is moved independently of the robot’s movement, which simplifies programming and reduces the cycle time. - The work object is located on an external axis that rotates continuously at a constant speed. In the mean time, the robot sprays plasma, for example, on the work object. When this is finished the work area is reset for the external axis in order to shorten the cycle time. Friction Compensation During low speed (10-100 mm/s) cutting of fine profiles, in particular small circles, a friction effect, typically in the form of approximately 0.5 mm “bumps”, can be noted. Advanced Motion offers a possibility of compensating for these frictional effects. Typically a 0.5 mm “bump” can be reduced to about 0.1 mm. This, however, requires careful tuning of the friction level (see User’s Guide for tuning procedure). Note that even with careful tuning, there is no guarantee that “perfect” paths can always be generated. For the IRB 6400 family of robots, no significant effects can be expected by applying Friction Compensation. RAPID instructions and functions included in this option IndReset IndAMove IndDMove IndRMove IndCMove IndInpos IndSpeed CorrCon CorrWrite CorrRead CorrDiscon CorrClear Resetting the work area for an axis Running an axis independently to an absolute position Running an axis independently for a specified distance Running an axis independently to a position within one revolution, without taking into consideration the number of turns the axis had rotated earlier Running an axis continuously in independent mode Checking whether or not an independent axis has reached the programmed position Checking whether or not an independent axis has reached the programmed speed Activating path correction Changing path correction Read current path correction Deactivating path correction Removes all correction generators Product Specification RobotWare Options for BaseWare OS 4.0 13 [530] Advanced Functions [530] Advanced Functions Includes functions making the following possible: - Information transfer via serial channels or files. - Setting an output at a specific position. - Checking signal value at a specific position. - Executing a routine at a specific position. - Defining forbidden areas within the robot´s working space. - Automatic setting of output when the robot is in a user-defined area. - Robot motion in an error handler or trap routine, e.g. during automatic error handling. - Cross connections with logical conditions. - Interrupts from analog input or output signals. Transferring information via serial channels Data in the form of character strings, numeric values or binary information can be transferred between the robot and other peripheral equipment, e.g. a PC, bar code reader, or another robot. Information is transferred via an RS232 or RS485 serial channel. Examples of applications: - Printout of production statistics on a printer connected to the robot. - Reading part numbers from a bar code reader with a serial interface. - Transferring data between the robot and a PC. The transfer is controlled entirely from the robot’s work program. When it is required to control the transfer from a PC, use the option RAP Communication or FactoryWare Interface. Data transfer via files Data in the form of character strings, numerical values or binary information can be written to or read from files on a diskette or other type of mass storage/memory. Examples of applications: - Storing production statistics on a diskette or flashdisk. This information can then be read and processed by an ordinary PC. - The robot’s production is controlled by a file. This file may have been created in a PC, stored on a diskette, and read by the robot at a later time. 14 Product Specification RobotWare Options for BaseWare OS 4.0 [530] Advanced Functions Fixed position output The value of an output (digital, analog or a group of digitals) can be ordered to change at a certain distance before or after a programmed position. The output will then change at the same place every time, irrespective of the robot’s speed. Consideration can also be given to time delays in the process equipment. By specifying this time delay, the output is set at the corresponding time before the robot reaches the specified position. The distance can also be specified as a certain time before the programmed position. This time (max. 500 ms) must be within the deceleration time when approaching that position. Examples of applications: - Handling press work, to provide a safe signalling system between the robot and the press, which will reduce cycle times. Just as the robot leaves the press, an output is set that starts the press. - Starting and finishing process equipment. When using this function, the start will always occur at the same position irrespective of the speed. For dispensing and sealing, see DispenseWare. Fixed position IO check The value of an input/output signal (digital, analog or group) can be checked at a certain distance before or after a programmed position. The signal will then be checked at the same place every time, irrespective of the robot's speed. The distance can also be specified as a certain time (max 500 ms) before the programmed position. The data being checked is compared with a certain programmed value and if the comparison is false, the robot will stop and an interrupt routine will be executed. In the interrupt routine appropriate error handling can be executed. Examples of applications: - A robot is used for extraction of parts from a die casting machine. Before entering the machine the robot can check, in the fly, if the gate is open. If not, the robot will stop and, in the interrupt routine, wait for the gate to open. Fixed position procedure call A procedure call can be carried out when the robot passes the middle of a corner zone. The position will remain the same, irrespective of the robot’s speed. Example of application: - In the press example above, it may be necessary to check a number of logical conditions before setting the output that starts the press. A procedure which takes care of the complete press start operation is called at a position just outside the press. Product Specification RobotWare Options for BaseWare OS 4.0 15 [530] Advanced Functions World Zones A spherical, cylindrical or cubical volume can be defined within the working space. When the robot reaches this volume it will either set an output or stop with the error message “Outside working range”, both during program execution and when the robot is jogged into this area. The areas, which are defined in the world coordinate system, can be automatically activated at start-up or activated/deactivated from within the program. Examples of applications: - A volume is defining the home position of the robot. When the robot is started from a PLC, the PLC will check that the robot is inside the home volume, i.e. the corresponding output is set. - The volume is defining where peripheral equipment is located within the working space of the robot. This ensures that the robot cannot be moved into this volume. - A robot is working inside a box. By defining the outside of the box as a forbidden area, the robot cannot run into the walls of the box. - Handshaking between two robots both working in the same working space. When one of the robots enters the common working space, it sets an output and after that enters only when the corresponding output from the other robot is reset. Movements in interrupt routines and error handlers This function makes it possible to temporarily interrupt a movement which is in progress and then start a new movement which is independent of the first one. The robot stores information about the original movement path which allows it to be resumed later. Examples of applications: - Cleaning the welding gun when a welding fault occurs. When a welding fault occurs, there is normally a jump to the program’s error handler. The welding movement in progress can be stored and the robot is ordered to the cleaning position so that the nozzle can be cleaned. The welding process can then be restarted, with the correct parameters, at the position where the welding fault occurred. This is all automatic, without any need to call the operator. (This requires options ArcWare or ArcWare Plus.) - Via an input, the robot can be ordered to interrupt program execution and go to a service position, for example. When program execution is later restarted (manually or automatically) the robot resumes the interrupted movement. Cross-connections with logical conditions Logical conditions for digital input and output signals can be defined in the robot’s system parameters using AND, OR and NOT. Functionality similar to that of a PLC can be obtained in this way. 16 Product Specification RobotWare Options for BaseWare OS 4.0 [530] Advanced Functions Example: - Output 1 = Input 2 AND Output 5. - Input 3 = Output 7 OR NOT Output 8. Examples of applications: - Program execution to be interrupted when both inputs 3 and 4 become high. - A register is to be incremented when input 5 is set, but only when output 5=1 and input 3=0. Interrupts from analog input or output signals An interrupt can be generated if an analog input (or output) signal falls within or outside a specified interval. RAPID instructions and functions included in this option Open Close Write WriteBin WriteStrBin ReadNum ReadStr ReadBin Rewind WriteAnyBin ReadAnyBin ReadStrBin ClearIOBuff WZBoxDef WZCylDef WZLimSup WZSphDef WZDOSet WZDisable WZEnable WZFree StorePath RestoPath TriggC TriggL TriggJ TriggIO TriggEquip TriggCheckIO TriggInt MoveCSync MoveLSync Opens a file or serial channel Closes a file or serial channel Writes to a character-based file or serial channel Writes to a binary file or serial channel Writes a string to a binary serial channel Reads a number from a file or serial channel Reads a string from a file or serial channel Reads from a binary file or serial channel Rewind file position Write data to a binary serial channel or file Read data from a binary serial channel or file Read a string from a binary serial channel or file Clear input buffer of a serial channel Define a box shaped world zone Define a cylinder shaped world zone Activate world zone limit supervision Define a sphere shaped world zone Activate world zone to set digital output Deactivate world zone supervision Activate world zone supervision Erase world zone supervision Stores the path when an interrupt or error occurs Restores the path after an interrupt/error Position fix output/interrupt during circular movement Position fix output/interrupt during linear movement Position fix output/interrupt during joint movement Definition of trigger conditions for one output Definition of trigger conditions for process equipment with time delay Definition of trigger condition for check of signal value Definition of trigger conditions for an interrupt Position fix procedure call during circular movement Position fix procedure call during linear movement Product Specification RobotWare Options for BaseWare OS 4.0 17 [530] Advanced Functions MoveJSync ISignalAI ISignalAO 18 Position fix procedure call during joint movement Interrupts from analog input signal Interrupts from analog output signal Product Specification RobotWare Options for BaseWare OS 4.0 [537] Developer’s Function [537] Developer’s Function This option is intended to be used by application developers requiring more advanced functions than normally available for an end user. The package includes a detailed reference manual on the RAPID language kernel and a number of instruction and function groups useful for different application development as listed below. The groups are: - Bit Functions - Data Search Functions - RAPID Support Functions - Power Failure Functions - Trigg Functions - File Operation Functions RAPID Kernel Reference Manual The manual describes the RAPID language syntax and semantics in detail concerning the kernel, i.e. all general language elements which are not used to control robot or other equipment. In addition to this the manual includes descriptions on: - Built-in Routines - Built-in Data Objects - Built-in Objects - Intertask Objects - Text Files - Storage allocation for RAPID objects Bit Functions This is a package for handling, i.e. setting, reading and clearing, individual bits in a byte. The instructions/functions are: byte BitSet BitClear BitCheck BitAnd BitOr BitXOr BitNeg BitLSh BitRSh Data type for a byte data Set a specified bit in a byte Clear a specified bit in a byte Check if a specified bit in a byte is set Logical bitwise AND operation on byte Logical bitwise OR operation on byte Logical bitwise XOR operation on byte Logical bitwise NEGATION operation on byte Logical bitwise LEFT SHIFT operation on byte Logical bitwise RIGHT SHIFT operation on byte Product Specification RobotWare Options for BaseWare OS 4.0 19 [537] Developer’s Function Data Search Functions With these functions it is possible to search all data in a RAPID program, where the name or the data type is given as a text string. This might be useful for instance in the following examples: - A common problem is to check if a data with a certain name is declared in the system, and in such case what is its value, e.g.a robtarget - Another problem is to list all variables of a certain datatype, which are declared in the system, and write their values on the screen, e.g. all weld data. The following instructions/functions are included in the package: SetDataSearch Define the search criteria GetNextSym Search next data and get its name as a string GetDataVal Get the value of a data, specified with a string for the name SetDataVal Set the value of a data, specified with a string for the name RAPID Support Functions This package includes a number of miscellaneous instructions etc., which are used in application development. User defined data typesThis will make it possible to create your own data types, like a record definition 20 AliasIO Instruction used to define a signal of any type with an alias (alternative) name. The instruction can be used to make generic modules work together with site specific I/O, without changing the program code. ArgName Function used inside a routine to get the name of a data object, which is referenced as argument in the call of the routine. The name is given as a string. The function can also be used to convert the identifier of a data into a string. BookErrNo Instruction used to book a new RAPID system error number. This should be used to avoid error number conflicts if different generic modules are combined in a system. TextTabGet Function used to get the text table number of a user defined text table during runtime. TextGet Function used to get a text string from the system text tables (installed at cold start). TextTabInstall Instruction used to install a text table in the system. TextTabFreeToUse Function to test whether the text table name (text resource string) is free to use. IsSysId Function used to test the system identity. SetSysData Instruction which will activates the specified system data (tool or workobject). With this instruction it is possible to change the current active tool or workobject. Product Specification RobotWare Options for BaseWare OS 4.0 [537] Developer’s Function IsStopStateEvent Function which will return information about the movement of the Program Pointer (PP). ReadCfgData Read system configuration data. WriteCfgData Write system configuration data. Power Failure Functions The package is used to get I/O signal values before power failure and to reset them at power on. The following instructions are included and are normally used in the power on event routine: PFIOResto Restore the values of all digital output signals. PFDOVal Get the value of the specified digital output signal at the time for power failure. PFGOVal Get the value of the specified digital output group at the time for power failure. PFRestart Check if path has been interrupted. Trigg Functions TriggSpeed Instruction to define conditions and actions for control of an analog output signal with an output value proportional to the actual TCP speed. Note that this instruction must be used in combination with a TriggL/C/J instruction (see [530] Advanced Functions). StepBwdPath Instruction used to move backward on its path in a RESTART event routine. TriggStopProc Generation of restart data at program stop or emergency stop. File Operation Functions The package includes instructions and functions to work with directories and files on mass memory like floppy disc, flash disc or hard disc. It can be used when creating application packages, using RAPID, where RAPID programs and modules should be loaded or stored. It can also be used to search for all files in different directories and e.g. list them on the teach pendant. The following instructions and functions are available: dir MakeDir OpenDir CloseDir RemoveDir ReadDir RemoveFile IsFile Datatype for variables referencing a directory Create a new directory Open a directory to read the underlaying files or subdirectories Close a directory Delete a directory Read next object in a directory, file or subdirectory Delete a file Check the type of a file Product Specification RobotWare Options for BaseWare OS 4.0 21 [537] Developer’s Function FileSize FSSize 22 Get the size of a file Get the size of a file system Product Specification RobotWare Options for BaseWare OS 4.0 [558] Discrete Application [558] Discrete Application Discrete Applications Platform (DAP) is a software platform for time critical applications, where certain actions shall be performed at specific robot positions. Target users are advanced application software engineers and system integrators, e.g. for spot welding, drilling, measuring, quality control. The main advantages are achieved in the following areas: - Development time - Program execution time. - RAPID- program memory needed - Similar “look and feel” between applications - Tested kernel software Features • Specialized RAPID instructions and datatypes. • A single instruction for motion and process execution. • Combination of fine point positioning with execution of up to 4 parallel processes. • Specialized process for monitoring of external process devices, like spot welding controllers. • Supports encapsulation of the process and motion, in shell-routines provided to the end-user. • The Advanced Functions option is included in DAP. Application Creation of software for advanced applications with a discrete behaviour, such as spot welding, drilling, measuring, quality control. Performance C-code kernel and RAPID calls. The DAP platform is designed to have an internal kernel, administrating the fast and quality secured process sequence skeleton. The kernel calls RAPID routines, which are prepared by the application writer to fulfil the specific tasks. The application developer regulates the degree of flexibility of the end-user. Requirements There are no other requirements than S4CPlus cabinet and BaseWare. Rapid instructions included in this option See RAPID Discrete Application Platform User’s Guide. 22 Product Specification RobotWare Options for BaseWare OS 4.0 [540] Conveyor Tracking [540] Conveyor Tracking Conveyor Tracking (also called Line Tracking) is the function whereby the robot follows a work object which is mounted on a moving conveyor. While tracking the conveyor, the programmed TCP speed relative to the work object will be maintained, even when the conveyor speed is changing slowly. Note that hardware components for measuring the conveyor position are also necessary for this function. Please refer to the Product Specification for your robot. Conveyor Tracking provides the following features: - A conveyor can be defined as either linear or circular. - It is possible to have four conveyors connected simultaneously and to switch between tracking the one or the other. - Up to 254 objects can reside in an object queue which can be manipulated by RAPID instructions. - It is possible to define a start window in which an object must be before tracking can start. - A maximum tracking distance may be specified. - If the robot is mounted on a parallel track motion, then the system can be configured such that the track will follow the conveyor and maintain the relative position to the conveyor. - Tracking of a conveyor can be activated “on the fly”, i.e. it is not necessary to stop in a fine point. Performance At 150 mm/s constant conveyor speed, the TCP will stay within ±2 mm of the path as seen with no conveyor motion. When the robot is stationary relative to the conveyor, the TCP will remain within 0.7 mm of the intended position. These values are valid as long as the robot is within its dynamic limits with the added conveyor motion and they require accurate conveyor calibration. RAPID instructions included in this option WaitWObj DropWObj Connects to a work object in the start window Disconnects from the current object Product Specification RobotWare Options for BaseWare OS 4.0 23 [533] Electronically Linked Motors [533] Electronically Linked Motors This option is used to make master/slave configurations of motors, which are defined as external axes. The main application is to replace mechanical driving shafts of Gantry machines, but the option can be used to control any other set of motors as well. Features • Up to 4 master motors. • Up to 11 motors total (masters and followers). • Jogging and calibration routines. • Replacement of mechanical driving shafts. • Arm/Motor position available on the TPU. • Possibility to activate/deactivate link during process. • Automatic calibration at startup. Application Gantry machines: to replace mechanical driving shafts. Requirements There are no software or hardware requirements for this option. Performance - When jogging, the electronically linked motors will follow the master motor - Calibration – running follower motors independent of the master - is performed through a RAPID calibration program, to ensure high personnel safety - At startup, a routine will automatically set the master- and follower motors at the start position, through a safe maneuver RAPID instruction included in this option There are no RAPID instructions included in this option. 24 Product Specification RobotWare Options for BaseWare OS 4.0 [547]Sensor Synchronization [547] Sensor Synchronization Sensor Synchronization adjusts the robot speed to an external moving device (e.g. a press or conveyor) with the help of a sensor. This option simplifies programming and improves productivity of any loading /unloading application since it provides automatic sensor status check and speed adjustment. The robot TCP speed will be adjusted in correlation to the sensor output so that the robot will reach the programmed robtargets at the same time as the external device reaches their programmed positions. The synchronization is started/stopped with a new instruction, SyncToSensor, combined with movement instructions (fine points or corner zones). Note that hardware components for measuring the sensor output are needed for this function. The same hardware as for Conveyor Tracking is used: encoder and canbus boards. Please refer to the Product Specification for your robot. Features • Up to 4 sensors/robot. • “On-the-fly” activation. • Valid for any type of movement. • RAPID access to sensor and queue data. • Object queue: the same functionality as conveyor tracking. Applications Press synchronization “Side robot”or “Top_Robot “ (1 plane work robot NOFAC), paint application Performance The TCP will stay within ±50ms delay of the teached sensor position with linear sensor and constant sensor speed. Rapid instructions included in this option SyncToSensor WaitSensor DropSensor Start/stop synchronization Connect to an object in the start window Disconnect from current object Product Specification RobotWare Options for BaseWare OS 4.0 25 [539] Sensor Interface [539] Sensor Interface The Sensor Interface option can be used to integrate sensor equipment for adaptive control, like path correction or process tuning. The option includes a driver for serial communication with the sensor system using a specific link protocol (RTP1) and a specific application protocol (LTAPP). The communication link makes it easy to exchange data between the robot controller and the sensor system, using predefined numbers for different data like x,y,z offset values, gap between sheets, time stamp etc. Features • Interrupt routines, based on sensor data changes. • Read/write sensor data from/to sensors using RAPID functions. • Store/retrieve sensor data as a block to/from a mass memory. • Seam tracking functionality, when combined with option Advanced Motion, based on using the contour tracking (path correction) functionality. Application In any application where it is wanted to read/control a sensor during execution, and to react on changes in certain data, like path offset or process supervisory data, thus making adaptive seam tracking and process control possible. Requirements External sensors communicating with the robot controller via serial links. RAPID instruction included in this option IVarValue ReadBlock ReadVar WriteBlock WriteVar 26 Used to order and enable an interrupt when the value of a variable accessed via the serial sensor interface has been changed Used to read a block of data from a device connected to the serial sensor interface Used to read a variable from a device connected to the serial sensor interface Used to write a block of data to a device connected to the serial sensor interface Used to write a variable to a device connected to the serial sensor interface Product Specification RobotWare Options for BaseWare OS 4.0 [561] Servo Tool Control [561] Servo Tool Control The Servo Tool Control is a general and flexible software platform for controlling an integrated servo tool from S4CPlus. For additional features, like control of external processes, or control of several ServoGuns in parallel, please refer to the option SpotWare Servo. Target users are advanced system integrators who want to develop customer specific application software, such as spotwelding packages. As a “quick-start”, the option includes an example code package. This package can be used as a base for application development. Features • Position control (gap). • Force control. • Dynamic and kinematic model (tool configured as external axis). • Example code package. Application Spot Welding with Servo Guns: The option provides advanced control functionality for Servo Guns. Communication with Weld timers and other process control functionality needs to be implemented outside this option. For a total spot welding package, please refer to the option SpotWare Servo. Performance The tool is configured as an external axis, which ensures optimal performance, regarding path following and speed. (Dynamic and kinematic model.) The option Servo Tool Change can be added to the system in order to allow a switch between two or more servo tool, which will then utilize the same drive unit and measurement board. Requirements • Motion parameter file A specific servo tool parameter file has to be installed in the controller, for each servo tool. The parameter file is optimized for each system, concerning system behaviour and motion/process performance. • Drive Module & Measurement board See User’s Guide External Axes. Product Specification RobotWare Options for BaseWare OS 4.0 27 [561] Servo Tool Control Rapid instructions included in this option STClose STOpen STCalib STTune STTuneReset STIsClosed STIsOpen STCalcTorque STCalcForce 28 Close a Servo Tool with a predefined force and thickness Open a Servo Tool Calibrate a Servo Tool Tune motion parameters for a Servo Tool Reset tuned motion parameters Test if a Servo Tool is closed Test if a Servo Tool is open Calculate the motor torque for a Servo Tool Calculate the programmable force for a Servo Tool Product Specification RobotWare Options for BaseWare OS 4.0 [631] Servo Tool Change [631] Servo Tool Change Servo Tool Change enables an on-line change of tools (external axes), for a certain drive- and measurement system. The control is switched between the axes by switching the motor cables from one servo motor to another. The switch is performed on-line, during production. The main advantages are: - Flexibility in the production process One robot handles several tools - Minimized equipment A single drive-measurement system shared by many tools Features • On-line change of tools. • Up to 8 different tools. Application Servo gun changing; Robot held servo guns, designed for different reach and weld forces, equipped with different brands and sizes of servo motors, may be held and operated by a robot, switching from one servo gun to another. Servo Tool Change can be used as an independent option, or as an addition to the SpotWare Servo or Servo Toool Control options. Requirements Servo Tool Change requires a mechanical wrist interface, a Tool Changer. A MOC service parameter, Disconnect deactive = YES (Types: Measurement channel), must be set for each tool (external axis) used with this function. Performance When switching tools, the following steps are performed (switching from Axis 1 to Axis 2): - Axis 1 is deactivated using the RAPID instruction DeactUnit. - Axis 1 is disconnected from the motor cables. - Axis 2 is connected to the motor cables. - Axis 2 is activated using RAPID instruction ActUnit. After activation, Axis 2 is ready to run. Product Specification RobotWare Options for BaseWare OS 4.0 29 [631] Servo Tool Change The motor position at the moment of deactivation of one axis is saved and restored next time the axis is activated. Note: The motor position must not change more than half a motor revolution, when the axis is disconnected. In SpotWare Servo, there is a calibration routine, which handles larger position changes. RAPID instructions included in this option There are no specific RAPID instructions included in this option. 30 Product Specification RobotWare Options for BaseWare OS 4.0 [535] RAP Communication [535] RAP Communication This option is required for all communication with a superior computer, where none of the WebWare products are used. It includes the same functionality described for the option Factory Ware Interface. It also works for the WebWare products. There is no difference from the FactoryWare Interface (except that the price is higher). Note that both FactoryWare Interface and RAP Communication can be installed simultaneously. Product Specification RobotWare Options for BaseWare OS 4.0 31 [543] Ethernet Services [543] Ethernet Services FTP This option includes the same functionality as described for Ethernet Services NFS except that the protocol used for remote mounted disc functionality is FTP. The aspect of authorization differs between NFS and FTP. Examples of applications: - All programs for the robot are stored in the PC. When a new part is to be produced, i.e. a new program is to be loaded, the program can be read directly from the hard disk of the PC. This is done by a manual command from the teach pendant or an instruction in the program. If the option RAP Communication or FactoryWare Interface is used, it can also be done by a command from the PC (without using the ramdisk as intermediate storage). - Several robots are connected to a PC via Ethernet. The control program and the user programs for all the robots are stored on the PC. A software update or a program backup can easily be executed from the PC. NFS Information in mass storage, e.g. the hard disk in a PC, can be read directly from the robot using the NFS protocol. The robot control program can also be booted via Ethernet instead of using diskettes. This requires Ethernet hardware in the robot. 32 Product Specification RobotWare Options for BaseWare OS 4.0 [534] FactoryWare Interface [534] FactoryWare Interface This option enables the robot system to communicate with a PC. FactoryWare Interface serves as a run-time license for WebWare, i.e. the PC does not require any license protection when executing a WebWare based application. Factory Ware Interface includes the Robot Application Protocol (RAP). The Robot Application Protocol is used for computer communication. The following functions are supported: - Start and stop program execution - Transfer programs to/from the robot - Transfer system parameters to/from the robot - Transfer files to/from the robot - Read the robot status - Read and write data - Read and write output signals - Read input signals - Read error messages - Change robot mode - Read logs RAP communication is available both for serial links and network, as illustrated by the figure below. RAP RPC (Remote Procedure Call) TCP/IP Standard protocols SLIP Ethernet RS232/RS422 Examples of applications: - Production is controlled from a superior computer. Information about the robot status is displayed by the computer. Program execution is started and stopped from the computer, etc. - Transferring programs and parameters between the robot and a PC. When many different programs are used in the robot, the computer helps in keeping track of them and by doing back-ups. RAPID instruction included in this option SCWrite Sends a message to the computer (using RAP) Product Specification RobotWare Options for BaseWare OS 4.0 33 [271] Interbus-S Configuration Tool [271] Interbus Configuration Tool The Interbus Configuration Tool is used to configure the communication channels of the DSQC 512 board. (See ‘I/O Interfaces’, in the S4Cplus Product Specification.) The tool consists of standard PC software. The tool creates a bus configuration, which is used by the controller. 34 Product Specification RobotWare Options for BaseWare OS 4.0 [270] Profibus DP Configuration Tool [270] Profibus DP Configuration Tool The Profibus Configuration Tool is used to configure the master channel of the Profibus DP DSQC 510 board. (See ‘I/O Interfaces’, in the S4Cplus Product Specification.) The tool consists of standard PC software. The tool creates a bus configuration, which is used in the robot controller. Note: This tool is NOT needed for configuration and use of other channels than the master channel of the DSQC 510 board. Product Specification RobotWare Options for BaseWare OS 4.0 35 [538] I/O Plus [538] I/O Plus I/O Plus enables the S4Cplus to use non-ABB I/O units. The following units are supported: - Wago modules with DeviceNet fieldbus coupler, item 750-306 revision 3. - Lutze IP67 module DIOPLEX-LS-DN 16E 744-215 revision 2 (16 digital input signals). - Lutze IP67 module DIOPLEX-LS-DN 8E/8A 744-221 revision 1 (8 digital input signals and 8 digital output signals). For more information on any of these units, please contact the supplier. The communication between these units and S4Cplus has been verified (this does not, however, guarantee the internal functionality and quality of the units). Configuration data for the units is included. In I/O Plus there is also support for a so-called “Welder”. This is a project specific spot welding timer, and is not intended for general use. In addition to the above units, the I/O Plus “Generic Driver” also opens up the possibility to use other digital I/O units that conform with the DeviceNet specification. ABB does not assume any responsibility for the functionality or quality of such units. The user must provide the appropriate configuration data. I/O Plus also opens up the use of the second DeviceNet channel named CAN2, the configuration of the second channel is automatic if you have I/O Plus. I/O Plus also opens up the DeviceNet Slave functionality, which allow the S4Cplus controller to act as a slave unit towards another DeviceNet master, the configuration data for the slave unit is included. 36 Product Specification RobotWare Options for BaseWare OS 4.0 [551] ArcWare 3 ProcessWare [551] ArcWare ArcWare comprises a large number of dedicated arc welding functions, which make the robot well suited for arc welding. It is a simple yet powerful program since both the positioning of the robot and the process control and monitoring are handled in one and the same instruction. I/O signals, timing sequences and weld error actions can be easily configured to meet the requirements of a specific installation. ArcWare functions A few examples of some useful functions are given below. Adaptation to different equipment The robot can handle different types of weld controllers and other welding equipment. Normally communication with the welding controller uses parallel signals but a serial interface is also available. Advanced process control Voltage, wire feed rate, and other process data can be controlled individually for each weld or part of a weld. The process data can be changed at the start and finish of a welding process in such a way that the best process result is achieved. Testing the program When testing a program, welding, weaving or weld guiding can all be blocked. This provides a way of testing the robot program without having the welding equipment connected. Automatic weld retry A function that can be configured to order one or more automatic weld retries after a process fault. Weaving The robot can implement a number of different weaving patterns up to 10 Hz depending on robot type. These can be used to fill the weld properly and in the best possible way. Weaving movement can also be ordered at the start of the weld in order to facilitate the initial striking of the arc. Product Specification RobotWare Options for BaseWare OS 4.0 37 [551] ArcWare Wire burnback and rollback These are functions used to prevent the welding wire sticking to the work object. Fine adjustment during program execution The welding speed, wire feed rate, voltage and weaving can all be adjusted whilst welding is in progress. This makes trimming of the process much easier because the result can be seen immediately on the current weld. This can be done in both manual and automatic mode. Seam finding and tracking Seam finding and tracking can be implemented using a number of different types of sensors. Please contact your nearest local ABB office for more information. Interface signals The following process signals are, if installed, handled automatically by ArcWare. The robot can also support dedicated signals for workpiece manipulators and sensors. 38 Digital outputs Power on/off Gas on/off Wire feed on/off Wire feed direction Weld error Error information Weld program number Description Turns weld on or off Turns gas on or off Turns wire feed on or off Feeds wire forward/backward Weld error Digital outputs for error identification Parallel port for selection of program number, or 3-bit pulse port for selection of program number, or Serial CAN/Devicenet communication Digital inputs Arc OK Voltage OK Current OK Water OK Gas OK Wire feed OK Manual wire feed Weld inhibit Weave inhibit Stop process Wirestick error Supervision inhibit Torch collision Description Arc established; starts weld motion Weld voltage supervision Weld current supervision Water supply supervision Gas supply supervision Wire supply supervision Manual command for wire feed Blocks the welding process Blocks the weaving process Stops/inhibits execution of arc welding instructions Wirestick supervision Program execution without supervision Torch collision supervision Analog outputs Voltage Wire feed Current Voltage adjustment Current adjustment Description Weld voltage Velocity of wire feed Weld current Voltage synergic line amplification Current synergic line amplification Product Specification RobotWare Options for BaseWare OS 4.0 [551] ArcWare Analog inputs (cont.) Description (cont.) Voltage Weld voltage measurement for monitoring and supervision Weld current measurement for monitoring and supervision Current RAPID instructions included in this option ArcL ArcC ArcKill ArcRefresh Arc welding with linear movement Arc welding with circular movement Aborts the process and is intended to be used in error handlers Updates the weld references to new values Product Specification RobotWare Options for BaseWare OS 4.0 39 [552] ArcWare Plus [552] ArcWare Plus ArcWare Plus contains the following functionality: - ArcWare, see previous chapter. - Arc data monitoring. Arc data monitoring with adapted RAPID instructions for process supervision. The function predicts weld errors. - Contour tracking during welding. Path corrections during welding, i.e. when executing ArcL or ArcC instructions, can be made relative to the path using external sensors like Serial Weld Guide or Laser Track. Such corrections will take effect immediately, also during movement between two positions. The correction data are sent from the sensor system to the controller using a serial link and will automatically affect the path through built in functionality. Please note, that this option is compulsory for Serial Weld Guide systems (AWC) or Laser Track systems (M-Spot 90). - Contour tracking in normal movements (path corrections) Path corrections can also be activated when running normal movements like MoveL using specific RAPID path correction instructions. This functionality is also a part of option Advanced Motion, see this option for more information. - Adaptive process control for e.g. sensors like LaserTrak and Serial Weld Guide systems. The sensor can for instance provide the robot system with changes in the shape of the seam. These values can then be used to adapt the process parameters, like voltage or wire feed, to the current shape. (See option Sensor Interface for more information) RAPID instructions and functions included in this option CorrCon CorrWrite CorrRead CorrDiscon CorrClear SpcCon SpcWrite SpcDump SpcRead SpcDiscon IVarValue ReadBlock ReadVar WriteBlock WriteVar 40 Activating path correction Changing path correction Read current path correction Deactivating path correction Removes all correction generators Activates statistical process supervision Provides the controller with values for statistical process supervision Dumps statistical process supervision data to a file or on a serial channel Reads statistical process supervision information Deactivates statistical process supervision Orders a variable interrupt Read a block of data from the sensor device Read a variable from the sensor device Write a block of data to the sensor device Write a variable to the sensor device Product Specification RobotWare Options for BaseWare OS 4.0 [556] Arcitec [556] Arcitec This option is intended to be used in combination with the Arcitec power sources. It shall only be ordered by the supplying unit of Arcitec. The package is a special software, used together with the ArcWare package, to be able to control not only the robot program but also the set up, configuration and programming of the power source. Thus the robot teach pendant will be used for programming and tuning both the robot and the power source. The package also includes a special aid for easy welding programming, i.e. the synergic function. This means that there is a pre-programmed relationsship between the wire feed rate and all other data components in the power source, making it easy to control the entire welding process, just by tuning the wire feed rate. Product Specification RobotWare Options for BaseWare OS 4.0 41 [553] SpotWare [553] SpotWare The Spotweld options are general and flexible software platforms for creation of customized and easy to use function packages for different types of spotweld systems and process equipments. The SpotWare option is used for sequential welding with one or several pneumatic gun equipments. If welding with several pneumatic guns at the same time is desired then the SpotWare Plus option has to be used instead. The SpotWare option provides dedicated spotweld instructions for fast and accurate positioning combined with gun manipulation, process start and supervision of the weld equipment. Communication with the welding equipment is normally carried out by means of digital inputs and outputs but a serial interface is also available for some type of weld timers. It should be noted that the SpotWare options are general and can be extensively customized. They have a default “ready to use” functionality directly after install but it is intended that some configuration data, RAPID data and RAPID routines has to be changed during the customizing. SpotWare features Some examples of useful functions are given below: - Fast and accurate positioning using the unique QuickMove and TrueMove concept. - Gun pre-closing. - Quick start after a weld. - Handling of an on/off gun with two strokes. - Dual/single gun. - Manual actions for welding and gun control. - Simulation possibilities for test purposes. - Reverse execution with gun control. - Spot counters. - User-defined supervision and error recovery. Weld error recovery with automatic rewelding. - User-defined continuous supervision of the weld equipment, such as weld current signal and water cooling start. Note: This feature requires the MultiTasking option. - Wide customizing possibilities. 42 Product Specification RobotWare Options for BaseWare OS 4.0 [553] SpotWare Principles of SpotWare The SpotWare functions will be controlled by separate internal program processes, which will run in parallel. For instance the robot movements, the continuous supervision and the spot welding will be handled in different independent processes. This means that if for instance the program execution and thus the robot movements is stopped, then the welding and supervision will continue until they come to a well defined process stop. For example, the welding process will carry on and finish the weld and open the gun, although the program has been stopped during the weld phase. For well defined points in the welding sequence and movements, calls to user routines offer adaptations to the plant environment. A number of predefined parameters are also available to shape the behaviour of the SpotWare instructions. Programming principles Both the robot movement and the control of the spot weld equipment are embedded in the basic spot weld instructions SpotL and SpotJ. The spot welding process is specified by: - Spotdata: spot weld process data - Gundata: spot weld equipment data - The system modules SWUSRC and SWUSRF: RAPID routines and global data for changing of process and test behaviour. - System parameters: the I/O Signal configuration. Spot welding instructions Instruction Used to: SpotL Control the motion, gun closure/opening and the welding process. Move the TCP along a linear path and perform a spot welding at the end position. SpotJ Control the motion, gun closure/opening and the welding process. Move the TCP along a non-linear path and perform a spot welding at the end position. Spot welding data Data type Used to define: spotdata The spot weld process gundata The spot weld equipment Product Specification RobotWare Options for BaseWare OS 4.0 43 [554] SpotWare Plus [554] SpotWare Plus The SpotWare Plus package provides support for sequential welding with one or several pneumatic on/off gun equipments, as the SpotWare package, but also welding and full individual monitoring of up to four separate gun equipments at the same time. SpotWare Plus features The SpotWare Plus package contains the same features as SpotWare but with following feature in addition: - Possibility to weld with up to four guns at the same time. Principles of SpotWare Plus As in SpotWare the spotweld functions will be controlled by separate internal program processes, which will run in parallel. For instance the robot movements, the continuous supervision and each spotweld process will be handled in different independent program processes. This means that if for instance the program execution and thus the robot movements is stopped, then the weld processes and supervision will continue until they come to a well defined process stop. For example, the welding processes will carry on and finish the welds and open the guns, although the program has been stopped during the weld phase. For well defined points in the welding sequence, calls to user routines offer adaptations to the plant environment. A number of predefined parameters are also available to shape the behaviour of the SpotWare instruction. The opening and closing of the guns are always executed by RAPID routines. These gun routines may be changed from the simple on/off default functionality to a more complex gun control and they may contain additional gun supervision. SpotWarePlus is based on the DAP (Discrete Application Platform). Programming principles Both the robot movement and control of up to four spot weld processes are embedded in the basic spot weld instructions for multiple welding, SpotML and SpotMJ. Each spot welding process is specified by: - Spotmdata: spot weld process data - Gunmdata: spot weld equipment data - The system modules SWUSRF and SWUSRC: RAPID routines and global data for customizing purposes and data for changing of process and test behaviour. - System parameters: the I/O Signal configuration. 44 Product Specification RobotWare Options for BaseWare OS 4.0 [554] SpotWare Plus Spot welding instructions Instruction Used to: SpotML Control the motion, gun closure/opening and 1 - 4 welding processes. Move the TCP along a linear path and perform spot welding with 1 - 4 gun equipments at the end position. SpotMJ Control the motion, gun closure/opening and 1 - 4 welding processes. Move the TCP along a non-linear path and perform spot welding with 1 - 4 gun equipments at the end position. Spot welding data Data type Used to define: spotmdata The spot weld process gunmdata The spot weld equipment Product Specification RobotWare Options for BaseWare OS 4.0 45 [625] SpotWare Servo [625] SpotWare Servo The Spotweld options are general and flexible software platforms for creation of customized and easy to use function packages for different types of spotweld systems and process equipments. The SpotWare Servo option is used for sequential welding with one or two servo gun equipments. If also welding with two servo guns at the same time is desired then the SpotWare Servo Plus option has to be used instead. The SpotWareServo option provides dedicated spotweld instructions for fast and accurate positioning combined with gun manipulation, process start and supervision of the different gun equipments. Communication with the welding equipment is carried out by means of digital inputs and outputs. It should be noted that the SpotWare options are general and can be extensively customized. They have a default “ready to use” functionality directly after install but it is intended that some configuration data, RAPID data and RAPID routines has to be changed during the customizing. SpotWare Servo features The SpotWare Servo package contains the following features: - Fast and accurate positioning using the unique QuickMove and TrueMove concept. - Gun pre-closing, i.e having the gun closing synchronized with weld position. - Gun equalizing, i.e. having the gun “floating” around the weld position. - Constant tip force during welding. - Manual actions for welding and gun control. - Several simulation possibilities for test purposes. - Reverse execution with gun control. - Weld error recovery with automatic rewelding. - User-defined supervision and error recovery. - User-defined autonomous supervision, such as weld current signal and water cooling start. - Wide customizing possibilities. - Default “ready to use” functionality directly after install. - Detecting of missing or improper plates. - Gun calibration functions. - Spot counters and tip wear data for each used gun. 46 Product Specification RobotWare Options for BaseWare OS 4.0 [625] SpotWare Servo - Fast switch between two servo guns with a tool changer. Note: This feature requires the Servo Tool Change option. Principles of SpotWare Servo The SpotWare functions will be controlled by separate internal program processes, which will run in parallel. For instance the robot movements, the continuous supervision and the spotwelding will be handled in different independent processes. This means that if for instance the program execution and thus the robot movements is stopped, then the welding and supervision will continue until they come to a well defined process stop. For example, the welding process will carry on and finish the weld and open the gun, although the program has been stopped during the weld phase. For well defined points in the welding sequence and movements, calls to user routines offer adaptations to the plant environment. A number of predefined parameters are also available to shape the behaviour of the SpotWare instructions. Programming principles Both the robot movement and the control of the spot weld equipment are embedded in the basic spot weld instructions SpotL and SpotJ. The spot welding process is specified by: - Spotdata: spot weld process data - Gundata: spot weld equipment data - The system modules SWDEFINE and SWDEFUSR: RAPID routines and global data for customizing purposes e.g. adaptations for a specific process equipment. - The system module SWUSER: RAPID routines and global data for changing of process and test behaviour. - System parameters: the I/O Signal configuration and the Manipulator configuration. Product Specification RobotWare Options for BaseWare OS 4.0 47 [625] SpotWare Servo Spot welding instructions Instruction Used to: SpotL Control the motion, gun closure/opening and the welding process. Move the TCP along a linear path and perform a spot welding at the end position. SpotJ Control the motion, gun closure/opening and the welding process. Move the TCP along a non-linear path and perform a spot welding at the end position. SetForce Close the gun a predefined time then open the gun. CalibL Calibrate the gun during linear movement to the programmed position. CalibJ Calibrate the gun during non-linear movement to the programmed position. Calibrate Calibrate the gun in current position without movement. STTune Tune motion parameters for the servo gun. STTuneReset Reset tuned motion parameters for the servo gun. Spot welding data 48 Data type Used to define: spotdata The spot weld process gundata The spot weld equipment forcedata The SetForce process simdata Simulation modes Product Specification RobotWare Options for BaseWare OS 4.0 [626] SpotWare Servo Plus [626] SpotWare Servo Plus The SpotWare Servo Plus package provides support for sequential welding with one or several servo gun equipments, as the SpotWare Servo package, but also welding with two servo guns at the same time. SpotWare Servo Plus features The SpotWare Servo Plus package contains the same features as SpotWareServo but with following feature in addition: - Possibility to weld with two servo guns at the same time. Principles of SpotWare Servo Plus As in SpotWare Servo the SpotWare functions will be controlled by separate internal program processes, which will run in parallel. For instance the robot movements, the continuous supervision and the spotwelding will be handled in different independent processes. This means that if for instance the program execution and thus the robot movements is stopped, then the weld processes and supervision will continue until they come to a well defined process stop. For example, the welding processes will carry on and finish the weld and open the guns, although the program has been stopped during the weld phase. Programming principles Both the robot movement and the control of the spot weld equipments are embedded in the basic spot weld instructions. SpotL and SpotJ are used for sequential welding. With SpotML or SpotMJ it is possible to weld with several guns simultaneously. Each spot welding process is specified by: - Spotdata: spot weld process data - Gundata: spot weld equipment data - The system modules SWDEFINE and SWDEFUSR: RAPID routines and global data for customizing purposes e.g. adaptations for a specific process equipment. - The system module SWUSER: RAPID routines and global data for changing of process and test behaviour. - System parameters: the I/O Signal configuration and the Manipulator configuration. Spot welding instructions The SpotWare Servo Plus package contains the same instructions as SpotWareServo plus following instructions in addition: Product Specification RobotWare Options for BaseWare OS 4.0 49 [626] SpotWare Servo Plus 50 Instruction Used to: SpotML Control the motion, gun closure/opening and 1 - 2 welding processes. Move the TCP along a linear path and perform spot welding with 1 - 2 gun equipments at the end position. SpotMJ Control the motion, gun closure/opening and 1 - 2 welding processes. Move the TCP along a non-linear path and perform spot welding with 1 - 2 gun equipments at the end position. Product Specification RobotWare Options for BaseWare OS 4.0 [569] DispenseWare [569] DispenseWare The DispenseWare package provides support for different types of dispensing processes such as gluing and sealing. The DispenseWare application provides fast and accurate positioning combined with a flexible process control. Communication with the dispensing equipment is carried out by means of digital and analog outputs. DispenseWare is a package that can be extensively customized. The intention is that the user adapts some user data and routines to suit a specific dispensing equipment and the environmental situation. Dispensing features The DispenseWare package contains the following features: - Fast and accurate positioning. - Handling of on/off guns as well as proportional guns. - Speed proportional or constant analog outputs. - Up to five different guns can be handled simultaneously, controlled by 1 - 5 digital output signals (for gun on/off control) and 1 - 2 analog output signals (for flow control). - Four different gun equipment, each controlled by 1 - 5 digital output signals and 1 - 2 analog output signals, can be handled in the same program. - Possibility to use different anticipated times for the digital and analog signals. - Possibility to use equipment delay compensation for the TCP speed proportional analog signals. - Global or local flow rate correction factors. - Dispensing instructions for both linear and circular paths. - Dispensing in wet or dry mode. - Wide opportunities of customizing the functionality to adapt to different types of dispensing equipment. - Possibility to restart an interrupted dispense sequence. Programming principles Both the robot’s movement and the dispensing process control are embedded in the instructions, DispL and DispC respectively. Product Specification RobotWare Options for BaseWare OS 4.0 51 [569] DispenseWare The gluing process is specified by: - Bead specific dispensing data. See Data types - beaddata. - Equipment specific dispensing data. See Data types - equipdata. - RAPID routines and global data for customizing purposes. See Predefined Data and Programs - System Module DPUSER. - The I/O configuration. See System Parameters - DispenseWare Dispensing instructions Instruction Used to: DispL Move the TCP along a linear path and perform dispensing with the given data DispC Move the TCP along a circular path and perform dispensing with the given data Dispensing data 52 Data type Used to define: beaddata Dispensing data for the different beads. equipdata Dispensing data for the equipment in use. Product Specification RobotWare Options for BaseWare OS 4.0 [571] PalletWare [571] PalletWare General PalletWare is a ready-to-use software package for the S4Cplus controller, focused on palletizing. PalletWare imports data created with PalletWizard, the included off-line PC-tool, to execute the defined palletizing cycles. PalletWare has a predefined interface for connecting PLC (Programmable Logic Controller), which is the most common way to control external equipment such as infeeders, outfeeders and sensor equipment. The standard package includes software components such as priority and scheduling routines that are ready to use. The package also includes components that can be customized, e.g. grip tool control routines. PalletWare supports system integrators who want to customize the system, by presenting a standardized interface. What is included Included in the PalletWare package is software components to control robot motion, and to communicate with the user and external equipment. In order to minimize commissioning time, PalletWare is equipped with a standardized set of modules, referred to as the Standard Package Add-On. Advanced users can replace these modules with their own if special customizing is needed. PalletWare is also delivered with template user routines that handles the most common solutions. PalletWare offers a standardized interface where to connect all external equipment such as infeeders, PLC, signal board, grip tool, sensor equipment etc. The package includes a set of predefined signals connected to a simulated board. The integrator has to implement the signal board and connect the signals. The configuration file for the signals has also to be modified depending on what type of board is used. Because of the large amount of signals, it is recommended to use a field bus such as for example Profibus. PalletWare features PalletWare offers for example following functionality: - Multiplacing - Parallel processing, up to 5 stations simultaneously - Multistationary production - User dialogue interface with Screen Viewer - On-line tuning of geometrical data - Safety functionality - Prepared PLC interface - Prepared MMI interface Product Specification RobotWare Options for BaseWare OS 4.0 53 [571] PalletWare - Tool control - Standardized error handling - Predefined user routines Programming principles PalletWare is added to the BaseWare system. PalletWare consists of predefined motion principles and communication routines for communicating with external equipment. It is not necessarily needed to implement any RAPID code. However, the system supports integrators for customizing by standardized functions and instructions. Customizing PalletWare PalletWare can be up-and-running without any need for implementing RAPID code, but it must be adapted to the current robot cell and its physical lay-out. For instance, there are a number of steps which are compulsory, e.g: - Connect external equipment such as infeeders, tool, PLC etc., via the predefined interface. - Connect safety equipment such as emergency stop, safety fences etc. - Define tooldata if the tool does not match the templates - Check the set-up in the configuration module PAL_CFG. - Define/teach work objects to the stations - Define/teach robtarget with tool in zero orientation - Create and load pallet cycles with PalletWizard. In addition to this, PalletWare offers a great deal of customizing possibilities for advanced users, e.g. - Using tools with suction cups or mechanical gripper - Sliding uppermost layer to gain pallet height - Controlling orientation on infeeder - Add or skip safety height movements between stations - Set priority when working with several pallet cycles in parallel. - Etc. Pallet Wizard Pallet Wizard is a complete and easy to use stand alone tool running on a PC under Windows 95/98 or Windows NT, for off line programming of palletizing or depalletizing processes. It is delivered as a part of the PalletWare option package. In PalletWizard the complete cell with its different components like the products, the tools, the in/out feeders and pallet stations as well as the pallet cycles with the layers and the pattern descriptions can be defined. 54 Product Specification RobotWare Options for BaseWare OS 4.0 [571] PalletWare PalletWizard offers for example the following features: - Detailed On-line help - Wizards for defining the products, tools, cell definition, station configurations, pallet composition and the pallet cycles - Automatic pick- and place definition - Automatic calculating of grip zones to be used for the tool - Software based collision detection - Library of predefined patterns Several different pallet cycles can be combined into a production cycle and saved into a file, which can be downloaded to the robot. At the robot the operator can then select what specific pallet cycle to run and on which infeeder and pallet station. Product Specification RobotWare Options for BaseWare OS 4.0 55 Index INDEX 4 Index A AbsAcc 5 Absolute Accuracy 5 Advanced functions 14 arc welding 37, 40 Arcitec 41 ArcWare 37 ArcWare Plus 40 B BaseWare 5 BaseWare Options 3 BaseWare OS 3 C Collision Detection 7 communication robot and PC 33 continuous movement 13 Contour tracking 12 Conveyor Tracking 23, 27, 29 coordinated motion 12 cross-connection locigal conditions 16 output 15 procedure call 15 Friction Compensation 13 FTP 32 I I/O Plus 36 independent movement 13 input or output signals interrupts 17 Interbus Configuration Tool 34 interrupt routine movement 16 interrupts from analog input or output signals 17 L Load Identification 7 logical conditions cross connections 16 N NFS 32 O output in fixed position 15 P D data read and write 14, 33 transfer 14 Discrete Applications Platform 22 DispenseWare 51 E electronically linked motors 24 error handler movement 16 Ethernet Services 32 F file read and write 14, 33 fixed position PalletWare 53 parallel processing 11 PLC functionality 16 printout 14 ProcessWare 3, 37 Profibus Configuration Tool 35 Profibus DP 35 program back-up 33 transfer 33 R RAP Communication 31 read data 14 file 14 Product Specification RobotWare Options for BaseWare OS 4.0 57 Index Reset the work area 12 S Sensor Interface 26 Sensor Synchronization 25 serial channel 14 Servo Tool Change 29 Servo Tool Control 27 SpotWare Servo 46 SpotWare Servo Plus 49 T transfer data 14, 33 file 33 program 33 W World Zones 16 write data 14 file 14 58 Product Specification RobotWare Options for BaseWare OS 4.0 Installation Manual, IRB 6600/6650, M2000A 3HAC 16245-1 Revision A The information in this manual is subject to change without notice and should not be construed as a commitment by ABB. ABB assumes no responsibility for any errors that may appear in this manual. In no event shall ABB be liable for incidental or consequential damages arising from use of this manual and products described herein. This manual and parts thereof must not be reproduced or copied without ABB’s written permission, and contents thereof must not be imparted to a third party nor be used for any unauthorized purpose. Contravention will be prosecuted. Additional copies of this manual may be obtained from ABB at its then current charge. ©Copyright 2002 ABB All rights reserved. ABB Automation Technology Products AB Robotics SE-721 68 Västerås Sweden Table of Contents 0.0.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 0.0.2 Product Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 Chapter 1: Safety, service 9 1.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9 Section 1.1: General information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 1.1.1 Safety, service - General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.1.2 Limitation of Liability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.1.3 Related information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 Section 1.2: Safety risks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.2.1 Safety risks related to gripper. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.2.2 Safety risks related to tools/workpieces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.2.3 Safety risks related to pneumatic/hydraulic systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.2.4 Safety risks during operational disturbances . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.2.5 Safety risks during installation and service . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12 1.2.6 Risks associated with live electric parts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12 Section 1.3: Safety actions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 1.3.1 Safety fence dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 1.3.2 Fire extinguishing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 1.3.3 Emergency release of the manipulator’s arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 1.3.4 Brake testing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 1.3.5 Risk of disabling function "Reduced speed 250 mm/s". . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15 1.3.6 Safe use of the Teach Pendant Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15 1.3.7 Work inside the manipulator’s working range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15 Chapter 2: Reference information 17 2.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17 Section 2.1: Reference information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18 2.1.1 Applicable Safety Standards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18 2.1.2 Screw joints . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19 2.1.3 Weight specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21 2.1.4 Standard toolkit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22 2.1.5 Special tools . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 2.1.6 Performing a leak-down test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .25 2.1.7 Lifting equipment and lifting instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .26 Chapter 3: Unpacking 27 3.0.1 Pre-installation procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27 3.0.2 Working range, IRB 6600 - 175/2.55 and IRB 6600 - 225/2.55 . . . . . . . . . . . . . . . . . . . . . . .30 3.0.3 Working range, IRB 6600 - 175/2.8. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .31 3.0.4 Working range, IRB 6650 - 125/3.2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32 3.0.5 Working range, IRB 6650 - 200/2.75. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 3.0.6 Risk of tipping/Stability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .34 Chapter 4: On-site Installation 35 Section 4.1: On-site installation, manipulator. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .36 4.1.1 Lifting manipulator with fork lift . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .36 4.1.2 Lifting manipulator with roundslings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .41 4.1.3 Lifting manipulator with lifting slings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .42 4.1.4 Manually releasing the brakes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .44 4.1.5 Lifting the base plate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .49 4.1.6 Securing the base plate. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .50 4.1.7 Orienting and securing the manipulator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .53 4.1.8 Fitting equipment on manipulator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .56 4.1.9 Loads . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .60 3HAC 16245-1 i Table of Contents Section 4.2: Restricting the working range. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61 4.2.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61 4.2.2 Mechanically restricting the working range of axis 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62 4.2.3 Mechanically restricting the working range of axis 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64 4.2.4 Mechanically restricting the working range of axis 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66 4.2.5 Position switches . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 Section 4.3: On-site installation, controller cabinet. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 4.3.1 Lifting the controller cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 4.3.2 Required installation space, control cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74 Chapter 5: Electrical connections 75 Section 5.1: Signal/Power cables. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76 5.1.1 Connecting the manipulator to the control cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76 5.1.2 Connection of manipulator cables to control cabinet, S4Cplus M2000A . . . . . . . . . . . . . . . . 79 5.1.3 Connection of mains power to control cabinet, S4Cplus M2000A . . . . . . . . . . . . . . . . . . . . . 80 Section 5.2: Signal connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82 5.2.1 Signal Classes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82 5.2.2 Selecting Cables. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 5.2.3 Interference elimination . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84 5.2.4 Connection types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 5.2.5 Connections to screw terminals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 5.2.6 Connections to connectors (option) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87 Section 5.3: Customer connections on manipulator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 5.3.1 Signal connections, SpotWelding Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 5.3.2 Signal connections, Material Handling Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89 Section 5.4: Customer connections on controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90 5.4.1 The MOTORS ON/MOTORS OFF circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90 5.4.2 External customer connections on panel X1 - X4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 5.4.3 Connection of external safety relay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98 Section 5.5: Supplies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 5.5.1 External 24V supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 5.5.2 24V I/O supply. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101 5.5.3 115/230 VAC supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 Section 5.6: Buses. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 5.6.1 Connection of the CAN bus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 5.6.2 Interbus-S, slave DSQC 351 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 5.6.3 Profibus-DP, slave DSQC 352. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110 Section 5.7: I/O units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113 5.7.1 Distributed I/O units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113 5.7.2 Distributed I/O, digital sensors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114 5.7.3 Distributed I/O, digital I/O DSQC 328 (option) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115 5.7.4 AD Combi I/O, DSQC 327 (optional) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118 5.7.5 Analog I/O, DSQC 355 (optional) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 121 5.7.6 Encoder interface unit, DSQC 354 (optional) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125 Section 5.8: Communication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129 5.8.1 Allen-Bradley, general. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129 5.8.2 RIO, remote I/O for Allen-Bradley PLC DSQC 350. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130 5.8.3 Communication, serial links . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133 5.8.4 Communication, Ethernet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 136 5.8.5 External operator’s panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 138 Chapter 6: Start-up 139 6.0.1 Inspection before start-up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 139 6.0.2 Start-up. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 140 ii 3HAC 16245-1 Table of Contents Chapter 7: Installation of controller software 141 7.0.1 Loading system software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .141 7.0.2 RobotWare CD-ROM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .143 7.0.3 Installing new Robot Controller Software with RobInstall . . . . . . . . . . . . . . . . . . . . . . . . . .144 7.0.4 Create a new Robot Controller System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .146 7.0.5 Update the Robot Controller image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .150 7.0.6 Transfer Robot Controller System using Ethernet connection. . . . . . . . . . . . . . . . . . . . . . . .151 7.0.7 Transfer Robot Controller System using floppy disks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .154 7.0.8 RobInstall preferences . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .156 Chapter 8: Robot controller 157 8.0.1 BootImage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .157 8.0.2 Start window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .158 8.0.3 Reboot Window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .159 8.0.4 Boot Disk Window. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .160 8.0.5 LAN Settings Window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .161 8.0.6 Service Settings Window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .162 8.0.7 System selection window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .163 8.0.8 How to perform a Restart . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .164 8.0.9 How to Start in Query Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .167 Chapter 9: System directory structure 169 9.0.1 Media pool in the PC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .169 9.0.2 System pool in the PC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .170 9.0.3 File structure in the robot controller mass storage memory. . . . . . . . . . . . . . . . . . . . . . . . . .171 9.0.4 Preparation of S4Cplus software to be installed . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .172 9.0.5 Handling mass memory storage capacity. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .173 Chapter 10: Calibration 175 Section 10.1: General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .175 10.1.1 Types of calibration procedures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .175 10.1.2 How to calibrate the robot system . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .176 10.1.3 Calibration, prerequisites . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .178 10.1.4 Calibration pendulum kit, contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .179 Section 10.2: Preliminaries . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .181 10.2.1 Checking the calibration position. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .181 10.2.2 Updating the revolution counter. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .183 10.2.3 Calibration procedure on TPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .185 10.2.4 Initialization of calibration pendulum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .186 Section 10.3: Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .188 10.3.1 Calibration sensor mounting positions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .188 10.3.2 Calibration scales . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .194 10.3.3 Calibration, all axes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .195 10.3.4 Calibrating axes 3-4, IRB 7600/2.3/500. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .197 Section 10.4: After calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .198 10.4.1 Post calibration procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .198 Section 10.5: Alternative calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .199 10.5.1 Alternative calibration position . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .199 10.5.2 Alternative calibrating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .200 10.5.3 New calibration position, axis 1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .201 10.5.4 New calibration offset, axis 1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .202 10.5.5 Retrieving offset values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .203 3HAC 16245-1 iii Table of Contents Chapter 11: Decommissioning 205 11.0.1 Balancing device, IRB 7600 and IRB 6600/6650 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 205 iv 3HAC 16245-1 0.0.1 Overview 0.0.1 Overview About This Manual This information product is a manual containing instructions for installing the complete robot system, mechanically as well as electrically. Usage This manual should be used during installation, from lifting the manipulator to its work site thru installing application software in the robot controller, making the robot ready for operation. Who Should Read This Manual? This manual is intended for: Prerequisites The reader should... • • Organization of Chapters installation personnel on the installation site. have the required knowledge of mechanical as well as electrical installation work. The information product is organized in the following chapters: Chapter Contents 1 Safety, Service 2 Reference Information 3 Unpacking 4 On-site Installation 5 Electrical connections 6 Start-up 7 Installation of controller software 8 Robot controller 9 System directory structure 10 Calibration 11 Decommissioning References 3HAC 16245-1 Reference Document Id Circuit Diagram, manipulator 3HAC 13347-1 Circuit Diagram, controller 3HAC 14189-2 A 5 0.0.1 Overview Revisions Revision Description - First edition A 6 • Various corrections in text and in figures due to reconstructions, new options, etc. • Manual completed with references to pagenumbers and numbering of sections (manipulator sections). • Manual completed with version IRB 6650. A 3HAC 16245-1 0.0.2 Product Documentation 0.0.2 Product Documentation General The complete product documentation kit for the robot, including controller, manipulator and any hardware option, consists of the manuals listed below: Installation and Commissioning Manual The Installation and Commissioning Manual contains the following information: Repair Manual Maintenance Manual • Safety, Service • Reference Information • Unpacking • On-site Installation • Electrical connections • Start-up • Installation of controller software • System directory structure • Calibration • If there is any, model specific information The Repair Manual contains the following information: • Safety, Service • Reference Information • Remove/Refitting instructions for all manipulator details considered spare parts • Remove/Refitting instructions for all controller cabinet details considered spare parts • If there is any, model specific information The Maintenance Manual contains the following information: • Safety, Service • Reference Information • Maintenance schedules • Instructions for all maintenance activities specified in the maintenance schedule, for example cleaning, lubrication, inspection etc. • If there is any, model specific information The information is generally divided into separate chapters for the manipulator and the controller, respectively. Software manuals The software documentation consists of a wide range of manuals, ranging from manuals for basic understanding of the operating system to manuals for entering parameters during operation. A complete listing of all available software manuals is available from ABB Robotics. 3HAC 16245-1 A 7 0.0.2 Product Documentation Hardware option manual Each hardware option is supplied with its own documentation. Each document set contains the types of information specified above: • Installation information • Repair information • Maintenance information In addition, spare part information is supplied for the complete option. 8 A 3HAC 16245-1 1 Safety, service 1.0.1 Introduction Chapter 1: Safety, service 1.0.1 Introduction Definitions This chapter details safety information for service personnel i.e. personnel performing installation, repair and maintenance work. Sections The chapter "Safety, service" is divided into the following sections: 1. General information contains lists of: • Safety, service -general • Limitation of liability • Referenced documents 2. Safety risks lists dangers relevant when servicing the robot system. The dangers are split into different categories: • Safety risks related to gripper/end effector • Safety risks related to tools/workpieces • Safety risks related to pneumatic/hydraulic systems • Safety risks during operational disturbances • Safety risks during installation and service • Risks associated with live electric parts 3. Safety actions details actions which may be taken to remedy or avoid dangers. • Safety fence dimensions • Fire extinguishing • Emergency release of the manipulator´s arm • Brake testing • Risk of disabling function "Reduced speed 250 mm/s" • Safe use of the Teach Pendant Unit enabling device • Work inside the manipulator´s working range 3HAC 16245-1 A 9 1 Safety, service 1.1.1 Safety, service - General Section 1.1: General information 1.1.1 Safety, service - General Validity and responsibility The information does not cover how to design, install and operate a complete system, nor does it cover all peripheral equipment, which can influence the safety of the total system. To protect personnel, the complete system must be designed and installed in accordance with the safety requirements set forth in the standards and regulations of the country where the robot is installed. The users of ABB industrial robots are responsible for ensuring that the applicable safety laws and regulations in the country concerned are observed and that the safety devices necessary to protect people working with the robot system have been designed and installed correctly. Personnel working with robots must be familiar with the operation and handling of the industrial robot, described in the applicable documents, e.g. User’s Guide and Product Manual. Connection of external safety devices Apart from the built-in safety functions, the robot is also supplied with an interface for the connection of external safety devices. Via this interface, an external safety function can interact with other machines and peripheral equipment. This means that control signals can act on safety signals received from the peripheral equipment as well as from the robot. In the Product Manual - Installation and Commissioning, instructions are provided for connecting safety devices between the robot and the peripheral equipment. 1.1.2 Limitation of Liability General Any information given in this information product regarding safety, must not be construed as a warranty by ABB Robotics that the industrial robot will not cause injury or damage even if all safety instructions have been complied with. 1.1.3 Related information General The list below specifies documents which contain useful information: Documents 10 Type of information Detailed in document Installation of safety devices Installation and Commissioning Manual Changing robot modes User’s Guide Start-up Restricting the working space Installation and Commissioning Manual On-site installation Manipulator A Section 3HAC 16245-1 1 Safety, service 1.2.1 Safety risks related to gripper Section 1.2: Safety risks 1.2.1 Safety risks related to gripper Ensure that a gripper is prevented from dropping a workpiece, if such is used. 1.2.2 Safety risks related to tools/workpieces Safe handling It must be possible to turn off tools, such as milling cutters, etc., safely. Make sure that guards remain closed until the cutters stop rotating. It should be possible to release parts by manual operation (valves). Safe design Grippers/end effectors must be designed so that they retain workpieces in the event of a power failure or a disturbance of the controller. 1.2.3 Safety risks related to pneumatic/hydraulic systems General Residual energy Safe design Special safety regulations apply to pneumatic and hydraulic systems. • Residual energy may be present in these systems so, after shutdown, particular care must be taken. • The pressure in pneumatic and hydraulic systems must be released before starting to repair them. • Gravity may cause any parts or objects held by these systems to drop. • Dump valves should be used in case of emergency. • Shot bolts should be used to prevent tools, etc., from falling due to gravity. 1.2.4 Safety risks during operational disturbances General Qualified personnel Extraordinary risks 3HAC 16245-1 • The industrial robot is a flexible tool which can be used in many different industrial applications. • All work must be carried out professionally and in accordance with the applicable safety regulations. • Care must be taken at all times. • Remedial action must only be carried out by qualified personnel who are familiar with the entire installation as well as the special risks associated with its different parts. If the working process is interrupted, extra care must be taken due to risks other than those associated with regular operation. Such an interruption may have to be rectified manually. A 11 1 Safety, service 1.2.5 Safety risks during installation and service 1.2.5 Safety risks during installation and service General risks during installation and service Nation/region specific regulations Non-voltage related risks To be observed by the supplier of the complete system • The instructions in the Product Manual - Installation and Commissioning must always be followed. • Emergency stop buttons must be positioned in easily accessible places so that the robot can be stopped quickly. • Those in charge of operations must make sure that safety instructions are available for the installation in question. • Those who install the robot must have the appropriate training for the robot system in question and in any safety matters associated with it. To prevent injuries and damage during the installation of the robot system, the regulations applicable in the country concerned and the instructions of ABB Robotics must be complied with. • Safety zones, which have to be crossed before admittance, must be set up in front of the robot's working space. Light beams or sensitive mats are suitable devices. • Turntables or the like should be used to keep the operator out of the robot's working space. • The axes are affected by the force of gravity when the brakes are released. In addition to the risk of being hit by moving robot parts, you run the risk of being crushed by the tie rod. • Energy, stored in the robot for the purpose of counterbalancing certain axes, may be released if the robot, or parts thereof, is dismantled. • When dismantling/assembling mechanical units, watch out for falling objects. • Be aware of stored heat energy in the controller. • Never use the robot as a ladder, i.e. do not climb on the robot motors or other parts during service work. There is a serious risk of slipping because of the high temperature of the motors or oil spills that can occur on the robot. • The supplier of the complete system must ensure that all circuits used in the safety function are interlocked in accordance with the applicable standards for that function. • The supplier of the complete system must ensure that all circuits used in the emergency stop function are interlocked in a safe manner, in accordance with the applicable standards for the emergency stop function. 1.2.6 Risks associated with live electric parts Voltage related risks, general Voltage related risks, controller 12 • Although troubleshooting may, on occasion, have to be carried out while the power supply is turned on, the robot must be turned off (by setting the mains switch to OFF) when repairing faults, disconnecting electric leads and disconnecting or connecting units. • The mains supply to the robot must be connected in such a way that it can be turned off outside the robot’s working space. A danger of high voltage is associated with the following parts: • Be aware of stored electrical energy (DC link) in the controller. A 3HAC 16245-1 1 Safety, service 1.2.6 Risks associated with live electric parts • Units inside the controller, e.g. I/O modules, can be supplied with power from an external source. • The mains supply/mains switch • The power unit • The power supply unit for the computer system (230 VAC) • The rectifier unit (400-480 VAC and 700 VDC. Note: Capacitors!) • The drive unit (700 VDC) • The service outlets (115/230 VAC) • The power supply unit for tools, or special power supply units for the machining process • The external voltage connected to the control cabinet remains live even when the robot is disconnected from the mains. • Additional connections Voltage related risks, manipulator A danger of high voltage is associated with the manipulator in: Voltage related risks, tools, material handling devices, etc Tools, material handling devices, etc., may be live even if the robot system is in the OFF position. Power supply cables which are in motion during the working process may be damaged. 3HAC 16245-1 • The power supply for the motors (up to 800 VDC) • The user connections for tools or other parts of the installation (max. 230 VAC, see Installation and Commissioning Manual) A 13 1 Safety, service 1.3.1 Safety fence dimensions Section 1.3: Safety actions 1.3.1 Safety fence dimensions General Fit a safety fence or enclosure around the robot to ensure a safe robot installation. Dimensioning Dimension the fence or enclosure to enable it to withstand the force created if the load being handled by the robot is dropped or released at maximum speed. Determine the maximum speed from the maximum velocities of the robot axes and from the position at which the robot is working in the work cell (see Product Specification - Description, Robot Motion). Also consider the maximum possible impact caused by a breaking or malfunctioning rotating tool or other device fitted to the manipulator. 1.3.2 Fire extinguishing Use a CARBON DIOXIDE (CO 2 ) extinguisher in the event of a fire in the robot (manipulator or controller)! 1.3.3 Emergency release of the manipulator’s arm Description In an emergency situation, any of the manipulator’s axes may be released manually by pushing the brake release buttons on the manipulator or on an optional external brake release unit. How to release the brakes is detailed in section "Manually releasing the brakes". The manipulator arm may be moved manually on smaller robot models, but larger models may require using an overhead crane or similar. Increased injury Before releasing the brakes, make sure that the weight of the arms does not increase the pressure on the trapped person, which may further increase any injury! 1.3.4 Brake testing When to test During operation the holding brakes of each axis motor wear normally. A test may be performed to determine whether the brake can still perform its function. How to test The function of each axis’ motor holding brakes may be checked as detailed below: 1. Run each manipulator axis to a position where the combined weight of the manipulator arm and any load is maximized (max. static load). 2. Switch the motor to the MOTORS OFF position with the Operating mode selector on the controller. 3. Check that the axis maintains its position. If the manipulator does not change position as the motors are switched off, then the brake function is adequate. 14 A 3HAC 16245-1 1 Safety, service 1.3.5 Risk of disabling function "Reduced speed 250 mm/s" 1.3.5 Risk of disabling function "Reduced speed 250 mm/s" Do not change "Transm gear ratio" or other kinematic parameters from the Teach Pendant Unit or a PC. This will affect the safety function Reduced speed 250 mm/s. 1.3.6 Safe use of the Teach Pendant Unit The enabling device is a push button located on the side of the Teach Pendant Unit (TPU) which, when pressed halfway in, takes the system to MOTORS ON. When the enabling device is released or pushed all the way in, the robot is taken to the MOTORS OFF state. To ensure safe use of the Teach Pendant Unit, the following must be implemented: The enabling device must never be rendered inoperative in any way. During programming and testing, the enabling device must be released as soon as there is no need for the robot to move. The programmer must always bring the Teach Pendant Unit with him/her, when entering the robot’s working space. This is to prevent anyone else taking control over the robot without the programmer knowing. 1.3.7 Work inside the manipulator’s working range If work must be carried out within the robot’s work envelope, the following points must be observed: - The operating mode selector on the controller must be in the manual mode position to render the enabling device operative and to block operation from a computer link or remote control panel. - The robot’s speed is limited to max. 250 mm/s when the operating mode selector is in position < 250 mm/s. This should be the normal position when entering the working space. The position 100% ”full speed”may only be used by trained personnel who are aware of the risks that this entails. - Pay attention to the rotating axes of the manipulator! Keep a distance to the axes in order not to get entangled with hair or clothing. Also be aware of any danger that may be caused by rotating tools or other devices mounted on the manipulator or inside the cell. - Test the motor brake on each axis, according to section Brake testing on page 14. 3HAC 16245-1 A 15 1 Safety, service 1.3.7 Work inside the manipulator’s working range 16 A 3HAC 16245-1 2 Reference information 2.0.1 Introduction Chapter 2: Reference information 2.0.1 Introduction General 3HAC 16245-1 This chapter presents generic pieces of information, complementing the more specific information in the following chapters. A 17 2 Reference information 2.1.1 Applicable Safety Standards Section 2.1: Reference information 2.1.1 Applicable Safety Standards Standards, general Standards, robot cell 18 The robot is designed in accordance with the requirements of: • EN 775 - Robot safety. • EN 292-1 - Basic terminology. • EN 292-2 - Technical principles. • EN 418 - Emergency stop. • EN 563 - Temperatures of surfaces. • EN 954-1 - Safety related parts of control systems. • EN 60204-1 - Electrical equipment of machines. • EN 1050 - Principles for risk assessment. • ANSI/RIA 15.06-1999 - Industrial robots, safety requirements. • DIN 19258 - Interbus-S, International Standard The following standards are applicable when the robot is part of a robot cell: • EN 953 - Fixed and moveable guards • EN 811 - Safety distances to prevent danger zones being reached by the lower limbs. • EN 349 - Minimum gaps to avoid crushing of parts of the human body. • EN 294 - Safety distances to prevent danger zones being reached by the upper limbs. • EN 1088 - Interlocking devices • EN 999 - The positioning of protective equipment in respect of approach speeds of the human body. • ISO 11 161 - Industrial automation systems - Safety of intergrated manufacturing systems. A 3HAC 16245-1 2 Reference information 2.1.2 Screw joints 2.1.2 Screw joints General This section details how to tighten the various types of screw joints on the manipulator as well as the controller. The instructions and torque values are valid for screw joints comprising metallic materials and do not apply to soft or brittle materials. Any instructions given in the repair, maintenance or installation procedure description override any value or procedure given here, i.e. these instruction are only valid for standard type screw joints. UNBRAKO screws UNBRAKO is a special type of screw recommended by ABB in certain screw joints. It features special surface treatment (Gleitmo as described below), and is extremely resistant to fatigue. Whenever used, this is specified in the instructions and in such cases no other type of replacement screw is allowed. Using other types of screw will void any warranty and may potentially cause serious damage or injury! Gleitmo treated screws Gleitmo is a special surface treatment to reduce the friction when tightening the screw joint. Screws treated with Gleitmo may be reused 3-4 times before the coating disappears. After this the screw must be discarded and replaced with a new one. When handling screws treated with Gleitmo, protective gloves of nitrile rubber type should be used. Screws lubricated in other ways Screws lubricated with Molycote 1000 (or another lubricant) should only be used when specified in the repair, maintenance or installation procedure descriptions. In such cases, proceed as follows: 1. Lubricate the thread of the screw. 2. Lubricate between the plain washer and screw head. 3. Tighten to the torque specified in section "Tightening torque" below. Screw dimensions of M8 or larger must be tightened with a torque wrench. Screw dimensions of M6 or smaller may be tightened without a torque wrench if this is done by trained and qualified personnel. 3HAC 16245-1 Lubricant Art. no. Molycote 1000 (molybdenum disulphide grease) 1171 2016-618 A 19 2 Reference information 2.1.2 Screw joints Tightening torque Screws with slotted or cross recess head Below are tables specifying the torque values for different screw joint types: Dimension Tightening torque (Nm) Class 4.8 "dry" M2.5 0.25 M3 0.5 M4 1.2 M5 2.5 M6 5.0 Screws with hexagon socket head, “dry” Screws with hexagon socket head, lubricated 20 Dimension Tightening torque (Nm) Class 8.8 "dry" Tightening Tightening torque (Nm) torque (Nm) Class 10.9 "dry" Class 12.9 "dry" M5 6 - - M6 10 - - M8 24 34 40 M10 47 67 80 M12 82 115 140 M16 200 290 340 Dimension Tightening torque (Nm) Class 10.9 Tightening torque (Nm) Class 12.9 M8 28 34 M10 55 66 M12 96 115 M16 235 280 A 3HAC 16245-1 2 Reference information 2.1.3 Weight specifications 2.1.3 Weight specifications Definition In all repair and maintenance instructions, weights of the components handled are sometimes specified. All components exceeding 22 kg (50 lbs) are high-lighted in this way. ABB recommends the use of lifting equipment when handling components with a weight exceeding 22 kg to avoid inflicting injury. A wide range of lifting tools and devices is available for each manipulator model. Example Below is an example of how a weight specification is presented: The motor weighs 65 kg! All lifting equipment used must be dimensioned accordingly! 3HAC 16245-1 A 21 2 Reference information 2.1.4 Standard toolkit 2.1.4 Standard toolkit General All service (repairs, maintenance and installation) instructions contain lists of tools required to perform the specified activity. All special tools required are listed directly in the instructions while all the tools that are considered standard are gathered in the Standard toolkit and defined in the table below. In this way, the tools required are the sum of the Standard Toolkit and any tools listed in the instruction. Contents, standard toolkit, 3HAC 15571-1 22 Qty Tool Rem. 1 Ring-open-end spanner 8-19mm 1 Socket head cap 5-17mm 1 Torx socket no:20-60 1 Box spanner set 1 Torque wrench 10-100Nm 1 Torque wrench 75-400Nm 1 Ratchet head for torque wrench 1/2 2 Hexagon-headed screw M10x100 1 Socket head cap no:14, socket 40mm bit L 100mm 1 Socket head cap no:14, socket 40mm bit L 20mm 1 Socket head cap no:6, socket 40mm bit L 145mm A To be shorted to 12mm 3HAC 16245-1 2 Reference information 2.1.5 Special tools 2.1.5 Special tools General All service (repairs, maintenance and installation) instructions contain lists of tools required to perform the specified activity. The required tools are a sum of standard tools, defined in section Standard toolkit on page 22, and of special tools, listed directly in the instructions and also gathered in the table below. Special tools, IRB 6600/6650/7600 The table below is an overview of all the special tools required when performing service activities on the IRB 6600/6650/7600. The tools are gathered in two kits: Basic Toolkit (3HAC 15571-3) and Extended Toolkit (3HAC 15571-2). The special tools are also listed directly in the current instructions. 3HAC 16245-1 Description IRB 66X0/Qty IRB 7600/Qty Art. no. Angel bracket a a 68080011-LP Bolts (M16 x 60) for Mech stop ax 3 2 - 3HAB 3409-86 Bolts (M16 x 80) for Mech stop ax 3 - 2 3HAB 3409-89 Cal. tool a a 68080011-GM Calibration bracket a - 3HAC 13908-9 Calibration tool ax1 a a 3HAC 13908-4 CalPen (Calibration Pendulum) 1 1 3HAC 15716-1 Extension 300mm for bits 1/2" 1 1 3HAC 12342-1 Fixture lower arm 1 - 3HAC 13659-1 Fixture lower arm - 1 3HAC 13660-1 Gearbox crank 1 - 3HAC 16488-1 Guide pins M12 x 150 2 - 3HAC 13056-2 Guide pins M12 x 200 2 - 3HAC 13056-3 Guide pins M12 x 250 1 - 3HAC 13056-4 Guide pins M8 x 100 2 - 3HAC 15520-1 Guide pins M8 x 150 2 - 3HAC 15520-2 Guide pins sealing - b 3HAC 14445-1 Guide pins sealing b - 3HAC 14446-1 Guide pins M10 x 100 2 2 3HAC 15521-1 Guide pins M10 x 150 2 2 3HAC 15521-2 Guide pins M16 x 150 - 2 3HAC 13120-2 Guide pins M16 x 200 - 2 3HAC 13120-3 Guide pins M16 x 250 - 1 3HAC 13120-4 Guide pins M16 x 300 2 2 3HAC 13120-5 Guide pins sealing ax 2, 3, 100mm 1 - 3HAC 14628-2 Guide pins sealing ax 2, 3, 80mm 1 - 3HAC 14628-1 Guide pins sealing ax 2, 3, 100mm - 1 3HAC 14627-3 Guide pins sealing ax 2, 3, 80mm - 1 3HAC 14627-2 Hydraulic cylinder 1 1 3HAC 11731-1 Hydraulic pump 80Mpa 1 1 3HAC 13086-1 A 23 2 Reference information 2.1.5 Special tools Description IRB 66X0/Qty IRB 7600/Qty Art. no. Hydraulic pump 80Mpa (Glycerin) b b 3HAC 13086-2 Levelmeter 2000 kit a a 6369901-348 Lifting device, base 1 1 3HAC 15560-1 Lifting device, manipulator 1 1 3HAC 15607-1 Lifting device, upper arm 1 - 3HAC 15994-1 Lifting device, upper arm - 1 3HAC 15536-1 Lifting eye VLBG M12 1 1 3HAC 16131-1 Lifting eye M12 2 2 3HAC 14457-3 Lifting eye M16 2 2 3HAC 14457-4 Lifting tool (chain) 1 1 3HAC 15556-1 Lifting tool, gearbox ax 2 1 - 3HAC 13698-1 Lifting tool, gearbox ax 2 - 1 3HAC 12731-1 Lifting tool, lower arm b b 3HAC 14691-1 Lifting tool, motor ax 1, 4, 5 1 1 3HAC 14459-1 Lifting tool, motor ax 2, 3, 4 1 1 3HAC 15534-1 Lifting tool, wrist unit 1 - 3HAC 13605-1 Lifting tool, wrist unit - 1 3HAC 12734-1 Measuring pin a - 3HAC 13908-5 Mech stop ax 3 2 - 3HAC 12708-1 Mech stop ax 3 - 2 3HAC 12708-2 Press tool, ax 2 bearing 1 - 3HAC 13527-1 Press tool, ax 2 bearing - 1 3HAC 13453-1 Press tool, ax 2 shaft 1 1 3HAC 13452-1 Press tool, balancing device shaft 1 1 3HAC 17129-1 Press tool, balancing device 1 1 3HAC 15767-1 Puller tool, balancing device shaft 1 1 3HAC 12475-1 Removal tool, wheel unit - 1 3HAC 15814-1 Removal tool, motor M10x 2 2 3HAC 14972-1 Removal tool, motor M12x 2 2 3HAC 14631-1 Removal tool, motor M12x 2 2 3HAC 14973-1 Rotation tool 1 1 3HAC 17105-1 Sensor plate a 1 3HAC 0392-1 Support, base 1 1 3HAC 15535-1 Sync. adapter a a 3HAC 13908-1 Tool set balancing device 1 - 3HAC 15943-2 Tool set balancing device - 1 3HAC 15943-1 Turn disk fixture a a 3HAC 68080011GU Washers for Mech stop axis 3 2 2 3HAA 1001-186 Note a) Calibration tools for IRB 6600/6650/7600 when CalPen is not used (standard). Note b) Special tools that may be rent from ATRP/S. 24 A 3HAC 16245-1 2 Reference information 2.1.6 Performing a leak-down test 2.1.6 Performing a leak-down test General After refitting any motor and any gearbox, the integrity of all seals enclosing the gearbox oil must be tested. This is done in a leak-down test. Required equipment Equipment, etc. Spare part no. Art. no. Leakdown tester Note 3HAC 0207-1 Leak detection spray Procedure Step 3HAC 16245-1 Action Note/Illustration 1. Finish the refitting procedure of the motor or gear in question. 2. Remove the topmost oil plug on the gear in question, and replace it with the leakdown tester . Adapters may be required, which are included in the leakdown tester kit. 3. Apply compressed air, and raise the pressure Recommended value: 0.2 - 0.25 with the knob until the correct value is shown on bar (20 - 25 kPa) the manometer. 4. Disconnect the compressed air supply. 5. Wait for approx. 8-10 minutes. No pressure loss If the compressed air is signifimust be detected. cantly colder or warmer than the gearbox to be tested, a slight pressure increase or decrease respectively may occur. This is quite normal. 6. Was any pressure drop evident? Localize the leak as detailed below. Remove the leakdown tester, and refit the oil plug. The test is complete. 7. Spray suspected leak areas with leak detection Art. no. specified above! spray . Bubbles indicate a leak. 8. When the leak has been localized: take the necessary measures to correct the leak. A Art. no. specified above! 25 2 Reference information 2.1.7 Lifting equipment and lifting instructions 2.1.7 Lifting equipment and lifting instructions General Many repair and maintenance activities require different pieces of lifting equipment, which are specified in each activity instruction. However, how to use each piece of lifting equipment is not detailed in the activity instruction, but in the instruction delivered with each piece of lifting equipment. This implies that the instructions delivered with the lifting equipment should be stored for later reference. 26 A 3HAC 16245-1 3 Unpacking 3.0.1 Pre-installation procedure Chapter 3: Unpacking 3.0.1 Pre-installation procedure General This instruction is primarily intended for use when unpacking and installing the manipulator (mechanical robot) for the first time. It also contains information useful during later re-installation of the manipulator. Checking the prerequisites for installation The checklist below details what must be observed before proceeding with the actual installation of the manipulator: 1. Make sure only qualified installation personnel conforming to all national and local codes are allowed to perform the installation. 2. Make sure the manipulator has not been damaged, by visually inspecting the manipulator and control cabinet exterior. 3. Make sure the lifting device to be used is dimensioned to handle the weight of the manipulator as specified in Weight, manipulator on page 27. 4. If the manipulator is not to be installed directly, it must be stored as described in Storage conditions, manipulator on page 28. 5. Make sure the expected operating environment of the manipulator conforms to the specifications as described in Operating conditions, manipulator on page 28. 6. Before taking the manipulator to its installation site, make sure the site conforms to Loads on foundation, manipulator, Requirements on foundation, manipulator on page 28 and Protection classes, manipulator on page 29. 7. Before moving the manipulator, please observe Risk of tipping/Stability on page 34 regarding risk of tipping! 8. When these prerequisites have been met, the manipulator may be taken to its installation site as described in Lifting manipulator with fork lift on page 36. Weight, manipulator 3HAC 16245-1 The table below shows the weights of the different models: Manipulator model Weight IRB 6600 - 175/2.55 1700 kg IRB 6600 - 225/2.55 1700 kg IRB 6600 - 175/2.8 1700 kg IRB 6650 - 125/3.2 1725 kg IRB 6650 - 200/2.75 1700 kg A 27 3 Unpacking 3.0.1 Pre-installation procedure Loads on foundation, manipulator The table below shows the various forces and torques working on the manipulator during different kinds of operation. NOTE! These forces and torques are extreme values that are rarely encountered during operation. The values also never reach their maximum simultaneously! Requirements on foundation, manipulator Storage conditions, manipulator Operating conditions, manipulator 28 Force Endurance load (in operation) Max. load (at emergency stop) Force xy ±10.1 kN ±20.7 kN Force z 18.0 ±13.8 kN 18.0 ±22.4 kN Torque xy ±27.6 kNm ±50.6 kNm Torque z ±7.4 kNm ±14.4 kNm The table below shows the requirements for the foundation where the manipulator is to be fitted: Requirement Value Min. levelity 0.5 mm Max. tilt 5° Min. resonance frequency 22 Hz Note The limit for the maximum payload on the manipulator is reduced if the manipulator is tilted from 0°. Contact ABB for further information about acceptable payload. The table below shows the allowed storage conditions for the manipulator: Parameter Value Min. ambient temperature -25°C Max. ambient temperature +55°C Max. ambient temperature (less than 24 hrs) +70°C Max. ambient humidity Max. 95% at constant temperature The table below shows the allowed operating conditions for the manipulator: Parameter Value Min. ambient temperature +5°C Max. ambient temperature +50°C Max. ambient humidity Max. 95% at constant temperature A 3HAC 16245-1 3 Unpacking 3.0.1 Pre-installation procedure Protection classes, manipulator 3HAC 16245-1 The table below shows the protection class of the manipulator: Equipment Protection class Manipulator, IRB 6600/6650 IP 67 A 29 3 Unpacking 3.0.2 Working range, IRB 6600 - 175/2.55 and IRB 6600 - 225/2.55 3.0.2 Working range, IRB 6600 - 175/2.55 and IRB 6600 - 225/2.55 Illustration The illustration below shows the unrestricted working range of IRB 6600 - 175/2.55 and IRB 6600 - 225/2.55: IR B 6600-175/2,55 IR B 6600-225/2,55 903 1119 1814 2550 xx0200000025 30 A 3HAC 16245-1 3 Unpacking 3.0.3 Working range, IRB 6600 - 175/2.8 3.0.3 Working range, IRB 6600 - 175/2.8 Illustration The illustration below shows the unrestricted working range of IRB 6600 - 175/2.8: IR B 6600-175/2,8 1004 1324 2061 2800 xx0200000026 3HAC 16245-1 A 31 3 Unpacking 3.0.4 Working range, IRB 6650 - 125/3.2 3.0.4 Working range, IRB 6650 - 125/3.2 Illustration The illustration below shows the unrestricted working range of IRB 6650 - 125/3.2: IRB 6650-125/3.2 xx0200000338 32 A 3HAC 16245-1 3 Unpacking 3.0.5 Working range, IRB 6650 - 200/2.75 3.0.5 Working range, IRB 6650 - 200/2.75 Illustration The illustration below shows the unrestricted working range of IRB 6650 - 200/2.75: RB 6650-200/2.75 xx0200000339 3HAC 16245-1 A 33 3 Unpacking 3.0.6 Risk of tipping/Stability 3.0.6 Risk of tipping/Stability Risk of tipping When the manipulator is not fastened to the floor and standing still, the manipulator is not stable in the whole working area. Moving the arms will displace the centre of gravity, which may cause the manipulator to tip over. DO NOT change the manipulator position before securing it to the foundation. Stabililty The figure below shows the manipulator in its shipping position, which also is its most stable position. ° 50 m xx0100000103 1. DO NOT change the manipulator position before securing it to its foundation. The shipping position is the most stable. 34 A 3HAC 16245-1 4 On-site Installation Chapter 4: On-site Installation 3HAC 16245-1 A 35 4 On-site Installation 4.1.1 Lifting manipulator with fork lift Section 4.1: On-site installation, manipulator 4.1.1 Lifting manipulator with fork lift General The manipulator may be moved using a fork lift. Special aids are available. This section applies to the IRB 7600 as well as IRB 6600. Different designs There are two different versions of the fork lift that fit one design of the frame respectevily. The different designs of the frame and of the fork lift attachments are shown in the figure below. Determine which fork lift set fits the current manipulator. Note! The distance between the attachment holes for the fork lift pockets, shown in the figure below, are different depending on the design of the frame. This means that the fork lift sets are unique for one type of frame, they are in other words not compatible! Except for the shorter distance between the attachment holes, the later design of the frame also includes an extra oil plug, located as shown in the figure below. C 1 2 A B xx0200000386 1 Frame version without oil plug on the side (C), fork lift set to be used: 3HAC 0604-2 2 Frame version with oil plug on the side (C), fork lift set to be used: 3HAC 0604-1 A Attachment holes, fork lift 3HAC 0604-2 B Attachment holes, fork lift 3HAC 0604-1 C Oil plug Required equipment 36 Equipment, etc. Art. no. Note Fork lift set, incl. all required hardware 3HAC 0604-2 See Illustration, 3HAC 0604-2 on page 37. Fork lift set, incl. all required hardware 3HAC 0604-1 See Illustration, 3HAC 0604-1 on page 38. A 3HAC 16245-1 4 On-site Installation 4.1.1 Lifting manipulator with fork lift Illustration, 3HAC 0604-2 Equipment, etc. Art. no. Note Standard toolkit 3HAC 15557-1 The contents are defined in section Standard toolkit on page 18. The figure below shows how to attach the fork lift set, 3HAC 0604-2, to the manipulator. A C B xx0100000102 3HAC 16245-1 A Securing screws (2x4 pcs) B Fork lift pockets (2 pcs) C Spacer (2 pcs) A 37 4 On-site Installation 4.1.1 Lifting manipulator with fork lift Illustration, 3HAC 0604-1 The figure below shows how to attach the fork lift set, 3HAC 0604-1, to the manipulator. D E C A B C A xx0200000379 Lifting the manipulator with fork lift A Fork lift pocket (2 pcs, different from each other) B Spacer (2 pcs) C Securing screws (2x4 pcs), not oil lubricated D Securing screws (2 pcs), oil lubricated E Attachment point for spacer The section below details how to secure the fork lift set to the manipulator in order to lift and move the manipulator using the fork lift ONLY! The IRB 6600/6650 manipulator weighs 1725 kg! All lifting equipment used must be dimensioned accordingly! The IRB 7600 manipulator weighs 2550 kg! All lifting equipment used must be dimensioned accordingly! The shorter fork lift pocket weighs 22 kg while the longer version weighs 60 kg! Use a suitable lifting device to avoid injury to personnel! 38 A 3HAC 16245-1 4 On-site Installation 4.1.1 Lifting manipulator with fork lift No personnel must under any circumstances be present under the suspended load! Step Info/Illustration Make sure the manipulator is posiRelease the brakes if required as detailed in tioned as shown in the figure to the Manually releasing the brakes on page 44. right. If it is not, position it that way. Note! Depending on which fork lift set 50° is used, the manipulator may or may not be equipped with a load, see figures on the right! 10° 1. Action m xx0200000079 When using fork lift set 3HAC 0604-2, no load is permitted on the manipulator! 10° 50° m xx0200000387 When using fork lift set 3HAC 0604-1, a load is permitted on the manipulator! 3HAC 16245-1 2. Fit the two spacers to the manipulator Shown in the figures Illustration, 3HAC and secure. 0604-2 on page 37 or Illustration, 3HAC 0604-1 on page 38! 3. Secure the fork lift pocket horizontally Shown in the figure Illustration, 3HAC 0604to the spacers with four washers and 2 on page 37 or Illustration, 3HAC 0604-1 securing screws. on page 38! Notice the tightening torques! All the 4 pcs; M16x60; tightening torque: 60 Nm securing screws are identical, but ±12 Nm (not oil lubricated screws). they are secured with different tight- Make sure the original screws are always ening torques! used (or replacements of equivalent quality: M16, quality 12.9)! A 39 4 On-site Installation 4.1.1 Lifting manipulator with fork lift Step 4. Action Info/Illustration Secure the fork lift pocket vertically by Shown in the figure Illustration, 3HAC 0604fastening the two washers and oil 1 on page 38! lubricated securing screws to the 2 pcs; M16x60; tightening torque: 300 Nm frame (only in fork lift set 3HAC 0604- ±45 Nm. 1!). Make sure the original screws are always used (or replacements of equivalent quality: M16, quality 12.9)! 5. Secure the second fork lift pocket on Shown in figure Illustration, 3HAC 0604-2 the other side of the manipulator with on page 37 or Illustration, 3HAC 0604-1 on securing screws. page 38! 4 pcs; M16x60; tightening torque: 60 Nm ±12 Nm (not oil lubricated screws). Make sure the original screws are always used (or replacements of equivalent quality: M16, quality 12.9)! 6. Double-check that the pockets are properly secured to the manipulator! Insert the fork lift forks into the pockets and carefully lift the manipulator. xx0200000380 Reposition the harness, if any, before using a fork lift! 7. 40 Lift the manipulator and move it to its installation site. A 3HAC 16245-1 4 On-site Installation 4.1.2 Lifting manipulator with roundslings 4.1.2 Lifting manipulator with roundslings General The manipulator may be lifted with roundslings according to the illustration below. The illustration is the same as the label attached to the manipulator´s lower arm. L IF T ING OF R OB OT HE B E N DE S R OB OT E R S L E VAGE DU R OB OT Roundsling, 2000kg Do not strech! Rundschlingen, 2000kg Nicht gespannt! Élingue ronde, 2000kg Ne doivent pas etre sous tension! IRB 6600: m=1700kg, 3750lbs 50 m . 10 700-725 3x Chain sling with shortener, 4250kg, 0.47m, 0.54m, 0.76m. 3x Anschlagketten mit Verkürzer, 4250kg, 0.47m, 0.54m, 0.76m. 3x Chaîne avec crochet raccourcisseur, 4250kg, 0.47m, 0.54m, 0.76m. 3x Roundsling, 2000kg, 2m. 3x Rundschlingen, 2000kg, 2m. 3x Élingue ronde, 2000kg, 2m. 3HAC 16487-1 xx0200000282 - 3HAC 16245-1 Label for lifting of robot, IRB 6600 A 41 4 On-site Installation 4.1.3 Lifting manipulator with lifting slings 4.1.3 Lifting manipulator with lifting slings General The section below applies to IRB 7600 as well as IRB 6600. Illustration, lifting slings The figure below shows how to lift the complete manipulator with lifting slings. Note the recommended manipulator position shown in the following figure and in the instruction! Attempting to lift a manipulator in any other position may result in the manipulator tipping over, causing severe damage or injury! A D C D F C E I L B xx0200000153 42 A Load hook B Swivelling lifting eyes, 4 pcs C Shortening hook D Chain E M12 lifting eye F Lifting device´s eye I Lifting slings, 4 pcs L Hook A 3HAC 16245-1 4 On-site Installation 4.1.3 Lifting manipulator with lifting slings Required equipment Equipment Art. no. Lifting device, manipulator 3HAC 15607-1, includes instruction, 3HAC 15971-2, for how to use the lifting device. Slings attached directly onto manipulator The section below details how to lift and move the manipulator using lifting slings when these are to be attached directly onto the manipulator frame. The IRB 6600/6650 manipulator weighs 1725 kg! All lifting equipment used must be dimensioned accordingly! The IRB 7600 manipulator weighs 2550 kg! All lifting equipment used must be dimensioned accordingly! No personnel must under any circumstances be present under the suspended load! Step Action Note 1. Run the overhead crane to a position above the manipulator. 2. Make sure the manipulator is positioned Release the brakes if required as as shown in the figure on the right. If it is detailed in Manually releasing the not, position it that way. brakes on page 44. ° 50 m xx0100000103 3HAC 16245-1 3. Fit the lifting device, manipulator to the robot as described in the enclosed instruction! 4. Raise the overhead crane to lift the robot. Make sure all hooks and attachments maintain their correct positions while lifting the manipulator! Always move the manipulator at very low speeds, making sure it does not tip. A Art. no. specified in Required equipment on page 43! 43 4 On-site Installation 4.1.4 Manually releasing the brakes 4.1.4 Manually releasing the brakes General The section below details how to release the holding brakes of each axis motor. It applies to IRB 7600 as well as IRB 6600/6650. Differences between the versions are highlighted in the affected sections. The brakes may be released by: • Internal brake release unit: using push buttons on the manipulator. This requires either that the controller is connected or that power is supplied to the R1.MP connector (on manipulator base), 0V on pin 12 and 24V on pin 11. • IRB 7600: External brake release unit: using push-buttons on an external brake release unit. This does NOT require the controller to be connected. The external unit is used when there are no push-buttons on the manipulator. Supplying power on the wrong pins may cause all brakes on the manipulator to be released! Illustration, IRB 6600/6650 The internal brake release unit on the IRB 6600/6650 is located at the frame, as shown in the figure below. 6 5 4 3 2 1 xx0300000044 - 44 Internal brake release unit with push buttons, located on the manipulator frame A 3HAC 16245-1 4 On-site Installation 4.1.4 Manually releasing the brakes Illustration, IRB 7600 base The internal brake release unit on the IRB 7600 is located either at the base or at the frame. The figure below shows the unit located at the base. xx0200000375 - Illustration, IRB 7600 frame Internal brake release unit with push buttons, located on the manipulator base The internal brake release unit on the IRB 7600 is located either at the base or at the frame. The figure below shows the unit located at the frame. 6 5 4 3 2 1 xx0200000376 - 3HAC 16245-1 Internal brake release unit with push buttons, located on the manipulator frame A 45 4 On-site Installation 4.1.4 Manually releasing the brakes Internal brake release unit, releasing the brakes The procedure below details how to release the holding brakes when the robot is equipped with an internal brake release unit. When relasing the holding brakes, the manipulator axes may move very quickly and sometimes in unexpected ways! Make sure no personnel is near the manipulator arm! Step Illustration, IRB 7600 external brake release unit connections Action Info/Illustration 1. The internal brake release unit is equipped with six buttons for controlling the axes brakes. The buttons are numbered according to the numbers of the axes. The buttons are located according to one of the figures -Illustration, IRB 6600/6650 on page 44, - Illustration, IRB 7600 base on page 45 or - Illustration, IRB 7600 frame on page 45. 2. Release the holding brake on a particular manipulator axis by pressing the corresponding button on the internal brake release panel. The brake will function again as soon as the button is released. The illustration below shows where to connect the external brake release unit in order to release the manipulator’s holding brakes. B A C D xx0100000104 46 A Connector R1.BU B Rear connector plate C Rear cover plate D External brake release unit A 3HAC 16245-1 4 On-site Installation 4.1.4 Manually releasing the brakes Illustration IRB 7600, external brake release unit connectors The illustration below shows the connectors on the manipulator and on the external brake release unit. A B C D E xx0200000081 A Rear connector plate B Connector R1.MP C Connector R1.BU D External brake release unit E Connect to R1.BU Required equipment External brake release unit (only IRB 7600) Equipment Art. no. External brake release unit 3HAC 12987-1 This section details how to release the holding brakes when the robot is equipped with an external brake release unit (only IRB 7600). When releasing the holding brakes, the manipulator axes may move very quickly and sometimes in unexpected ways! Make sure no personnel is near the manipulator arm! Step 1. 3HAC 16245-1 Action Info/Illustration Remove the rear cover plate on the base of Shown in Illustration, IRB 7600 exterthe manipulator by unscrewing its attachnal brake release unit connections on ment screws and plain washers page 46! A 47 4 On-site Installation 4.1.4 Manually releasing the brakes Step 48 Action Info/Illustration 2. Locate the free connector, connected to the Shown in Illustration IRB 7600, exterrear of connector R1.MP behind the rear nal brake release unit connectors on connector plate. page 47! Make sure it is designated R1.BU. 3. Connect the external brake release unit to connector R1.BU. 4. Release the holding brake of each manipulator axis by pressing the respective button on the external brake release unit. 5. Disconnect the external brake release unit. 6. Refit the rear cover plate with its attachment screws. A Art. no. specified in section Required equipment on page 47! Shown in Illustration IRB 7600, external brake release unit connectors on page 47! 3HAC 16245-1 4 On-site Installation 4.1.5 Lifting the base plate 4.1.5 Lifting the base plate General This section details how to lift the base plate Equipment Spare part no. Art. no. Note Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Lifting eye, M16 3HAC 14457-4 Use three lifting eyes. For lifting the base plate. Lifting slings Use three slings. Length: approx. 2 m Hole configuration A xx0200000096 A Attachment holes for lifting eyes (x3) The base plate weighs 335 kg! All lifting equipment used must be dimensioned accordingly! Lifting the base plate Step 3HAC 16245-1 Action Info/Illustration 1. Fit lifting eyes in the three lifting holes. Shown in the figure Hole configuration on page 49! 2. Fit lifting slings to the eyes and to the lifting device. A 49 4 On-site Installation 4.1.6 Securing the base plate 4.1.6 Securing the base plate General This section details how to secure the base plate. Base plate, dimensions 2x 503 2x 453 2x 247 2x 182 2x 90 2x 90 2x 451 2x 407 2x 321 2x 273 D B B 455 A A 540 480 A-A B- B D xx0100000105 50 A 3HAC 16245-1 4 On-site Installation 4.1.6 Securing the base plate Base plate, grooves and holes The illustration below shows the orienting grooves and guide sleeve holes in the base plate. B A B A B xx0300000045 A Guide sleeve holes B Orienting grooves in the base plate Required equipment Equipment Spare part no. Art. no. Base plate 3HAC 12937-7 Includes all required guide sleeves, screws and washers. A drawing of the base plate itself may be ordered from ABB Robotics! Guide sleeves, 2 pcs (between guide plate and manipulator) 3HAC 12937-3 Included in Base plate, 3HAC 12937-7. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. 3HAC 16245-1 Note These procedures include references to the tools required. A 51 4 On-site Installation 4.1.6 Securing the base plate Base plate This section details how to secure the base plate to the foundation. The table specifies any recommendations made by ABB: Variable Recommendation Recommended foundation quality 1 Steel fibre reinforced concrete foundation, 30 kg/m3, class K30, t=250 mm Recommended foundation quality 2 Sturdy concrete foundation, double reinforced by ø10 mm steel bars, distance 140 mm, class K25, t=250 Recommended bolt quality and dimen- Hilti HDA-P, M20 x 200 sion The base plate weighs 335 kg! All lifting equipment used must be dimensioned accordingly! Step 52 Action Info/illustration 1. Make sure the foundation is level. 2. Orient the base plate in relation to the robot work location using the three grooves in the base plate. 3. Lift the base plate to its mounting position. Detailed in Lifting the base plate on page 49. 4. Use the base plate as a template and drill If possible, observe the recommenda16 attachment holes as required by the tions specified in the table above. ABB selected bolt dimension. does not assume any responsibility for other foundation qualities, due to great variations in the foundation properties. 5. Fit the base plate and use the levelling bolts to level the base plate. 6. If required, fit strips of sheet metal underneath the base plate to fill any gaps. 7. Secure the base plate to the foundation with screws and sleeves. 8. Recheck the four manipulator contact sur- Max. allowed deviation: 0.5 mm faces on the base plate to make sure they are level and flat. If they are not, pieces of sheet metal or similar may be used to bring the base plate to a level position. A Shown in Base plate, grooves and holes on page 51. 3HAC 16245-1 4 On-site Installation 4.1.7 Orienting and securing the manipulator 4.1.7 Orienting and securing the manipulator General This section details how to orient and secure the manipulator to the base plate after fitting it to the foundation, in order to run the robot safely. The requirements made on the foundations are shown in the following tables and figures. The section below applies to IRB 7600 as well as IRB 6600/6650. The only difference between these robot models is that IRB 7600 is secured using 12 attachment bolts while IRB 6600/6650 uses 8 attachment bolts. Illustration, manipulator fitted to base plate The illustration below shows the IRB 7600 manipulator base fitted to the base plate. The IRB 6600/6650 manipulator base does not have the attachment holes A (4 pcs). A B C D B xx0100000107 Attachment screws 3HAC 16245-1 A Manipulator attachment bolts and washers, 4 pcs M24 x 120 (IRB 7600 only) B Manipulator attachment bolts and washers, 8 pcs M24 x 120 C Levelling screws D Base plate attachment screws The table below specifies the type of securing screws and washers to be used for securing the manipulator to the base plate/foundation. Suitable screws, lightly lubricated: M24 x 120 Quality Quality 8.8 Suitable washer: Thickness: 4 mm Outer diameter: 44 mm Inner diameter: 25 mm Tightening torque: 775 Nm A 53 4 On-site Installation 4.1.7 Orienting and securing the manipulator Securing the manipulator The procedure below details how to secure the manipulator to the base plate after fitting the plate to the foundation. Step Hole configuration, IRB 6600/ 6650 Action Info/Illustration 1. Lift the manipulator. Detailed in Lifting manipulator with fork lift on page 36or Lifting manipulator with lifting slings on page 42. 2. Move the manipulator to the vicinity of its installation location. 3. Fit two guide sleeves to the guide sleeve Shown in Base plate, grooves and holes holes in the base plate. on page 51. Note that one of the guide sleeve holes is elongated! 4. Guide the manipulator gently using two M24 screws while lowering it into its mounting position. Make sure the manipulator base is correctly fitted onto the guide sleeves! 5. Fit the bolts and washers in the base attachment holes. Specified in Attachment screws on page 53. Shown in the figure Illustration, manipulator fitted to base plate on page 53! Note! Lightly lubricate the 8 or 12 screws before assembly! 6. Tighten the bolts in a criss-cross pattern to ensure that the base is not distorted. The illustration below shows the hole configuration used when securing the manipulator, IRB 6600. R400 4 x ° 15 7,5° 4x3 xx0200000029 54 A 3HAC 16245-1 4 On-site Installation 4.1.7 Orienting and securing the manipulator Hole configuration, IRB 7600 The illustration below shows the hole configuration used when securing the manipulator, IRB 7600. 4x 10 4 4 5 .5 x1 x7 4x 37.5 xx0300000046 Cross section, guide sleeve hole The illustration below shows the cross section of the guide sleeve holes. xx0100000109 3HAC 16245-1 A 55 4 On-site Installation 4.1.8 Fitting equipment on manipulator 4.1.8 Fitting equipment on manipulator General The manipulator features mounting holes for additional equipment. Access to any of the following mounting holes may be obstructed by any additional cabling, equipment etc, fitted by the robot user. Make sure the required mounting holes are accessible when planning the robot cell. Under certain conditions, mounting holes may be added on the manipulator. Illustration, fitting extra equipment on lower arm The illustration below shows the mounting holes available for fitting extra equipment on the lower arm. Make sure not to damage the manipulator cabling on the inside of the lower arm when fitting extra equipment. Always use the appropriate attachment screws! 202 207,5* 282 154 M12 (4x) 80 125 25 110* 40* 5, 35* 75 150 53 354, 369* xx0200000195 * Illustration, fitting extra equipment on upper arm IRB 6650 The illustration below shows the mounting holes available for fitting extra equipment on the upper arm. M12 (4x) 190 xx0200000196 56 A 3HAC 16245-1 4 On-site Installation 4.1.8 Fitting equipment on manipulator Illustration, fitting extra equipment on frame The illustration below shows the mounting holes available for fitting extra equipment on the frame. 75 200 45 240 4x M16 790 1195 xx0200000198 3HAC 16245-1 A 57 4 On-site Installation 4.1.8 Fitting equipment on manipulator Illustration, fitting on mounting flange The illustrations below show the mounting holes available for fitting equipment on the mounting flange. There are two different versions of the mounting flange, as shown in illustrations below. A 30° (11x) 15 Ø12 H7 Depth 15 B B A A-A Ø100 H7Depth 8 min Ø 160 B -B xx0200000197 - 58 Mounting flange for robot version 225/2.55, 175/2.8, 125/3.2 and 200/2.75 A 3HAC 16245-1 4 On-site Installation 4.1.8 Fitting equipment on manipulator A 30° (12 x) 15 Ø12 H7 Depth 15 B B A Ø100H7 Depth 8min Ø160 xx0200000397 - Fastener quality 3HAC 16245-1 Mounting flange for robot version 175/2.55 When fitting tools on the mounting flange (see the figures above), use only screws with quality 12.9. When fitting other equipment, standard screws with quality 8.8 can be used. A 59 4 On-site Installation 4.1.9 Loads 4.1.9 Loads General Any loads mounted on the manipulator must be defined correctly and carefully (with regard to the position of center of gravity and inertia factor) in order to avoid jolting movements and overloading the motors. If this is not done correctly operational stops may result. References Load diagrams, permitted extra loads (equipment) and their positions are specified in the Product Specification. The loads must also be defined in the software as detailed in User’s Guide. Stop time and braking distances Manipulator motor brake performance depends on any loads attached. For further information about brake performance, please contact ABB Robotics. 60 A 3HAC 16245-1 4 On-site Installation 4.2.1 Introduction Section 4.2: Restricting the working range 4.2.1 Introduction General The working range of the manipulator may be limited to eliminate the risk of collisions. The following axes may be restricted: • Axis 1, hardware (mechanical stop) and software (signal from adjustable position switch) • Axis 2, hardware (mechanical stop) and software (signal from adjustable position switch) • Axis 3, hardware (mechanical stop) and software (signal from adjustable position switch) This section describes the utilization of the mechanical stops and the position switches. 3HAC 16245-1 A 61 4 On-site Installation 4.2.2 Mechanically restricting the working range of axis 1 4.2.2 Mechanically restricting the working range of axis 1 General The working range of axes 1 is limited by fixed mechanical stops and can be reduced by adding additional mechanical stops giving 7.5 or 15 graduation in both directions. Mechanical stops, axis 1 The illustration below shows the mounting position of the mechanical stops on axis 1. A B xx0300000049 A Additional mechanical stop B Fixed mechanical stop Required equipment Equipment, etc. 62 Spare part no. Art. no. Note 7.5°, mechanical stop for axis 1 3HAC 11076-1 Includes attachment screws. 15°, mechanical stop for axis 1 3HAC 11076-2 Includes attachment screws. Standard toolkit 3HAC 15571-1 The contents are defined in the section Standard toolkit on page 18. A 3HAC 16245-1 4 On-site Installation 4.2.2 Mechanically restricting the working range of axis 1 Installation, mechanical stops axis 1 The procedure below details how to mount the mechanical stops on axis 1. An assembly drawing is also enclosed with the product. The addititonal mechanical stop must be replaced after a hard collision if the mechanical stop has been deformed! Step 3HAC 16245-1 Action Note/Illustration 1. Mount the additional mechanical stop on the frame according to the figure Mechanical stops, axis 1 on page 62. Tightening torque: 115 Nm. 2. The software working range limitations must be amended to correspond to the changes in the mechanical limitations of the working range. A 63 4 On-site Installation 4.2.3 Mechanically restricting the working range of axis 2 4.2.3 Mechanically restricting the working range of axis 2 General The working range of axis 2 is limited by fixed mechanical stops and can be reduced by adding up to six additional mechanical stops with 15 graduation in respective direction. Mechanical stops, axis 2 The illustration below shows the mounting position of the mechanical stops on axis 2. A B xx0300000047 A Additional mechanical stops B Fixed mechanical stop Required equipment Equipment, etc. 64 Spare part no. Art. no. Note Mechanical stop set, axis 2 IRB 6600/6650 3HAC 13787-1 Includes six stops, 3HAC 137861, each one restricting the working range by 15°. Includes attachment screws. Mechanical stop set, axis 2 IRB 7600 3HAC 11077-1 Includes six stops, 3HAC 114071, each one restricting the working range by 15°. Includes attachment screws. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18. A 3HAC 16245-1 4 On-site Installation 4.2.3 Mechanically restricting the working range of axis 2 Installation, mechanical stops axis 2 The procedure below details how to mount the mechanical stops on axis 2. An assembly drawing is also enclosed with the product. The addititonal mechanical stop must be replaced after a hard collision if the mechanical stop has been deformed! Step 3HAC 16245-1 Action Note/Illustration 1. Mount and tighten the additional stops in a row, Tightening torque: 115 Nm. starting from the fixed stop. Shown in the figure Mechanical stops, axis 2 on page 64. 2. The software working range limitations must be amended to correspond to the changes in the mechanical limitations of the working range. A 65 4 On-site Installation 4.2.4 Mechanically restricting the working range of axis 3 4.2.4 Mechanically restricting the working range of axis 3 General The working range of axis 3 is limited by fixed mechanical stops and can be reduced by adding additional mechanical stops with 20 graduation in respective direction. Mechanical stops, axis 3 The illustration below shows the mounting position of the mechanical stops on axis 3. A B xx0300000048 A Additional mechanical stops B Fixed mechanical stop Required equipment Equipment, etc. 66 Spare part no. Art. no. Note Mechanical stop set, axis 3, IRB 6600/6650 3HAC 13128-1 Includes six stops, one with 80°restriction, 3HAC 12708-3 (use when limitation angle >=80), and five with 20°, 3HAC 12708-1. Includes attachment screws. Mechanical stop set, axis 3, IRB 7600 3HAC 13128-3 Includes six stops, one with 80°restriction, 3HAC 12708-4 (use when limitation angle >=80), and five with 20°, 3HAC 12708-2. Includes attachment screws. Standard toolkit 3HAC 15571-1 The contents are defined in the section Standard toolkit on page 18. A 3HAC 16245-1 4 On-site Installation 4.2.4 Mechanically restricting the working range of axis 3 Installation, mechanical stops axis 3 The procedure below details how to mount the mechanical stops on axis 3. An assembly drawing is also enclosed with the product. The addititonal mechanical stop must be replaced after a hard collision if the mechanical stop has been deformed! Step 3HAC 16245-1 Action Note/Illustration 1. Mount and tighten the additional stops in a row, starting from the fixed stop. Shown in the figure Mechanical stops, axis 3 on page 66 Tightening torque: 115 Nm. 2. The software working range limitations must be amended to correspond to the changes in the mechanical limitations of the working range. A 67 4 On-site Installation 4.2.5 Position switches 4.2.5 Position switches General Position switches can be installed on axes 1-3. The position switches include cams as shown in the figures below (all illustrations show IRB 7600 unless otherwise stated). The position switch kits may be delivered in one of two ways: Axis 1 • Fitted by ABB Robotics on delivery. In this case, the cams must still be fitted and locked by the user. For axis 1, the cover for the cams must also be fitted. • As kits to be completely fitted to the manipulator and adjusted by the user. Description Art. no. Position switch, axis 1 complete 3HAC 14118-1 Position switch, axis 2 complete 3HAC 15710-1 Position switch, axis 3 complete 3HAC 15709-1 The illustration below shows the position switch for axis 1: A F C D B E xx0100000158 68 A Position switch, axis 1 B Cam C Set screw, cam (cam stop) D Protection sheet E Rail F Rail attachment A 3HAC 16245-1 4 On-site Installation 4.2.5 Position switches Axis 2 The illustration below shows the position switch for axis 2: E B A C F xx0100000159 3HAC 16245-1 A Position switch, axis 2 B Cam C Set screw, cam (cam stop) E Rail F Rail Attachment A 69 4 On-site Installation 4.2.5 Position switches Axis 3 The illustration below shows the position switch for axis 3: F E C B A xx0100000160 Specifications Connections 70 A Position switch, axis 3 B Cam C Set screw, cam (cam stop) E Rail F Rail attachment Maximum voltage/current for the position switches: Parameter Value Voltage Max. 50 V DC Current Max. 1 A The position switches may be connected to different points on the robot system: • R1.SW1 at the manipulator base. Customer connection kit is recommended! Also see "Customer Connection Kit"! • R1.SW2/3 at the manipulator base. Customer connection kit is recommended! Also see "Customer Connection Kit"! • XT8, screw terminal in the controller cabinet A 3HAC 16245-1 4 On-site Installation 4.2.5 Position switches Fitting and adjusting cams and stops The instruction below details how to fit and adjust the parts of the position switches: Step Illustration, adjust and secure cams Action Info/Illustration 1. Cut the cam to a suitable length. Use a sharp knife and rubber hammer or similar. 2. Cut the edge of the cam edge to max 30°! Shown in Illustration, cutting the cam on page 72. If the angle is larger, this may damage the position switch! 3. Cut the part of the cam running in the profile to 90°! Also see Illustration, cutting the cam on page 72 below! 4. Make sure the ends of the profile are chamfered to enable the cam to run through the profile. 5. Fit the cam with the M5 screw and nut. Tighten Shown in Illustration, adjust and the M5 screw to secure the cam. secure cams on page 71. The illustration below show how to adjust and secure the position switch cams and profiles. C 30° A B xx0100000113 3HAC 16245-1 A Cam stop, M5 nut and M5 x 6 set screw B Adjustable cam C Profile A 71 4 On-site Installation 4.2.5 Position switches Illustration, cutting the cam The illustration below show how to cut the position switch cam. A o 30 o 90 xx0100000114 A 72 Remove the gray section A 3HAC 16245-1 4 On-site Installation 4.3.1 Lifting the controller cabinet Section 4.3: On-site installation, controller cabinet 4.3.1 Lifting the controller cabinet Lifting device Use the four lifting devices on the cabinet or a fork lift when lifting the controller cabinet S4Cplus M2000A as shown below. 60° xx0100000153 3HAC 16245-1 A Min. 60°when lifting with straps B Fork lift A 73 4 On-site Installation 4.3.2 Required installation space, control cabinet 4.3.2 Required installation space, control cabinet Dimensions The figure below shows the required installation space for the S4Cplus M2000A control cabinet: A A xx0100000156 A Dimensions Min. distance from wall The figure below shows the bolt pattern for the S4Cplus M2000A control cabinet: 720 400 xx0100000157 74 A 3HAC 16245-1 5 Electrical connections Chapter 5: Electrical connections 3HAC 16245-1 A 75 5 Electrical connections 5.1.1 Connecting the manipulator to the control cabinet Section 5.1: Signal/Power cables 5.1.1 Connecting the manipulator to the control cabinet General Connect the manipulator and control cabinet to each other after securing them to the foundation. The lists below specify which cables to be used in each application. Location of connectors XS Application interface XS20 I/O connections XS8 External axes in separate cabinet X13/X5 Operator’s panel XS78 Safety signals, external connections XS77/X7 DeviceNet LAN/XTDF Mains connection X24VE/VS External axes IBS Position switches XS41 Manipulator cables XS58 XS2 Ext. contr. panel Main cable categories All cables between manipulator and control cabinet are divided into the following categories: Cable category Description Manipulator cables Handles power supply to and control of the manipulator’s motors as well as feedback from the serial measurement board. Position switch cables (option) Handles supply to and feedback from any position switches and cooling fans on the manipulator. 76 Customer cables (option) Handles communication with equipment fitted on the manipulator by the customer, including databus communication, low voltage signals and high voltage power supply + protective earth. External axes cables (option) Handles power supply to and control of the external axes’ motors as well as feedback from the servo system. A 3HAC 16245-1 5 Electrical connections 5.1.1 Connecting the manipulator to the control cabinet These categories are divided into sub-categories which are specified below: Manipulator cables These cables are included in the standard delivery. They are completely premanufactured and ready to plug in. Cable subcategory Connection Connection point, point, cabinet manipulator Description Manipulator cable, power Transfers drive power from the drive XP1 units in the control cabinet to the manipulator motors. R1.MP Manipulator cable, signals Transfers resolver data from the serial measurement board and power supply to the SMB. R1.SMB XP2 Manipulator cable, power Cable Article number Manipulator cable, power, 7 m 3HAC 11818-1 Manipulator cable, power, 15 m 3HAC 11818-2 Manipulator cable, power, 30 m 3HAC 11818-4 Cable Article number Manipulator cable, signal, shielded, 7 m 3HAC 7998-1 Manipulator cable, signal, shielded, 15 m 3HAC 7998-2 Manipulator cable, signal, shielded, 30 m 3HAC 7998-4 Manipulator cable, signals Position switch cables 3HAC 16245-1 These cables are not included in the standard delivery, but can be included in the delivery if the Position switch option is ordered. (The position switches can also be ordered without cables.) The cables are completely pre-manufactured and ready to plug in. Cable Article number Connection Connection point, point, cabinet manipulator Position switch cable, axis 1, 7 m 3HAC 13175-1 XP8 R1.SW Position switch cable, axis 1, 15 m 3HAC 13175-2 XP8 R1.SW Position switch cable, axis 1, 30 m 3HAC 13175-4 XP8 R1.SW Position switch cable, axes 2 and 3, 7 m 3HAC 13176-1 XP58 R1.SW2/3 Position switch cable, axes 2 and 3, 15 m 3HAC 13176-2 XP58 R1.SW2/3 Position switch cable, axes 2 and 3, 30 m 3HAC 13176-4 XP58 R1.SW2/3 A 77 5 Electrical connections 5.1.1 Connecting the manipulator to the control cabinet Customer cables External axes cables These cables are not included in the standard delivery, but can be included in the delivery of each specific option. The cables are not ready to plug in, but requires connection to terminals inside the control cabinet as well as keying. These activities are detailed in Customer Connection Kit. Connection point, cabinet Connection point, manipulator 3HAC 13173-1 XT/XP5.1 XT/XP6 XS6 R1.CP/CS Fieldbus cable, CAN, 15 m 3HAC 13173-2 XT/XP5.1 XT/XP6 XS6 R1.CP/CS Fieldbus cable, CAN, 30 m 3HAC 13173-4 XT/XP5.1 XT/XP6 XS6 R1.CP/CS Fieldbus cable, Profibus, 7 m 3HAC 13174-1 XT/XP5.1 XT/XP6 DP/M R1.CP/CS Fieldbus cable, Profibus, 15 m 3HAC 13174-2 XT/XP5.1 XT/XP6 DP/M R1.CP/CS Fieldbus cable, Profibus, 30 m 3HAC 13174-4 XT/XP5.1 XT/XP6 DP/M R1.CP/CS Cable Article number Fieldbus cable, CAN, 7 m These cables are not included in the standard delivery, but can be included if the External axes option is ordered. The cables are ready to plug in. Cable sub-category Description 78 Connection Connection point, point, cabinet manipulator External axes cable, power Transfers drive power from the XP7 drive units in the control cabinet to the externa axes motors. XS45 External axes cable, signals Transfers resolver data from the serial measurement board and power supply to the SMB. XS47 A XP41 3HAC 16245-1 5 Electrical connections 5.1.2 Connection of manipulator cables to control cabinet, S4Cplus M2000A 5.1.2 Connection of manipulator cables to control cabinet, S4Cplus M2000A General Section "Connecting the manipulator to the control cabinet" specifies which cables to use and to which connectors these are to be connected in order to to connect the controller to the manipulator. Connections to the cabinet All control cabinet connectors are shown in the figure below. xx0100000247 The connections on the manipulator are located on the rear of the robot base. 3HAC 16245-1 A Manipulator cable (Power) B Manipulator cable (Signal) A 79 5 Electrical connections 5.1.3 Connection of mains power to control cabinet, S4Cplus M2000A 5.1.3 Connection of mains power to control cabinet, S4Cplus M2000A General Connect the power supply either inside the cabinet, or to a optional socket on the left-hand side of the cabinet or the lower section of the front. The cable connector is supplied but not the cable. Dimension the mains supply cables and fuses in accordance with the rated power and line voltage, see rating plate on the controller. Connections to the mains switch Also see the Circuit Diagram. The instruction below details how to make all required connections to the mains switch: xx0100000248 A Connector Q1 (L1, L2, L3) B Cable gland C Protective Earth connection PE Step Action 80 Info/Illustration 1. Remove the left cover plate under the top lid. 2. Pull the mains cable (outer diam. 10.2 mm) through the gland located on the left cabinet wall. 3. Release the connector from the knob by pushing the release buttons located on the side of the connector. A Shown in the figure above! 3HAC 16245-1 5 Electrical connections 5.1.3 Connection of mains power to control cabinet, S4Cplus M2000A Step Action 4. Connection through a power socket Info/Illustration Connect phase: • 1 to L1 (Not dependent on phase sequence) • 2 to L2 • 3 to L3 • 0 to XT26.N (line neutral is needed only for option 432) • and protective earth to theprotective earth connection. 5. Snap the breaker on to the knob again and check that it is fixed properly in the correct position. 6. Tighten the cable gland. 7. Fasten the cover plate. Shown in the figure above! NOTE! Max. conductor size is 6 mm2 (AWG 10). Tighten to a torque of 2.3-2.5 Nm. Retighten after approx. 1 week. It is also possible to connect the mains supply through an optional wall socket of type 3x32A or 4x32A or via an industrial Harting connector (DIN 41 640). See the figure below. Cable connectors are supplied (option 132 - 134). A xx0100000162 A 3HAC 16245-1 DIN connector A 81 5 Electrical connections 5.2.1 Signal Classes Section 5.2: Signal connections 5.2.1 Signal Classes Overview Signals 82 Different rules apply to the different classes when selecting and laying cable. Signals from different classes must not be mixed. • Power Signals: Supplies external motors and brakes. • Control signals: Digital operating and data signals (digital I/O, safety stops, etc.). • Measuring signals: Analog measuring and control signals (resolver and analog I/O). • Data communication signals: Gateway (Field bus) connection, computer link. A 3HAC 16245-1 5 Electrical connections 5.2.2 Selecting Cables 5.2.2 Selecting Cables Controller cables: All cables laid in the controller must be capable of withstanding 70o C. In addition. Power Signal: Shielded cable with an area of at least 0.75mm2 or AWG 18. Note that any local standards and regulations concerning insulation and area must always be complied with. Control signals: Shielded cables. Measuring signals: Shielded cable with twisted pair conductors. Data communication signals: Shielded cable with twisted pair conductors. A specific cable should be used for Gateway (Fiel bus) connections. CAN bus with DeviceNet for distributing I/O units: Thin cable according to DeviceNet specification release 1.2, must be used, e.g. ABB article no. 3HAB 8277-1. The cable is shielded and has four conductors, two for electronic supply and two for signal transmission. Note that a separate cable for supply of I/O loads is required. Allen-Bradley Remote I/O: Cables according to Allen-Bradley specification, e.g. "Blue hose", should be used for connections between DSQC 350 and the Allen-Bradley PLC bus. Interbus-S: Cables according to Phönix specification, e.g. "Green type", should be used for connections between the DSQC 351 and external Interbus-S bus. Profibus DP: Cables according to Profibus DP specification should be used for connections between the I/ O unit DSQC 352 and the external Profibus DP bus. Ethernet: Shielded twisted pair conductors (10 Base T STP). 3HAC 16245-1 A 83 5 Electrical connections 5.2.3 Interference elimination 5.2.3 Interference elimination External units External relay coils, solenoids, and other units that will be connected to the controller must be neutralized. The figure below illustrates how this can be done. The turn-off time for DC relays increases after neutralisation, especially if a diode is connected across the coil. Varistors give shorter turn-off times. Neutralising the coils lengthens the life of the switches that control them Clamping with a diode The diode should be be dimensioned for the same current as the relay coil, and a voltage of twice the supply voltage. +24V 0V xx0100000163 Clamping with a varistor The varistor should be be dimensioned for the same current as the relay coil, and a voltage of twice the supply voltage. +24V 0V xx0100000164 Clamping with an RC circuit R 100 ohm, 1W C 0.1 - 1 mF. >500V max. voltage, 125V nominal voltage. +24V DC, or AC voltage R C 0V xx0100000165 84 A 3HAC 16245-1 5 Electrical connections 5.2.4 Connection types 5.2.4 Connection types General I/O, external emergency stops, safety stops, etc. can be supplied on screw connections or as industrial connectors. Connections 3HAC 16245-1 Designation Connection type X(T) Screw terminal XP Pin (male) XS Sockets (female) A 85 5 Electrical connections 5.2.5 Connections to screw terminals 5.2.5 Connections to screw terminals Overview This section describes how to connect conductors to screw terminals. Detailed information about connection location and functions will be found in the circuit diagram (Service Manual). Installation The installation should comply with the IP54 (NEMA 12) protective standard. 1. Bend unused conductors backwards and attach them to the cable using a clasp, or similar. To prevent interference, ensure that unused conductors are not connected at the other end of the cable (antenna effect) In environments with much interference, disconnected conductors should be grounded (0V) at both ends. 86 A 3HAC 16245-1 5 Electrical connections 5.2.6 Connections to connectors (option) 5.2.6 Connections to connectors (option) Location of connectors The industrial connectors can be found on the front of the control cabinet. See the figure below and the figure in section "Control cabinet connections manipulator"! The manipulator arm is equipped with round Burndy/Framatome connectors (customer connector not included). xx0100000249 XS Application interface XS20 I/O connections XS8 External axes in separate cabinet X13/X5 Operator’s panel XS78 Safety signals, external connections XS77/X7 DeviceNet LAN/XTDF Mains connection X24VE/VS External axes IBS Position switches XS41 Manipulator cables XS58 XS2 Ext. contr. panel Connectors, description Each industrial connector has accomodations for four rows of 16 conductors with a maximum conductor area of 1.5 mm 2 . The pull-relief clamp must be used when connecting the shield to the case. Making the connection The section below details how to crimp cable connections to pins: 1. Using a special crimp tool, crimp a pin or socket on to each non-insulated conductor. When two conductors are be connected to the same pin or socket, both of them must be crimped into the same pin or socket. A maximum of two conductors may be crimped into the same pin or socket. 2. Snap the pin into the connector housing. 3. Push the pin into the connector until it locks. 4. When removing pins or sockets from industrial connectors, a special extractor tool must be used. 3HAC 16245-1 A 87 5 Electrical connections 5.3.1 Signal connections, SpotWelding Specification Section 5.3: Customer connections on manipulator 5.3.1 Signal connections, SpotWelding Specification General The section below specifies the signal connections on manipulator arm housing for material handling. Customer Power (CP) Servo motor power 3 600 VAC, 12A rms, min. 1, 5 mm 2 Utility power 4 600 VAC, 5A rms, min. 0,5 mm 2 Protective earth 1 min. 1,5 mm 2 Signals 20 50 VAC/DC, 1A rms, min. AWG 24 tw.pairs Sensitive signals 10 50 VAC/DC, 1A rms, min. AWG 24 tw.pairs + extra screening Bus signals 2 Profibus 12 Mbit/s spec* Bus signals 2 CAN/DeviceNet spec* Bus signals 4 Interbus spec* Bus utility signals 4 50 VAC/DC, 1A rms, min. AWG 24 tw.pairs Fibre Optics 2 1 mm Polymer fibre, wavelength 660 mm Hose 5 Inner diameter 12,5 mm, max. working pressure 16 bar Weld power 2 35 mm 2 , 600 VAC, Frequency 50-1000 Hz 150A rms at +20°(68 F) ambient temp. 120 A rms at +50°(122 F) ambient temp. Protective earth 1 35 mm 2 Customer Signal (CS) Customer BUS (CBUS) Air/Water (PROC) Welding power (WELD) Further information 88 See Circuit Diagram in the "Repairs Manual, part 2" for further information. A 3HAC 16245-1 5 Electrical connections 5.3.2 Signal connections, Material Handling Specification 5.3.2 Signal connections, Material Handling Specification General The section below specifies the signal connections on manipulator arm housing for material handling. Customer Power (CP) Servo motor power 3 600 VAC, 12A rms, min. 1, 5 mm 2 Utility power 4 600 VAC, 5A rms, min. 0,5 mm 2 Protective earth 1 min. 1,5 mm 2 Signals 20 50 VAC/DC, 1A rms, min. AWG 24 tw.pairs Sensitive signals 10 50 VAC/DC, 1A rms, min. AWG 24 tw.pairs + extra screening Bus signals 2 Profibus 12 Mbit/s spec* Bus signals 2 CAN/DeviceNet spec* Bus signals 4 Interbus spec* Bus utility signals 4 50 VAC/DC, 1A rms, min. AWG 24 tw.pairs Fibre Optics 2 1 mm Polymer fibre, wavelength 660 mm Customer Signal (CS) Customer BUS (CBUS) * Twisted pair under separate screen. Can also be used for very sensitive signals. Air/Water (PROC) Hose Further information 3HAC 16245-1 1 Inner diameter 12,5 mm, max. working pressure 16 bar See Circuit Diagram in the "Repairs Manual, part 2" for further information. A 89 5 Electrical connections 5.4.1 The MOTORS ON/MOTORS OFF circuit Section 5.4: Customer connections on controller 5.4.1 The MOTORS ON/MOTORS OFF circuit Outline diagram The MOTORS ON/MOTORS OFF circuit is made up of two identical chains of switches. The diagram shows the available customer connections, AS, GS and ES. A E C D B G F H J R S T M K L N P xx0100000174 Function of the MOTORS ON/ MOTORS OFF circuit 90 A ES (emergency stop) B LS (Limit switch) C Solid state switches D Contactor E Mains F Drive unit G Second chain interlock H GS (general mode safeguarded space stop) J AS (Automatic mode safeguarded space stop) K ED (TPU enabling device) L Manual mode M Motor N Automatic mode P Operating mode selector R RUN S EN1 T EN2 The circuit monitors all safety related equipment and switches. If any of the switches is opened, the MOTORS ON/MOTORS OFF circuit switches the power to the motors off. As long as the two chains are not identical, the robot will remain in MOTORS OFF mode. A 3HAC 16245-1 5 Electrical connections 5.4.1 The MOTORS ON/MOTORS OFF circuit Connection of safety chains The diagram below shows the two-channel safety chain. Supply from internal 24V (X3/X4:12) and 0 V (X3/X4:7) is displayed. When external supply of GS and AS, X3/X4:10,11 is connected to 24V and X3/X4:8,9 is connected to external 0V. Connection tables for X1-X4 are given in "External customer connections on panel X1 - X4". 24V X3:12 X4:12 Ext LIM1 24V K1 0V X1:11 12 X3:10 ES1 8 Opto GS1 isol. TPU En1 & 11 Opto AS1 isol. 9 Auto1 K1 EN Run Intern locking K2 Man1 External contactors 0V 24 V X3:3 X4:3 0V Ext LIM2 X2:11 12 4 4 CONT1 CONT2 K2 X4:10 ES2 8 Opto GS2 isol. TPU En2 Drive Unit & 11 9 24 V M Opto AS2 isol. Auto2 Man2 xx0100000166 Technical data per chain Connection of ES1/ES2 on panel unit 3HAC 16245-1 Limit switch Load: 300 mV. Max. voltage drop: 1 V External connectors Load: 10 mA. Max. voltage drop: 4 V GS/AS load at 24 V 25 mA GS/AS closed "1" >18 V GS/AS open "0" <5V External supply of GS/AS Max. + 35 VDC Min. - 35 VDC Max. potential in relation to the cabinet earthing and other signal groups 300 V Signal class Control signals The diagram below shows the terminals for the emergency circuits. Supply from internal 24V (X1/X2:10) and 0V (X1/X2:10) is displayed. When ext. supply, X1/X2:3 is connected to ext. 24V and X1/X2:8 is connected to ext. 0V (dotted lines). A 91 5 Electrical connections 5.4.1 The MOTORS ON/MOTORS OFF circuit A 24V 0V B C D X1:3 1:4 X1:7 X1:10 X1:9 X1:8 X1:1 X1:2 24V X1:6 E 24V G 24V 0V F B D C 2:4 X2:7 X2:8 X2:1 X2:2 24V X2:6 H 24V X2:4 X2:5 J xx0100000191 A Internal F Run chain 1 top B Ext shop G Internal C TPU H ES2 internal D Cabinet J Run chain 2 top E ES1 internal Technical data 92 ES1 and ES2 max output voltage 120 VAC or 48 VDC ES1 and ES2 max output current 120 VAC: 4 A 48 VDC L/R: 50 mA 24 VDC L/R: 2 A 24 VDC R load: 8 A External supply of ES relay Min. 22 V between terminals X1:9, 8 and X2:9 ,8 respectively Rated current per chain 40 mA Max. potential in relation to the cabinet earthing and other signal groups 300 V Signal class Control signals A 3HAC 16245-1 5 Electrical connections 5.4.1 The MOTORS ON/MOTORS OFF circuit Connection to MOTORS ON/ MOTORS OFF contactor The diagram below shows the connection of terminals for customer use. A B X3:2 1 X4:2 1 xx0100000193 A K1 (Motor on/off 1) B K1 (Motor on/off 2) Technical data Max. voltage 48 VDC Max. current 4A Max. potential in relation to the cabinet earthing and other signal groups 300 V Signal class Connection to operating mode selector Control signals The diagram below shows the connection of terminals for customer use. S1.1.x1 8 A 7 6 5 B S1.1.x1 4 D C 3 2 1 E F xx0100000197 A Auto 1 B MAN1 C 100 % (Option) D Auto 2 E MAN2 F 100% (Option) Technical data 3HAC 16245-1 Max. voltage 48 VDC Max. current 4A A 93 5 Electrical connections 5.4.1 The MOTORS ON/MOTORS OFF circuit Technical data Connection to brake contactor Max. potential in relation to the cabinet earthing and other signal groups 300 V Signal class Control signals The diagram below shows the connection of terminals for customer use. A X4:5 6 xx0100000199 A K3 (Brake) Technical data 94 Max. voltage 48 VDC Max. current 4A Max. potential in relation to the cabinet earthing and other signal groups 300 V Signal class Control signals A 3HAC 16245-1 5 Electrical connections 5.4.2 External customer connections on panel X1 - X4 5.4.2 External customer connections on panel X1 - X4 Outline diagram The diagram shows the customer connections X1 - X4 located on the panel unit WARNING REMOVE JUMPERS BEFORE CONNECTING ANY EXTERNAL EQUIPMENT xx0100000205 grey field Jumper Connection of X1: 12-pole type Phoenix COMBICON connector Connection of X2: 12-pole type Phoenix COMBICON connector 3HAC 16245-1 The table below shows the signal descriptions for X1 The signal names refer to the Circuit Diagram. Signal Terminal Comment number ES1 out: A 1 Emergency stop out chain 1 ES1 out: B 2 Emergency stop out chain 1 ES1 top 3 Top of emergency stop chain 1 24 V panel 4 + 24 V emergency stop chain 1 and run chain 1 Run ch1 top 5 Top of run chain 1 ES1 internal 6 Internal signal from emergency stop relay chain 1 Sep. ES1: A 7 Separated emergency stop chain 1 Sep. ES1: B 8 Separated emergency stop chain 1 ES1 bottom 9 Bottom of emergency stop chain 1 0V 10 0 V emergency stop chain 1 Ext. LIM1: A 11 External limit switch chain 1 Ext. LIM1: B 12 External limit switch chain 1 The table below shows the signal descriptions for X2 The signal names refer to the Circuit Diagram. Signal Terminal Comment number ES2 out: A 1 Emergency stop out chain 2 A 95 5 Electrical connections 5.4.2 External customer connections on panel X1 - X4 Connection of X3: 12-pole type Phoenix COMBICON connector Connection of X4: 12-pole type Phoenix COMBICON connector 96 Signal Terminal Comment number ES2 out: B 2 Emergency stop out chain 2 ES2 top 3 Top of emergency stop chain 2 0V 4 0 V emergency stop chain 2 Run ch2 top 5 Top of run chain 2 ES2 internal 6 Internal signal from emergency stop relay chain 2 Sep. ES2: A 7 Separated emergency stop chain 2 Sep. ES2: B 8 Separated emergency stop chain 2 ES2 bottom 9 Bottom of emergency stop chain 2 24 V panel 10 + 24 V emergency stop chain 1 and run chain 2 Ext. LIM2: A 11 External limit switch chain 2 Ext. LIM2: B 12 External limit switch chain 2 The table below shows the signal descriptions for X2 The signal names refer to the Circuit Diagram. Signal Terminal Comment number Ext. MON 1: A 1 Motor contactor 1 Ext. MON 1: B 2 Motor contactor 1 0V 3 External contactor 1 0 V CONT1 4 External contactor 1 5 No connection 6 No connection 0V 7 0 V to auto stop (AS) and general stop (GS) GS1- 8 General stop minus chain 1 AS1- 9 Auto stop minus chain 1 GS1+ 10 General stop plus chain 1 AS1+ 11 Auto stop plus chain 1 24 V panel 12 24 V to auto stop and general stop The table below shows the signal descriptions for X2 The signal names refer to the Circuit Diagram. Signal Terminal Comment number Ext. MON 2: A 1 Motor contactor 2 Ext. MON 2: B 2 Motor contactor 2 24 V panel 3 External contactor 2 24 V CONT2 4 External contactor 2 Ext. BRAKE A 5 Contactor for external brake Ext. BRAKE B 6 Contactor for external brake A 3HAC 16245-1 5 Electrical connections 5.4.2 External customer connections on panel X1 - X4 3HAC 16245-1 Signal Terminal Comment number 0V 7 0 V to auto stop (AS) and general stop (GS) GS2- 8 General stop minus chain 2 AS2- 9 Auto stop minus chain 2 GS2+ 10 General stop plus chain 2 AS2+ 11 Auto stop plus chain 2 24 V panel 12 24 V to auto stop and general stop A 97 5 Electrical connections 5.4.3 Connection of external safety relay 5.4.3 Connection of external safety relay Description The motor contactors K1 and K2 in the controller can operate with external equipment if external relays are used. The figure below shows two examples of how to connect the external safety relays: Connection examples A B X4:4 CONT 2 24 V X4:3 E xt MON 2 X4:2 0V K2 X4:1 X3:2 K1 E xt MON 1 X3:1 24 V 0 V X3:3 CONT 1 X3:4 C D E AS AS GS F GS F G E K H J xx0100000246 98 A Panel unit B Relays with positive action C Robot 1 D Robot 2 E External supply F ES (emergency stop) out G Safety relay A 3HAC 16245-1 5 Electrical connections 5.4.3 Connection of external safety relay 3HAC 16245-1 H To other equipment J Safety gate K Cell ES (emergency stop) A 99 5 Electrical connections 5.5.1 External 24V supply Section 5.5: Supplies 5.5.1 External 24V supply When is an external supply recommended? How to connect the external supply An external supply is recommended to make use of the advantages offered by the galvanic insulation on the I/O units or on the panel unit. An external supply must be used in the following cases: • When the internal supply is insufficient • When the emergency stop circuits must be independent of whether or not the robot has power on, for example. • When there is a risk that major interference can be carried over into the internal 24V supply. The external supply neutral wire must be connected to the chassis such that the maximum permitted potential difference in the chassis earth is not exceeded. For example, a neutral wire can be connected to the chassis earth of the controller, or some other common earthing point. Technical data 100 Potential difference to chassis earth Max. 60 V continuously Max. 500 V during 1 minute Permitted supply voltage I/O units 19 VDC - 35 VDC incl. ripple Panel unit 20.6 VDC - 30 VDC incl. ripple A 3HAC 16245-1 5 Electrical connections 5.5.2 24V I/O supply 5.5.2 24V I/O supply General The 24V I/O is not galvanically separated from the rest of the controller voltages. 24 VDC supply for internal and external use Voltage 24.0 - 26.4V Ripple Max. 0.2V Permitted customer load Max. 7A Current limit 13,5 ~0A. 24 VDC supply available at XT 31 3HAC 16245-1 24V I/O available for customer connections at XT 31 is shown in the figure in "Connections to screw terminals". XT.31.2 24 V (through a 2 A fuse) XT.31.1 for own fuses XT.31.4 0 V (connected to cabinet structure) A 101 5 Electrical connections 5.5.3 115/230 VAC supply 5.5.3 115/230 VAC supply General 115/230 VAC supply for internal and external use 115/230 VAC supply available at XT 21 102 This voltage is used in the robot for supplying optional service outlets. The AC supply is not galvanically separated from the rest of the controller voltages. Voltage 115 VAC or 230 VAC Permitted customer load Max. 500 VA Fuse size, 115 V 6.3 A Fuse size, 230 V 3.15 A 115 VAC/230 VAC available for customer connections at XT 21 is shown in the figure in "Connection to screw terminals". FU2 - 201 230 VAC FU1 - 202 115 VAC N - 203 N (connected to cabinet structure) A 3HAC 16245-1 5 Electrical connections 5.6.1 Connection of the CAN bus Section 5.6: Buses 5.6.1 Connection of the CAN bus Illustration The illustration below shows an example of how to connect the CAN bus: C A D D D X15 CAN1.1 (Internal I/O) B X6 CAN1.2 X7 CAN1.3 G D D D D D D E X15, X6, X7 1. 2. 3. 4. 5. 1. 0V_CAN 2. CAN_L 3. drain 4. CAN_H 5. 24V_I/O F xx0100000241 A Base connector unit E Termination of last unit B CAN bus F 120 ohm, 1%, 0.25 W metal film resistor C Control cabinet G See figure in section "CAN 2" below! D I/O CAN 1.1 Used for internal I/O unit mounted inside the cabinet. No terminating resistor is to be mounted on CAN 1.1 regardless of whether any I/O units are used or not. CAN 1.1 is connected to socket X15 on the Base connector unit (see Connection of the CAN bus). CAN 1.2 If CAN 1.2 is not used, a terminating resistor must be connected to the X6 socket (exceptional case see below!). 3HAC 16245-1 A 103 5 Electrical connections 5.6.1 Connection of the CAN bus If CAN 1.2 is used, the terminating resistor should be moved to the last I/O unit on the CAN 1.2 chain. If CAN 1.2, for example, is not connected in the end of any CAN chain but somewhere between the end points of the chain, then no terminating resistor should be mounted in CAN 1.3. This is in accordance with the basic rule, i.e. the CAN chain should be terminated in both end points. CAN 1.3 If CAN 1.3 is unused, a terminating resistor must be connected to the X7 socket. If CAN 1.3 is used, the terminating resistor should be moved to the last I/O unit on the CAN 1.3 chain. If CAN 1.2, for example, is not connected in the end of any CAN chain but somewhere between the end points of the chain, then no terminating resistor should be mounted in CAN 1.3. This is in accordance with the basic rule, i.e. the CAN chain should be terminated in both end points. Termination resistors in CAN bus The CAN chain must be terminated with terminating resistors in each end! CAN 2 The illustration below shows an example of how to connect the CAN 2 bus: If CAN 1.2, for example, is not connected in the end of any CAN chain but somewhere between the end points of the chain, then no terminating resistor should be mounted in CAN 1.3. A C B D X8 CAN 2 D D E X8 1. 0V_CAN 2. CAN_L 3. drain 4. CAN_H 5. 24V_I/O 1. 0V_CAN 2. CAN_L 3. drain 4. CAN_H 5. 24V_I/O 1. 2. 3. 4. 5. F xx0100000242 104 A Controller B Base connector unit C See figure in section "Illustration" above! D I/O E Termination of last unit F 120 ohm, 1%, 0.25 W metal film resistor A 3HAC 16245-1 5 Electrical connections 5.6.1 Connection of the CAN bus The illustration below shows CAN connections on base connector unit: A B C D xx0100000243 3HAC 16245-1 A X6 CAN 1.2 (external I/O) B X7 CAN 1.3 (external I/O) C X8 CAN 2 (external I/O) D X15 CAN 1.1 (internal I/O) A 105 5 Electrical connections 5.6.2 Interbus-S, slave DSQC 351 5.6.2 Interbus-S, slave DSQC 351 General The unit can be operated as a slave for a Interbus-S system. Supply The Interbus-S slave must be fed externally to avoid shutting down the Interbus-S net if a robot cell is switched off. The 24V power supply must be fed from outside the control cabinet and be connected to pin 2 Phoenix connector located on the Interbus-S card’s front panel marked 24V. Technical data Also see the Interbus-S specification. Further information For setup parameters, see User’s Guide - System Parameters, Topic: Controller. Also see the Circuit Diagram. Unit ID Unit ID to be entered in the Interbus-S master is 3. The length code depends on the selected data. Width between 1 and 4. Layout, DSQC 351 The figure below show the layout of the DSQC 351 board: X20 X21 X5 X3 xx0100000225 106 X3 Power connector X5 DeviceNet connector X20 Interbus-S, input X21 Interbus-S, output A 3HAC 16245-1 5 Electrical connections 5.6.2 Interbus-S, slave DSQC 351 Communication concept The Interbus-S system is able to communicate with a number of external devices, depending on the number of process words occupied by each unit. The robot may be equipped with one or two DSQC 351. The Interbus-S inputs and outputs are accessible in the robot as general inputs and outputs. For application data, refer to Interbus-S, International Standard, DIN 19258. Below is shown an outline diagram of the communication concept: E A F B In C Out In *1 D Out In Out *1 xx0100000224 A Master PLC B Robot 1, word 1:3 C Robot 1, word 4:7 D Robot 2, word 8:11 E 128 inputs/128 outputs F 64 inputs/64 outputs *1 Termination link A link is connected between pins 5 and 9 in the plug on the interconnection cable connected to the OUT connector of each unit. The link informs the Interbus-S unit that more units are connected further out in the chain. (The last unit in the chain does not have a cable connected and therefore no link). Connections, X5 DeviceNet connectors See DeviceNet Connectors. Connections, connector X20, Interbus-S IN The figure below shows the pin configuration of the connector: 5 1 6 9 xx0100000220 The table below show the connections to connector X20, Interbus-S IN: 3HAC 16245-1 Signal name X20 pin Function TPDO1 1 Communication line TPDO1 TPDI1 2 Communication line TPDI1 GND 3 Ground connection NC 4 Not connected A 107 5 Electrical connections 5.6.2 Interbus-S, slave DSQC 351 Connections, connector X21, Interbus-S OUT Signal name X20 pin Function NC 5 Not connected TPDO1-N 6 Communication line TPDO1-N TPDI1-N 7 Communication line TPDI1-N NC 8 Not connected NC 9 Not connected The figure below shows the pin configuration of the connector: 5 1 6 9 xx0100000220 The table below show the connections to connector X21, Interbus-S OUT: Connections, connector X3 Signal name X21 pin Function TPDO2 1 Communication line TPDO2 TPDI2 2 Communication line TPDI2 GND 3 Ground connection NC 4 Not connected +5V 5 + 5 VDC TPDO2-N 6 Communication line TPDO2-N TPDI2-N 7 Communication line TPDI2-N NC 8 Not connected RBST 9 Synchronization The figure below shows the pin configuration of the connector: 5 1 xx0100000221 The table below show the connections to connector X3: Bus status LEDs Signal name X3 pin Function 0 VDC 1 External supply of Interbus-S NC 2 Not connected GND 3 Ground connection NC 4 Not connected + 24 VDC 5 + 24 VDC The designations refer to LEDs shown in the figure in section "Layout, DSQC 352" above. The figure and table below show the location and significance of the the LEDs on the board. 108 A 3HAC 16245-1 5 Electrical connections 5.6.2 Interbus-S, slave DSQC 351 3HAC 16245-1 Designation Color Description POWER-24 VDC Green Indicates that a supply voltage is present, and has a level above 12 VDC. NS/MS Green/red See section "CAN bus status LED description". CAN Tx/CAN Rx Green/red See section "CAN bus status LED description". POWER- 5 VDC Green Lit when both 5 VDC supplies are within limits, and no reset is active. RBDA Red Lit when this Interbus-S station is last in the Interbus-S network. If it is not (which is required), check parameter setup. BA Green Lit when Interbus-S is active. If there is no light, check network, nodes and connections. RC Green Lit when Interbus-S communication runs without errors. A 109 5 Electrical connections 5.6.3 Profibus-DP, slave DSQC 352 5.6.3 Profibus-DP, slave DSQC 352 General The unit can be operated as a slave for a Profibus-DP system. Supply The Profibus does not need any external power feed. All the robot cells are connected to the trunk cable through a special D-sub connector which works as a very short drop cable. Because of this the profibus will work correctly even if a robot cell is turned off. Technical data Also see the Profibus-DP specification, Internation Standard DIN E 19245 part 3. Further information For setup parameters, see User’s Guide - System Parameters, Topic: I/O Signals. Also see the Circuit diagram. Layout, DSQC 352 The figure below show the layout of the DSQC 352 board: X20 X5 X3 xx0100000223 Communication concept X3 Power connector X5 DeviceNet connector X20 Profibus connection The Profibus-DP system is able to communicate with a number of external devices, depending on the number of process words occupied by each unit. The robot may be equipped with one or two DSQC 352. The Profibus-DP inputs and outputs are accessible in the robot as general inputs and outputs. Below is shown an outline diagram of the communication concept: E A B F C D xx0100000222 110 A 3HAC 16245-1 5 Electrical connections 5.6.3 Profibus-DP, slave DSQC 352 A Master PLC B Robot 1, word 1:8 C Robot 1, word 9:16 D Robot 2, word 17:24 E 256 inputs/256 outputs F 128 inputs/128 outputs Termination The Profibus cable must be terminated in both ends. Connections, X5 DeviceNet connectors See "Device Net Connectors". Connections, connector X20, Profibus-DP The figure below shows the pin configuration of the connector: 5 1 6 9 xx0100000220 The table below show the connections to connector X20, Interbus-S IN: Connections, connector X3 Signal name X20 pin Function Shield 1 Cable screen NC 2 Not connected RxD/TxD-P 3 Receive/Transmit data P Control-P 4 GND 5 +5 VDC 6 NC 7 Not connected RxD/TxD-N 8 Receive/Transmit data N NC 9 Not connected Ground The figure below shows the pin configuration of the connector: 5 1 xx0100000221 The table below show the connections to connector X3: 3HAC 16245-1 Signal name X3 pin Function 0 VDC 1 External supply of Profibus-DP A 111 5 Electrical connections 5.6.3 Profibus-DP, slave DSQC 352 Bus status LEDs Signal name X3 pin Function NC 2 Not connected GND 3 Ground connection NC 4 Not connected + 24 VDC 5 External supply of Profibus-DP The figure and table below show the location and significance of the the LEDs on the board. The designations refer to LEDs shown in the figure in section "Layout, DSQC 352" above. Designation Color Description Profibus active Green Lit when the node is communicating with the master. If there is no light, check system messages in robot and in Profibus net. NS/MS Green/red See section "CAN bus status LED description". CAN Tx/CAN Rx Green/red See section "CAN bus status LED description". POWER, 24 VDC Green 112 Indicates that a supply voltage is present, and has a level above 12 VDC. If there is no light, check that voltage is present in power unit and in the power connector. If not, check cables and connectors. If power is applied to the unit but it does not work, replace the unit. A 3HAC 16245-1 5 Electrical connections 5.7.1 Distributed I/O units Section 5.7: I/O units 5.7.1 Distributed I/O units General Up to 20 units can be connected to the same controller but only four of these can be installed inside the controller. Normally a distributed I/O unit is placed outside the controller. Connection The maximum total length of the distributed I/O cable is 100 m (from one end of the chain to the other end). The controller can be one of the end points or be placed somewhere in the middle of the chain. Parameter setup 3HAC 16245-1 For setup parameters, see User’s Guide, section System Parameters, Topic: I/O Signals. A 113 5 Electrical connections 5.7.2 Distributed I/O, digital sensors 5.7.2 Distributed I/O, digital sensors General Digital sensors are connected to one optional digital unit. Technical data See Product Specification for Controller S4Cplus. Allowed types of digital sensors The table below shows the allowed types of digtal sensors to be used, and their signal levels respectively: 114 Sensor type Signal level Digital one bit sensor High, "1" Low, "0" Digital two bit sensor High, "01" No signal, "00" Low, "10" Error status, "11" (stop program running) A 3HAC 16245-1 5 Electrical connections 5.7.3 Distributed I/O, digital I/O DSQC 328 (option) 5.7.3 Distributed I/O, digital I/O DSQC 328 (option) General The digital I/O unit handles digital communication between the robot system and any external systems. Technical data No. of inputs 16 (divided into two groups of 8, galvanically isolated from each other) No. of outputs 16 (divided into two groups of 8, galvanically isolated from each other) Supply voltage 24 VDC Supply source 24 V I/O or separate external supply Also see Product Specification for controller S4Cplus. Further information For setup parameters, see Users Guide - System Parameters, Topic: Controller. Also see the Circuit Diagram. Layout, DSQC 328 The figure below shows the layout of the DSQC328 board: A 1 2 3 4 5 6 7 8 OUT MS IN NS X1 X3 9 10 11 12 13 14 15 16 OUT IN X2 1 1 10 1 10 X4 1 10 10 1 12 X5 xx0100000240 A Connections, connector X1 Status LEDs If supervision of the supply voltage is required, a bridge connection can be made to an optional digital input. The supervision instruction must be written in the RAPID program. This is described in the User’s Guide. The table below show the connections to connector X1: 3HAC 16245-1 Unit function Signal name X1 pin Optically isolated output Out ch 1 1 Optically isolated output Out ch 2 2 Optically isolated output Out ch 3 3 Optically isolated output Out ch 4 4 A 115 5 Electrical connections 5.7.3 Distributed I/O, digital I/O DSQC 328 (option) Connections, connector X2 Unit function Signal name X1 pin Optically isolated output Out ch 5 5 Optically isolated output Out ch 6 6 Optically isolated output Out ch 7 7 Optically isolated output Out ch 8 8 Optically isolated output 0 V for outputs 1-8 9 Optically isolated output 24 V for outputs 1-8 10 If supervision of the supply voltage is required, a bridge connection can be made to an optional digital input. The supervision instruction must be written in the RAPID program. This is described in the User’s Guide. The table below show the connections to connector X2: Connections, connector X3 Unit function Signal name X2 pin Optically isolated output Out ch 9 1 Optically isolated output Out ch 10 2 Optically isolated output Out ch 11 3 Optically isolated output Out ch 12 4 Optically isolated output Out ch 13 5 Optically isolated output Out ch 14 6 Optically isolated output Out ch 15 7 Optically isolated output Out ch 16 8 Optically isolated output 0 V for outputs 9-16 9 Optically isolated output 24 V for outputs 9-16 10 The table below show the connections to connector X3: Unit function Signal name X3 pin Optically isolated input In ch 1 1 Optically isolated input In ch 2 2 Optically isolated input In ch 3 3 Optically isolated input In ch 4 4 Optically isolated input In ch 5 5 Optically isolated input In ch 6 6 Optically isolated input In ch 7 7 Optically isolated input In ch 8 8 Optically isolated input 0 V for inputs 1-8 9 Optically isolated input Not used 10 The input current is 5.5 mA (at 24V) on the digital inputs. A capacitor connected to ground, to prevent disturbances, causes a short rush of current when setting the input. When connecting outputs, sensitive to pre-oscillation current, a series resistor (100 W) may be used. 116 A 3HAC 16245-1 5 Electrical connections 5.7.3 Distributed I/O, digital I/O DSQC 328 (option) Connections, connector X4 The table below show the connections to connector X4: Unit function Signal name X4 pin Optically isolated input In ch 9 1 Optically isolated input In ch 10 2 Optically isolated input In ch 11 3 Optically isolated input In ch 12 4 Optically isolated input In ch 13 5 Optically isolated input In ch 14 6 Optically isolated input In ch 15 7 Optically isolated input In ch 16 8 Optically isolated input 0 V for inputs 9-16 9 Optically isolated input Not used 10 The input current is 5.5 mA (at 24V) on the digital inputs. A capacitor connected to ground, to prevent disturbances, causes a short rush of current when setting the input. When connecting outputs, sensitive to pre-oscillation current, a series resistor (100 W) may be used. 3HAC 16245-1 A 117 5 Electrical connections 5.7.4 AD Combi I/O, DSQC 327 (optional) 5.7.4 AD Combi I/O, DSQC 327 (optional) General The digital I/O unit handles digital and analog communication between the robot system and any external systems. Technical data No. of digital inputs 16 (divided into two groups of 8, galvanically isolated from each other) No. of digital outputs 16 (divided into two groups of 8, galvanically isolated from each other) No. of analog outputs 2 (galvanically isolated from the controller electronics) Supply voltage 24 VDC Supply source, digital I/O 24 V I/O or separate external supply Supply source, analog I/O 24 V_CAN (with galvanically isolated DC/AC converter) Also see Product Specification for controller S4Cplus. Further information For setup parameters, see Userss Guide - System Parameters, Topic: Controller. Also see the Circuit Diagram. Layout, DSQC 327 The figure below show the layout of the DSQC327 board: A 1 2 3 4 5 6 7 8 OUT MS IN NS X1 X3 OUT 9 10 11 12 13 14 15 IN X2 1 10 1 X4 10 1 X6 1 10 16 1 6 10 1 12 X5 xx0100000239 A Status LEDs Connector X5 is a CAN connector further described in section "Connection and address keying of the CAN bus". Connections, connector X1 If supervision of the supply voltage is required, a bridge connection can be made to an optional digital input. The supervision instruction must be written in the RAPID program. This is described in the User’s Guide. The table below show the connections to connector X1: 118 A 3HAC 16245-1 5 Electrical connections 5.7.4 AD Combi I/O, DSQC 327 (optional) Connections, connector X2 Unit function Signal name X1 pin Optically isolated output Out ch 1 1 Optically isolated output Out ch 2 2 Optically isolated output Out ch 3 3 Optically isolated output Out ch 4 4 Optically isolated output Out ch 5 5 Optically isolated output Out ch 6 6 Optically isolated output Out ch 7 7 Optically isolated output Out ch 8 8 Optically isolated output 0 V for outputs 1-8 9 Optically isolated output 24 V for outputs 1-8 10 If supervision of the supply voltage is required, a bridge connection can be made to an optional digital input. The supervision instruction must be written in the RAPID program. This is described in the User’s Guide. The table below show the connections to connector X2: Connections, connector X3 3HAC 16245-1 Unit function Signal name X2 pin Optically isolated output Out ch 9 1 Optically isolated output Out ch 10 2 Optically isolated output Out ch 11 3 Optically isolated output Out ch 12 4 Optically isolated output Out ch 13 5 Optically isolated output Out ch 14 6 Optically isolated output Out ch 15 7 Optically isolated output Out ch 16 8 Optically isolated output 0 V for outputs 9-16 9 Optically isolated output 24 V for outputs 9-16 10 The table below show the connections to connector X3: Unit function Signal name X3 pin Optically isolated input In ch 1 1 Optically isolated input In ch 2 2 Optically isolated input In ch 3 3 Optically isolated input In ch 4 4 Optically isolated input In ch 5 5 Optically isolated input In ch 6 6 Optically isolated input In ch 7 7 Optically isolated input In ch 8 8 Optically isolated input 0 V for inputs 1-8 9 Optically isolated input Not used 10 A 119 5 Electrical connections 5.7.4 AD Combi I/O, DSQC 327 (optional) Connections, connector X4 Connections, connectors X6 The table below show the connections to connector X4: Unit function Signal name X4 pin Optically isolated input In ch 9 1 Optically isolated input In ch 10 2 Optically isolated input In ch 11 3 Optically isolated input In ch 12 4 Optically isolated input In ch 13 5 Optically isolated input In ch 14 6 Optically isolated input In ch 15 7 Optically isolated input In ch 16 8 Optically isolated input 0 V for inputs 9-16 9 Optically isolated input Not used 10 The table below show the connections to connectors X6: Signal name X6 pin Explanation AN_ICH1 1 For test purposes only AN_ICH2 2 For test purposes only 0V 3 0 V for In channels 1-2 0 VA 4 0 V for Out channels 1-2 AN_OCH1 5 Out channels 1 AN_OCH2 6 Out channels 2 The input current is 5.5 mA (at 24V) on the digital inputs. A capacitor connected to ground, to prevent disturbances, causes a short rush of current when setting the input. When connecting outputs, sensitive to pre-oscillation current, a series resistor (100 W) may be used. 120 A 3HAC 16245-1 5 Electrical connections 5.7.5 Analog I/O, DSQC 355 (optional) 5.7.5 Analog I/O, DSQC 355 (optional) General The analog I/O unit handles communication between the robot system and any external systems through analog sensors. Technical data No. of analog inputs 4 (-10 V/+10 V) No. of analog outputs 3 (-10 V/+10 V) 1 (4-20 mA)) No. of analog outputs 2 (galvanically isolated from the controller electronics) Supply voltage 24 VDC Also see Product Specification for controller S4Cplus. Further information For setup parameters, see User’s Guide - System Parameters, Topic: Controller. Also see the Circuit Diagram. Layout, DSQC 355 The figure below show the layout of the DSQC 355 board: X7 X8 X7 X8 Bus s tatus S2S3 X2 X5 X3 Analog I/O DS QC 355 X5 AB B F lexible Automation X3 xx0100000238 3HAC 16245-1 X3 Not used X5 DeviceNet input and ID connector X7 Analog outputs X8 Analog inputs A 121 5 Electrical connections 5.7.5 Analog I/O, DSQC 355 (optional) Connections, connectors X7 analog output The figure below shows the pin configuration of the connector: 1 13 2 2 xx0100000236 The table below show the connections to connector X7: Signal name X7 pin Explanation ANOUT_ 1 Analog output 1, -10 V/+10 V ANOUT_ 2 Analog output 2, -10 V/+10 V ANOUT_ 3 Analog output 3, -10 V/+10 V ANOUT_ 4 Analog output 4, 4-20 mA Not used 5 Not used 6 Not used 7 Not used 8 Not used 9 Not used 10 Not used 11 Not used 12 Not used 13 Not used 14 Not used 15 Not used 16 Not used 17 Not used 18 GND 19 Analog output 1, 0 V GND 20 Analog output 2, 0 V GND 21 Analog output 3, 0 V GND 22 Analog output 4, 0 V GND 23 GND 24 The input current is 5.5 mA (at 24V) on the digital inputs. A capacitor connected to ground, to prevent disturbances, causes a short rush of current when setting the input. Connect a resistor (100 W) in series when connecting outputs, sensitive to pre-oscillation current. 122 A 3HAC 16245-1 5 Electrical connections 5.7.5 Analog I/O, DSQC 355 (optional) Connections, connectors X8 analog input The figure below shows the pin configuration of the connector: 1 1 6 3 xx0100000237 The table below show the connections to connector X8: 3HAC 16245-1 Signal name X7 pin Explanation ANIN_1 1 Analog input 1, -10 V/+10 V ANIN_2 2 Analog input 2, -10 V/+10 V ANIN_3 3 Analog input 3, -10 V/+10 V ANIN_4 4 Analog input 4, -10 V/+10 V Not used 5 Not used 6 Not used 7 Not used 8 Not used 9 Not used 10 Not used 11 Not used 12 Not used 13 Not used 14 Not used 15 Not used 16 +24 V out 17 +24 VDC supply +24 V out 18 +24 VDC supply +24 V out 19 +24 VDC supply +24 V out 20 +24 VDC supply +24 V out 21 +24 VDC supply +24 V out 22 +24 VDC supply +24 V out 23 +24 VDC supply +24 V out 24 +24 VDC supply GND 25 Analog input 1, 0 V GND 26 Analog input 2, 0 V GND 27 Analog input 3, 0 V GND 28 Analog input 4, 0 V GND 29 GND 30 GND 31 A 123 5 Electrical connections 5.7.5 Analog I/O, DSQC 355 (optional) Signal name X7 pin GND 32 Explanation The input current is 5.5 mA (at 24V) on the digital inputs. A capacitor connected to ground, to prevent disturbances, causes a short rush of current when setting the input. Connect a resistor (100 W) in series when connecting outputs, sensitive to pre-oscillation current. Bus status LEDs The figure and table below show the location and significance of the the LEDs on the board. Designation Color Description NS/MS Green/red See section 4.1. RS232 Rx Green Indicates the state of the RS232 Rx line. LED is active when receiving data. If there is no light, check communication line and connections. RS232 Tx Green Indicates the state of the RS232 Tx line. LED is active when transceiving data. If there is no light when transmission is expected, check error messages and check also system boards in rack. Green Indicates that supply voltage is present and at correct level. If there is no light, check that voltage is present on power unit and that power is present in power connector. If not, check cables and connectors. If power is applied to the unit but it does not work, replace the unit. A 3HAC 16245-1 +5VDC / +12VDC / -12VDC 124 5 Electrical connections 5.7.6 Encoder interface unit, DSQC 354 (optional) 5.7.6 Encoder interface unit, DSQC 354 (optional) General The encoder interface unit handles communication with external conveyor: • One encoder input (synchronisation of conveyor position with robot movements). The encoder is supplied with 24 V and 0 V, and sends position information in two channels. This information is computed by the on-board computer using quadrature decoding (QDEC) to determine position and direction. • One digital input (external start signal/conveyor synchronisation point) Technical data No. of encoder inputs 1 No. of digital inputs 1 (24 VDC) Supply voltage 24 VDC Supply source 24 V I/O or external supply Also see Product Specification for controller S4Cplus. Further information User reference Description Conveyor Tracking. For setup parameters, see User’s Guide - System Parameters, Topic: Controller. Also see the Circuit Diagram. Layout, DSQC 354 The figure below show the layout of the DSQC 354 board: X20 X5 X3 xx0100000233 3HAC 16245-1 X3 Not used X5 DeviceNet input and ID connector X20 Conveyor connection A 125 5 Electrical connections 5.7.6 Encoder interface unit, DSQC 354 (optional) Encoder connections The figure below show the encoder connections: AF AA AB 24 VDC 0V AC A B 24 VDC AD 0V AE 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Opto Opto Opto Opto Opto Opto AG xx0100000234 Connections, connectors X20 encoder and digital input connections 126 AA 24 V I/O or external supply AB 0 V I/O or external supply AC Encoder AD Sync switch AE 10-16 not used AF Encoder unit AG Galvanic isolation The table below show the connections to connector X20: Signal name X20 pin Explanation 24 VDC 1 24 VDC supply 0V 2 0V ENC 3 Encoder 24 VDC ENC 4 Encoder 0 VDC ENC_A 5 Encoder phase A ENC_B 6 Encoder phase B DIGIN 7 Synchronization switch 24 VDC DIGIN 8 0V DIGIN 9 Synchronization switch digital input Not used 10 Not used 11 Not used 12 A 3HAC 16245-1 5 Electrical connections 5.7.6 Encoder interface unit, DSQC 354 (optional) Signal name X20 pin Not used 13 Not used 14 Not used 15 Not used 16 Explanation The figure below show the layout of the pins in connector X20: 1 16 xx0100000235 Bus status LEDs The figure and table below show the location and significance of the the LEDs on the board. Designation Color Description POWER, 24 VDC Green Indicates that a supply voltage is present, and has a level above 12 VDC. If there is no light, check that voltage is present on power unit and in connector X20. If not, check cables and connectors. If power is applied to the unit but it does not work, replace the unit. NS/MS Green/red See section "CAN bus status LED description". CAN Tx/CAN Rx Green/red See section "CAN bus status LED description". ENC 1A/1B Indicates phase 1 and 2 from encoder. Flashes at each Encoder pulse. At frequencies higher than a few Hz, flashing can no longer be observed (light will appear weaker). If there is no light, there is an error due to one or more of the following reasons: • Faulty power supply for input circuit (internal or external). Green • Defective input circuit on board. • Short circuit or broken wire in external wiring or connectors. • Internal error in unit. Constant light indicates constant high level on input and vice versa. No light on one LED indicates fault in one encoder phase. 3HAC 16245-1 A 127 5 Electrical connections 5.7.6 Encoder interface unit, DSQC 354 (optional) 128 Designation Color Description DIGIN1 Green Digital input. Lit when digital input is active. The input is used for external start signal/conveyor synchronisation point. If there is no light, there is an error due to one or more of the following reasons: • Faulty power supply for input circuit (internal or external). A • Faulty limit switch, photocell etc. • Short circuit or broken wire in external wiring or connectors. • Defective input circuit on board. 3HAC 16245-1 5 Electrical connections 5.8.1 Allen-Bradley, general Section 5.8: Communication 5.8.1 Allen-Bradley, general General The robot may communicate with the Allen Bradley system only, or be used in combination with the I/O system in the robot. For example, the inputs to the robot may come from the Allen Bradley system while the outputs from the robot control external equipment via general I/O addresses and the Allen Bradley system only reads the outputs as status signals. Definitions The Allen Bradley system can communicate with up to 64 external systems. Each of these systems is called a Rack and is given a Rack Address 0-63. Basically, each robot connected to the Allen Bradley system will occupy one rack. Each rack is divided into four sections called Quarters. Each quarter provides 32 inputs and 32 outputs and a rack will subsequently provide 128 inputs and 128 outputs. A rack may also be shared by 2, 3, or 4 robots. Each of these robots will then have the same rack address, but different starting quarters must be specified. Illustration The following illustration shows a block diagram of the Allen-Bradley system, where Robot 1 uses a full rack while robot 2 and robot 3 share one rack. The rack address, starting quarter, and other required parameters such as baud rate, LED status etc. are entered in the configuration parameters. Allen Bradley control system Robot 1 - 128 in / 128 out Quarter 1 Quarter 2 Robot 2 - 64 in / 64 out Quarter 1 128 in / 128 out Quarter 3 Quarter 4 Rack ID 12 (example) Rack size 4 Starting quarter 1 64 in / 64 out Other systems Quarter 1 Quarter 2 Quarter 2 Rack ID 13 (example) Rack size 2 Starting quarter 1 Quarter 3 Quarter 4 Robot 3 - 64 in / 64 out Quarter 3 64 in / 64 out Quarter 4 Rack ID 13 (example) Rack size 2 Starting quarter 3 en0100000255 3HAC 16245-1 A 129 5 Electrical connections 5.8.2 RIO, remote I/O for Allen-Bradley PLC DSQC 350 5.8.2 RIO, remote I/O for Allen-Bradley PLC DSQC 350 General The unit handles communication between the robot system and the Allen Bradley system. Technical data No. of digital inputs Unit is programmable for 32, 64, 96 or 128 digital inputs No. of digital outputs Unit is programmable for 32, 64, 96 or 128 digital outputs Also see the Allen-Bradley RIO specification. Further information For setup parameters, see User’s Guide - System Parameters, Topic: I/O Signals. Also see Circuit Diagram. Connection The RIO-unit should be connected to an Allen-Bradley PLC using a screened, two conductor cable. Layout, DSQC 350 The figure below show the layout of the DSQC 350 board: X5 X9 X3 X8 DS QC 350 ABB F lexible Automation xx0100000226 Connections, connector X8 X3 Not used X5 DeviceNet and ID connector X8 RIO in X9 RION out The figure below shows the pin configuration of the connector: 5 1 xx0100000221 130 A 3HAC 16245-1 5 Electrical connections 5.8.2 RIO, remote I/O for Allen-Bradley PLC DSQC 350 The table below shows the connections to connector X8: Connections, connector X9 Signal name X8 pin Function LINE1 (blue) 1 Remote I/O in LINE2 (clear) 2 Remote I/O in Shield 3 Remote I/O in Cabinet ground 4 Remote I/O in The figure below shows the pin configuration of the connector: 5 1 xx0100000221 The table below show the connections to connector X9: Signal name X9 pin Function Blue 1 Remote I/O out Clear 2 Remote I/O out Shield 3 Remote I/O out Cabinet ground 4 Remote I/O out Termination When the robot is last in a RIO loop, the loop must be terminated with a termination resistor according to Allen-Bradley’s specification. Warranty This product incorporates a communications link which is licensed under patents and proprietary technology of Allen-Bradley Company, Inc. Allen-Bradley Company, Inc. does not warrant or support this product. All warranty and support services for this product are the responsibility of and provided by ABB Flexible Automation. Bus status LEDs The figure and table below show the location and significance of the the LEDs on the board. The designations refer to LEDs shown in the figure in section "Layout, DSQC 350" above. Designation Color Description POWER-24 VDC Green NS/MS Indicates that a supply voltage is present, and has a level above 12 VDC. If there is no light, check that voltage is present on power unit and in power connector. If not, check cables and connectors. If power is applied to the unit but it does not work, replace the unit. Green/red See section "CAN bus status LED description". CAN Tx/CAN Rx Yellow 3HAC 16245-1 See section "CAN bus status LED description". A 131 5 Electrical connections 5.8.2 RIO, remote I/O for Allen-Bradley PLC DSQC 350 132 Designation Color Description NAC STATUS Green Steady green indicates RIO link in operation. If there is no light, check network, cables and connections. Also check that PLC is operational. Flashing green indicates that communication is established, but the INIT_COMPLETE bit is not set in NA chip, or configuration, rack size etc. does not match configuration set in PLC. If LED keeps flashing continuously, check setup. A 3HAC 16245-1 5 Electrical connections 5.8.3 Communication, serial links 5.8.3 Communication, serial links General T he robot has three serial channels, which can be used by the customer to communicate with printers, terminals, computers, and other equipment (see the figure in "Connections" below). Further information • COM1 (computer system) - RS 232 115 kbps. This was formerly referred to as Com2. • COM2 - RS 232 with RTS-CTS-control and support for XON/XOFF, transmission speed 300 - 38 400 b/s. This was formerly referred to as SIO1. • COM3 - RS 422 full duplex TXD4, TXD4-N, RXD4, RXD4-N, transmission speed 300 38 400 b/s. This was formerly referred to as SIO2. • For temporary use : MC/CONSOLE - RS 232 115 kb/s. This was formerly referred to as Com1. • For setup parameters, see User's Guide - System Parameters, Topic: I/O Signals. • Circuit Diagram. • Location in the cabinet (see figure in section "Connection to screw terminals"). Technical data See Product Specification for controller S4Cplus. Separate documentation is included when the option RAP Serial link is ordered. Connections The figure below shows the connection of serial channels: A xx0100000219 A External computer Customer terminals, on base connector board: X10 (COM2) and X9 (COM3), see section "Connection to screw terminals". Connections on DSQC 504, COM1 Standard RS232 port. The figure below shows the pin configuration of the connector: 5 1 6 9 xx0100000220 3HAC 16245-1 A 133 5 Electrical connections 5.8.3 Communication, serial links The table below shows the signals from the COM1 (RS232): Connections on DSQC 504, D-sub connector X10, COM2 Signal Pin Description DCD 1 Data carrier Detect RX 2 Receive Data TX 3 Transmit Data DTR 4 Data Terminal Ready GND 5 Signal Ground DSR 6 Data Set Ready RTS 7 Request To Send CTS 8 Clear To Send RI 9 Ring Indicator NC 10 Not Connected The figure below shows the pin configuration of the connector: 5 1 6 9 xx0100000220 The table below shows the connections to connector X10: COM2 Signal name X10 pin 1 RxD (Receive Data) 2 TxD (Transmit Data) 3 DTR (Data Terminal Ready) 4 0V 5 DSR (Data Ready Set) 6 RTS N (Request To Send N) 7 CTS (Clear To Send) 8 9 Connections on DSQC 504, D-sub connector X9, COM3 The figure below shows the pin configuration of the connector: 5 1 6 9 xx0100000220 The table below shows the connections to connector X9: 134 COM3 Signal name X9 socket TxD (Transmit Data) 1 TxD N (Transmit Data N) 2 A 3HAC 16245-1 5 Electrical connections 5.8.3 Communication, serial links Connections to MC/CONSOLE COM3 Signal name X9 socket RxD (Receive Data) 3 RxD N (Receive data N) 4 0V 5 DATA (Data Signals in Half Duplex Mode) 6 DATA N (Data Signals in Half Duplex Mode N) 7 DCLK (Data Transmission Clock) 8 DCLK N (Data Transmission Clock N) 9 The figure below shows the MC/CONSOLE connection behind the service hatch: A xx0100000218 A External computer Standard RS232 port intended for temporary use, e.g. connection of laptop/PC. The table below shows the signals on the MC/CONSOLE (RS232): 3HAC 16245-1 Signal Pin Description RX 2 Receive Data TX 3 Transmit Data GND 5 Signal Ground A 135 5 Electrical connections 5.8.4 Communication, Ethernet 5.8.4 Communication, Ethernet General Connection of LAN (Main computer) The robot has two Ethernet channels available: • LAN (connected to the Main computer) • Service (connected to the I/O computer) The figure below shows an outline diagram of the Ethernet TCP/IP: A B C E thernet hub xx0100000217 A External computer B Controller Robot 1 C Controller Robot 2 Used for connection of shielded twisted-pair Ethernet (TPE), or as defined in IEEE 802.3: 10/ 100 BASE-T. Maximum node-to-node distance 100 meter. The main computer board has no termination for a cable shield. The cable shield must be grounded at the cabinet wall with a cable gland. 10BASE-T is a point-to-point net, connected via a HUB, see the figure above. Signal X1 Pin Description TX+ 1 Transmit data line + TX- 2 Transmit data line - RX+ 3 Receive data line + NC 4 Not Connected NC 5 Not Connected RX- 6 Receive data line - NC 7 Not Connected NC 8 Not Connected The figure below shows the main computer board front: 136 A 3HAC 16245-1 5 Electrical connections 5.8.4 Communication, Ethernet 1 8 X1 LAN PWR HDD STATUS X2 xx0100000216 Connection of Service (I/O Computer) Used for connection of a laptop to the service outlet on cabinet front (behind service hatch) on the controller. The figure below shows how to connect a laptop to the service outlet: E thernet xx0100000215 For setup parameters, see User’s Guide - System Parameters, Topic: I/O Signals. Also see the Circuit Diagram. Separate documentation is included when the option Ethernet services is ordered. 3HAC 16245-1 A 137 5 Electrical connections 5.8.5 External operator’s panel 5.8.5 External operator’s panel General All necessary components are supplied, except for the external enclosure. Dimensions for installation Install the assembled panel in a housing which satisfies protection class, IP 54, in accordance with IEC 144 and IEC 529! The following figure shows the main dimensions of the external operator’s panel: A B M8 (x4) M4 (x4) 62 C 45° 70 140 184 200 D E 90 ø5 (x2) 155 F G xx0100000214 138 A Holes for operator’s panel B Holes for flange C Required depth: 200 mm D External panel enclosure (option) E Holes for teach pendant unit (TPU) holder F Teach pendant unit (TPU) connector G Connection to the controller A 3HAC 16245-1 6 Start-up 6.0.1 Inspection before start-up Chapter 6: Start-up 6.0.1 Inspection before start-up General Perform the following checks before starting up the robot system: Check: 1. The controller mains section is protected with fuses. 2. The electrical connections are correct and correspond to the identification plate on the controller. 3. The teach pendant and peripheral equipment are properly connected. 4. That limiting devices that establish the restricted space (when utilised) are installed. 5. The physical environment is as specified. 6. The operating mode selector on the operator’s panel is in the Manual mode position. 7. When external safety devices are used, check that these have been connected or that the following circuits in either XS3 (connector on the outside left cabinet wall) or X1-X4 (screw terminals on the panel unit) are strapped: 3HAC 16245-1 Device XS3 Panel unit External limit switches A5-A6, B5-B6 X1.3-4, X2.3-4 External emergency stop A3-A4, B3-B4 X1.9-10, X2.9-10 External emergency stop internal 24 V A1-A2, B1-B2 X1.7-8, X2.7-8 General stop + A11-A12, B11-B12 X3.10-12, X4.10-12 General stop - A13-A14, B13-B14 X3.7-8, X4.7-8 Auto stop + A7-A8, B7-B8 X3.11-12, X4.11-12 Auto stop - A9-A10, B9-10 X3.7-9, X4.7-9 Motor off clamping A15-A16, B15-16 X1.5-6, X2.5-6 A 139 6 Start-up 6.0.2 Start-up 6.0.2 Start-up General 1. Switch on the mains switch on the cabinet. 2. The robot performs its self-test on both the hardware and software, which takes approximately 1 minute. 3. If the robot is not supplied with the software already installed, install the software as described in section "Robot Controller". A welcome message is shown on the Teach Pendant Unit display. 4. To switch from MOTORS OFF to MOTORS ON, press the enabling device on the teach pendant. 5. Update the revolution counters as described in "Updating the revolution counters". 6. Check the calibration position as described in "Checking the calibration position". 7. When the controller, with the manipulator electrically connected, is powered up for the first time, ensure that the power supply is connected for at least 36 hours continuously, in order to fully charge the batteries for the serial measurement board. It takes approx. 4 hours to fully charge a computer system battery. 8. After having checked the above, verify that: • the start, stop and mode selection (including the key lock switches) control devices work as intended. • each axis moves and is restricted as intended. • emergency stop and safety stop (where included) circuits and devices are functional. • it is possible to disconnect and isolate the external power sources. • the teach and playback facilities work correctly. • the safeguarding is in place. • at reduced speed, the robot operates properly and has the capability to handle the product or workpiece. • in automatic (normal) operation, the robot operates properly and has the capability to perform the intended task at the rated speed and load. 9. The robot is now ready for operation. Operating the robot 140 Starting and operating the robot is described in the User’s Guide. Before start-up, make sure that the robot cannot collide with any other objects in the working space. A 3HAC 16245-1 7 Installation of controller software 7.0.1 Loading system software Chapter 7: Installation of controller software 7.0.1 Loading system software General The robot system may delivered with or without system software. When the system is not delivered with software, this must be downloaded in one of a number of ways. Software installed on delivery If the robot controller is ordered with the software installed on delivery, the controller software and settings are already stored in the storage memory and the system is ready to use. Software not installed on delivery If the robot controller is ordered and delivered without software or if you want to reconfigure your system, the RobInstall tool must be used to install the controller software. The RobInstall tool is included on the RobotWare CD-ROM (see section "RobotWare CD-ROM"). The RobInstall tool can be used both for creation of the controller software and for downloading it to the controller system. Types of software loading Rob Install A B D C E xx0100000192 A RobotWare CD-ROM to install RobInstall and System Pack on PC B Floppy Disks C IOC Ethernet (service) with delivered boot cable UTP-X D Connected to IOC E MC Ethernet (LAN) network in workshop When downloading, the controller software can be transferred to the controller storage memory in three ways as shown in the figure above. 3HAC 16245-1 • using floppy disks, • using Ethernet connected direct to the IO computer (IOC) service outlet on the front of the controller cubicle, • using Ethernet connected via a local area network (LAN) to the main computer (MC). A 141 7 Installation of controller software 7.0.1 Loading system software Boot Image The transfer and installation of the controller software to the controller storage memory via Ethernet or floppy disks is executed by a basic program named Boot Image. This basic program must always be in the storage memory. At start-up of the controller, without any controller software installed, Boot Image will start and ask the operator for controller software installation instructions. If the controller software is already installed and a warm start is performed, Boot Image is not used. The installed controller software can be deleted by cold start and then the Boot Image will be reactivated. 142 A 3HAC 16245-1 7 Installation of controller software 7.0.2 RobotWare CD-ROM 7.0.2 RobotWare CD-ROM The CD contains all the System software and should therefore be treated and stored carefully. RobotWare CD-ROM contents Installation of the RobotWare on the PC (except FTP Client) The RobotWare CD-ROM contains the following: Contents Description 1. RobInstall A PC tool used to create and install the controller operating system in the robot control system. 2. Documentation On-line documentation for the RobInstall application and the Controller Operating System Package. 3. Controller OS Package Controller Operating System Package for S4Cplus. This package includes all the software needed to create the controller operating system with any ordered options. Please note that it is possible to install different releases with different versions of the same system package (see section "Media Pool in the PC"). 4. Test Signal Viewer A tool (created in LabView) for viewing MotionTest Signals (oscilloscope function) and also for logging these signals. 5. FTP Client On the CD is also included a so called FTP client named Voyager. Please note that this is not an ABB product but a shareware program, which means that it can be installed and used for a limited time, but that it has to be registered for permanent use. Registering means that a certain fee must be paid to the vendor. The FTP client is used to transport files manually between the PC and the robot controller storage memory. These actions are carried out in the same way as in a file manager or in Windows Explorer. This section describes how to install the software delivered on the RobotWare CD-ROM onto a PC hard drive, to be transferred to the robot system. 1. Insert the CD in your reader. 1. The Install Shield will automatically start and guide you through the install process (if it does not start, double-click the CD icon on your PC). When the setup type window is presented, it is recommended to select the Custom button. Then Next button will open the Select Components window, where normally all the four options, RobInstall, Documentation, Controller OS Package and Test Signal Viewer should be marked as selected. Installation of the FTP Client on the PC This section describes how to install the FTP Client onto a PC hard drive. 1. In the Explorer, select and open the directory "ftp" on the CD. 2. Double-click the file ftpvsetup.exe. The Install Shield for the FTP client will start and guide you through the installation. Please read the "Readme" file for information about license regulations. 3HAC 16245-1 A 143 7 Installation of controller software 7.0.3 Installing new Robot Controller Software with RobInstall 7.0.3 Installing new Robot Controller Software with RobInstall General Nomenclature How to use RobInstall Since most systems have the operating system installed already on delivery, the RobotWare CD-ROM is normally not needed. However it should be used when: • creating a new controller operating system, • changing the current operating system configuration, e.g. concerning included options. In the text dealing with RobInstall, the following nomenclature is used: Concept Means System pack This is the RobotWare Controller Operating System Package for S4Cplus, including all options, even if they are not ordered and activated. Key This is a text string, or a special file with the text string, which is used to define and open both the BaseWare and all ordered RobotWare options. System This is a complete controller software, i.e. controller operating system, based on the system pack and the key. It can also include any user files to be added to the home directory on the controller storage memory. Robinstall is used to create and install the controller software in the S4Cplus robot controller. With RobInstall, you can: • create a new system, • update an existing system, • download a system to the controller using the Ethernet connection, • create Boot Disks to transfer the system to the Controller. Step Action 144 Illustration/Info 1. Make sure RobInstall is installed. If not, install it according to the instructions in section "Installation of the RobotWare on the PC". 2. Click the start button on your PC and select programs/ABB Robotics/RobInstall/RobInstall. A 3HAC 16245-1 7 Installation of controller software 7.0.3 Installing new Robot Controller Software with RobInstall Step Action 3. Illustration/Info The RobInstall start window will open. xx0100000185 3HAC 16245-1 A 145 7 Installation of controller software 7.0.4 Create a new Robot Controller System 7.0.4 Create a new Robot Controller System Setting up the system Step Action Illustration/info 1. Start RobInstall as described in section "How to use Robinstall". 2. Choose New to create a new Robot Controller system as shown in the figure. 3. Enter a name for the new controller system. Select a saving location or use the default directory, normally "Program Files\ABB Robotics\system" (see the figure below, position 1). 4. Enter the RobotWare key or add from file. If added from a file, files with the extension .kxt should be used (see the figure above, position 2). 5. Press OK . The configured system will be displayed in the next window (see the figure below). xx0100000179 xx0100000180 xx0100000181 146 A 3HAC 16245-1 7 Installation of controller software 7.0.4 Create a new Robot Controller System Step Action 6. Illustration/info If no external options or parameters are to be added or changed, press Finish to create the new controller system. Otherwise press Next to continue to "Additional Keys" (see section "Add or remove external options"). Add or remove external options Step Action 1. Illustration(info To add or remove external options, press Next in the screen shown in the last figure in section "Setting up the system" or click on "Additional Keys" in the menu to the left. xx0100000182 Add or remove additional system parameters 2. Enter the key string for the selected option and press Add Key to list, or pressAdd key from file to select a key string file. 3. To remove additional keys, select the key in the Included Additional Keys list and press Remove Key . 4. Press Finish to create the controller system or press Next to continue to "Parameter Data" (see section "Add or remove additional system parameters). Step Action 1. Illustration/Info To add or remove additional parameters, press Next in the screen shown in the last figure in section "Add or remove external options" or click on "Parameter Data" in the menu to the left. xx0100000183 3HAC 16245-1 A 147 7 Installation of controller software 7.0.4 Create a new Robot Controller System Step Action Change options or system pack revision Illustration/Info 2. Press Add to load manipulator calibration data (see the figure above, position 1). This is the calib.cfg file delivered on the Manipulator Parameter disk (see section "The manipulator parameter disk"). 3. To remove manipulator calibration data, press Remove . 4. Press Add to load additional system parameters, see pos. 2. All system parameter files added here will be automatically loaded together with the system, when the controller is restarted with the new system. 5. To remove additional parameters, select the parameter in the "Loaded Additional Parameters" list and press Remove . 6. Press Finish to create the controller system or press Next to continue to "Options" (see section "Change options or system pack revision"). Step Action 1. Illustration/Info To change the option configuration, press Next in the screen shown in the figure below or click on "Options" in the menu to the left. xx0100000184 148 2. To change the Teach Pendant Unit language, robot type, or software options, press Options (see the figure above, position 1). 3. Normally the latest release or revision of all system packages and option packages stored in the media pool (see section "Media Pool in the PC") will be used. If an earlier revision should be used, uncheck the check mark and press Rev. Select (see the figure above, position 2). In the new window select the system package to use and press OK . A 3HAC 16245-1 7 Installation of controller software 7.0.4 Create a new Robot Controller System Step Action 3HAC 16245-1 Illustration/Info 4. If you want the system to start up in query mode, put a mark in the query mode selection square. For further details of the query mode, see section "Start in Query Mode". 5. Press Finish to create the controller system or press Next to view the current configuration. A 149 7 Installation of controller software 7.0.5 Update the Robot Controller image 7.0.5 Update the Robot Controller image Actions Step Action 1. Illustration/Info To update an existing controller system, press Update , see the figure below. xx0100000189 2. Select a system in the system list and press OK , see the figure above. Please note that a pop up menu can be shown by clicking right mouse button. With this menu Copy, Rename or Delete can be selected for the marked system. 3. The window displaying the current configuration of the system will be shown. Follow the instructions in sections "Add or remove external options", "Add or remove additional system parameters" or "Change options or system pack revision" to modify the system. xx0100000190 150 A 3HAC 16245-1 7 Installation of controller software 7.0.6 Transfer Robot Controller System using Ethernet connection 7.0.6 Transfer Robot Controller System using Ethernet connection Selecting type of set-up Before a system can be downloaded to a robot controller using the RobInstall tool some preparations and set up must be done. This may be done in one of two ways: ...then see instructions in section: If you are using: a direct connection between "If using a direct connection PC and IOC service outlet on between PC and IOC service controller outlet on controller" below! If using a direct connection between PC and IOC service outlet on controller ...and continue in section: "Download Robot Controller System" below! Network Intranet connection with fixed IP addresses "If using Network Intranet con"Download Robot Controlnection with fixed IP addresses " ler System" below! below! Network Intranet connection with DHCP (Dynamic Host Configuration Protocol) "If using Network Intranet connection with DHCP " below! Step Action "Download Robot Controller System" below! Illustration/Info 1. Connect a patch-cable between the Ethernet connection on the front of the controller and the corresponding connection on the PC/ Laptop. 2. Make sure that the Network protocol is set for TCP/IP properties. 3. Change the TCP/IP Properties in accordance with the following table and figure: xx0100000178 3HAC 16245-1 A 151 7 Installation of controller software 7.0.6 Transfer Robot Controller System using Ethernet connection If using Network Intranet connection with fixed IP addresses If using Network Intranet connection with DHCP Step Action Illustration/Info 1. Make sure that the Network protocol is set for TCP/IP properties. 2. Change the TCP/IP Properties in accordance with the values to be used for IP address, Subnet mask and Gateway. 3. Perform a X-START (see section "x-START") or CSTART (see section "C-start") on the S4Cplus controller. 4. Configure the IP address to be used for the robot controller from the TPU. Step Action 1. Illustration/Info Read Ethernet MAC-id on the Teach Pendant Unit (see section "LAN settings"). Download Robot Controller System Before downloading, check the following: Make sure there is at least 25 Mb free disk space on the controller mass storage memory. For information on how to perform a manual storage capacity check, see section "Check Storage Capacity". Make sure that the robot controller displays the Start Window on the Teach Pendant Unit (see section "Start window"). Step Action 1. Illustration/Info To download a controller system, press Download as in the figure below: xx0100000176 152 A 3HAC 16245-1 7 Installation of controller software 7.0.6 Transfer Robot Controller System using Ethernet connection Step Action Illustration/Info 2. Select a target system as in the fig- If a direct connection is used with the patch ure, position 1. cable between the PC and the controller front, then just select the default IP address (192.168.125.1) and "Direct" option. In other cases, write the correct IP address for the robot controller and select "Hostname or IPaddress". RobInstall will store already used IP addresses, which can later be selected with the down arrow. 3. Type your username and password if required by the robot controller as in the figure below, position 2. 4. Test the connection by pressing Test Connection and press OK if a connection is established. 5. Select a system in the list on the left and press OK as in the figure below. Please note that it is possible to select another system pool than the shown one (in such case be sure to select the system pool directory, not the system itself on the lower level). 6. RobInstall will now create a system After downloading it is possible to restart the file and download it to the controller. controller with the new downloaded controller system. Otherwise, the controller may be restarted from the Teach Pendant Unit as detailed in section "Reboot". xx0100000177 xx0100000175 3HAC 16245-1 A 153 7 Installation of controller software 7.0.7 Transfer Robot Controller System using floppy disks 7.0.7 Transfer Robot Controller System using floppy disks Before downloading, make sure: there is at least 25 Mb free disk space on the controller mass storage memory. For information on how to perform a manual storage capacity check, see section "Check Storage Capacity". that the robot controller displays the Start Window on the Teach Pendant Unit (see section "Start Window"). an optional floppy disk drive is installed in the robot controller. Create Boot Diskettes from RobInstall Step Action 1. Illustration/Info Press Create Boot Disk as in the figure below. xx0100000173 2. Select a system in the list on the left and press OK as in the figure below. RobInstall will now create an image file and estimate the number of disks needed. xx0100000175 xx0100000188 154 3. Insert a formatted 1.44 Mb diskette into the disk drive. 4. Press Continue to start copy the Robot Controller System image to the disks. A 3HAC 16245-1 7 Installation of controller software 7.0.7 Transfer Robot Controller System using floppy disks Step Action 5. 3HAC 16245-1 Illustration/Info Use the finished floppy disks to boot your system as described in section "Boot Disks". A 155 7 Installation of controller software 7.0.8 RobInstall preferences 7.0.8 RobInstall preferences Customizing RobInstall RobInstall may be customized to suit particular requirements. Step Action 1. Illustration/Info To customise RobInstall for new programs and optional products, press Preferences as shown in the figure. See also chapter "System Directory Structure". xx0100000186 2. To select another media pool (see section "Media Pool in the PC"), press Select Media Pool as shown in the figure, position 1. xx0100000187 3. 156 To add a new system package or option package to the media pool, press Import Program as shown in the figure, position 2. Also see chapter "System Directory Structure". A 3HAC 16245-1 8 Robot controller 8.0.1 BootImage Chapter 8: Robot controller 8.0.1 BootImage General The BootImage is a basic program which is used to start up the system from "scratch". Purpose of the program This program is already installed in the controller at delivery and is used to: 3HAC 16245-1 • restart the system • load the system from boot disks or network connections • set or check network settings • choose a system from the mass storage memory. A 157 8 Robot controller 8.0.2 Start window 8.0.2 Start window When is it shown? xx0100000168 The start window displays the start menu and will appear in the following cases: • When no controller operating system is installed at power on. • After X-START (see section "X-start"). • After C-START (see section "C-start"). Possible actions From this window you can choose to do one of the following: Restart the system, Reboot The BootImage will be re-executed, used to apply changes in the system settings (see section "Reboot"). Load a system from diskettes, Boot Disks (See section 4.4) Set the network settings, Network Settings Set network settings for Main Computer or check how to configure your PC (see section "Network Settings"). Choose a system from the mass storage memory, Select System If there are one or more systems in the mass storage memory, you can choose to activate one of them (see section "Select System). 158 A 3HAC 16245-1 8 Robot controller 8.0.3 Reboot Window 8.0.3 Reboot Window When is it shown? The Reboot window will be displayed if any of the system settings are changed or when Reboot is pressed in the Start window as shown in the figure below:. xx0100000169 3HAC 16245-1 Button Function YES Restarts the system NO Returns to the start window A 159 8 Robot controller 8.0.4 Boot Disk Window 8.0.4 Boot Disk Window When is it shown? The Boot Disk window will be displayed when Boot Disks is pressed in the Start window as shown in the figure in section "Start window". How to create boot disks Information on how to create boot disks from RobInstall can be found in section "Create Boot Diskettes from Robinstall". Load the system Step Action 1. Illustration/Info Insert the correct diskette in the floppy disk drive and press OK . If the diskette is alright, the system will be loaded. CANCEL removes all previously loaded data and returns to the Start window as shown in the figure in section "Start window". xx0100000170 160 A 3HAC 16245-1 8 Robot controller 8.0.5 LAN Settings Window 8.0.5 LAN Settings Window When is it shown? The LAN Settings window will be displayed when LAN Settings is pressed in the Network Settings window as shown in the figure in section "Network Settings". en0100000256 NONE will, after the system is rebooted, remove the IP settings. CANCEL returns to the Start window, as shown in the figure in section "Start Window", without changing any settings. Parameter Type Description MAC ID Node identification The Main Computer’s ethernet address. Current IP Node identification The Main Computer’s current IP address. This row is blank if the LAN Settings has not been defined. IP Network setting Space for typing a new IP address, for the Main Computer or the DHCP server. See Configure for fixed IP network and Configure for DHCP distributed IP network below. (Subnet mask) Network setting Shows the subnet mask of the network. Only visible when configured for fixed IP. (Gateway) Network setting Shows the gateway IP for the network. Only visible when configured for fixed IP. Node identification Configure for fixed IP network 1. Press FIX IP . 2. Fill in the assigned IP address for the Main Computer, and the Subnet Mask and Gatway for the Network and press OK . You will be asked to reboot the system. 3. Press YES to make the new setting take effect. Configure for DHCP distributed IP network 1. Press DHCP . 2. The value for IP will change to DHCP. 3. Press OK. You will be asked to reboot the system. 4. Press YES to make the new setting take effect. 3HAC 16245-1 A 161 8 Robot controller 8.0.6 Service Settings Window 8.0.6 Service Settings Window When is it shown? The Service Settings window will be displayed when Service Settings is pressed in the Network Settings window as shown in the figure in section "Network Settings". en0100000257 OK returns to the Start window as shown in the figure in section "Start Window". Parameter Description Service Setting IP (service setting) The IP Address for the I/O Computer 162 IP Required to configure your PC’s network settings for communication between RobInstall and the I/O Computer. Subnet mask Required to configure your PC’s network settings for communication between RobInstall and the I/O Computer. Gateway Required to configure your PC’s network settings for communication between RobInstall and the I/O Computer. A 3HAC 16245-1 8 Robot controller 8.0.7 System selection window 8.0.7 System selection window When is it shown? The Select System window will be displayed when Select System is pressed in the Start window as shown in the figure in section "Start Window". xx0100000171 CANCEL How to select system returns to the Start window as shown in the figure in section "Start Window". The window shows all systems installed on the controller mass storage memory. Step Action 1. Illustration/Info Select by moving the X to a desired system and press OK . The system will reboot with the new system and then present the Welcome window as shown in the figure. xx0100000172 3HAC 16245-1 A 163 8 Robot controller 8.0.8 How to perform a Restart 8.0.8 How to perform a Restart General Performing a restart may be done in a number of ways. These are detailed below: Reboot (Warm start), apply changed settings When executing a Warm start, the system reboots with the current system, e.g. to make new or changed settings take effect. Step Action Illustration/Info 1. Press the button Miscellaneous and select Service window or System Parameter window 2. Select Restart from the File menu and press OK . The system reboots and returns to the Welcome window as shown in the second figure in section "Select System". Miscellaneous button: xx0100000194 P-START, reinstallation of RAPID A P-Start will warm start the current system, with a reinstallation of the RAPID language and all auto loaded modules. This means that all RAPID program and system modules currently loaded in the working memory will be closed, and thus have to be reloaded again after the PStart, with exception for such modules which are automatically loaded, due to settings in the System Parameters/Controller/Task Modules. Step Action 1. Illustration/info Press the button Miscellaneous and select Service window . Miscellaneous button: xx0100000194 X-START, change active controller system 2. Select Restart from the File menu. 3. Enter the numbers: 2_5_8 (the fifth function key changes to P-START) 4. Press P-START . The system will reboot, reinstall RAPID and its auto loaded modules, and return to the Welcome window as shown in the second figure in section "Select System". An X-start will exit the running system, store system data on the mass storage memory, and then execute the BootImage to present the Start window. Any system stored in the mass storage memory, may then be selected as described in section "Select System". When performing an X-Start all stored system data will be restored (similar to performing a warm start). Step Action 1. Illustration/Info Press the button Miscellaneous and select Service win- Miscellaneous button: dow. xx0100000194 164 A 3HAC 16245-1 8 Robot controller 8.0.8 How to perform a Restart Step Action I-START, start in Query mode Illustration/Info 2. Select Restart from the File menu. 3. Enter the numbers: 1_5_9 (the fifth function key changes to X-START) 4. Press X-START . The system will reboot and return to the Start window as shown in the figure in section "Start Window". If "Use Query Mode at System Boot" was selected when creating the running system in RobInstall (see section "Change options or system pack revision"), an I-Start can be done. An IStart will restart the current system and give the opportunity to set some values at start-up, e.g. language, IRB type (within the same model) or options (see section "Start in Query Mode"). Step Action Illustration/Info 1. Press the button Miscellaneous and selectService win- Miscellaneous button: dow. 2. Select Restart from the File menu. 3. Enter the numbers: 1_4_7 (the fifth function key changes to I-START). 4. Press I-START . The system will start to reboot, then pause to ask for Silent, Easy, or Query mode. For more information on the different modes, continue to section "Start in Query Mode". xx0100000194 C-START (Cold start), delete the active system When executing a C-Start, the system exits the running system and deletes it from the mass storage memory. The BootImage is then executed and the Start window as shown in the figure in section "Start Window" is presented. Use C-start with caution. Since it deletes the current system, it should not be used to just switch between installed systems. For this purpose, use X-Start (see section "X-start"). It will take quite some time to implement a Cold start. Just wait until the robot shows the Start window. When the Start window is shown, a new system can be selected if available in the mass storage memory (see section "Select System) or a new system can be down loaded and started (see section "Transfer Robot Controller System using Ethernet connection" or "Transfer Robot Controller System using floppy disks"). Do not touch any key, joystick, enable device, or emergency stop during the cold start until the Start window is shown as in the figure in section "Start Window". Step Action 1. Illustration/Info Press the button Miscellaneous and selectService win- Miscellaneous button: dow. xx0100000194 2. 3HAC 16245-1 Select Restart from the File menu. A 165 8 Robot controller 8.0.8 How to perform a Restart Step Action 166 Illustration/Info 3. Enter the numbers: 1_3_4_6_7_9 (the fifth function key changes to C-START) 4. Press C-START . A 3HAC 16245-1 8 Robot controller 8.0.9 How to Start in Query Mode 8.0.9 How to Start in Query Mode Preconditions for selecting Query Mode start It is possible to set some values, e.g. language, IRB type (within the same model) or options, at the first start-up of the system, using a C-Start (see section "C-start"), or later on when performing an I-Start (see section "I-start") if "Use Query Mode at System Boot" was selected when creating the system in RobInstall (see section "Change options or system pack revision"). Types of Query Mode The first question from the system is what Query Mode to start. Depending on your needs, you should select one of the following three: Easy Query Mode • Silent Mode, pushbutton Silent . If Silent Mode is selected, the operating system will be installed with the system configured as defined in RobInstall. • Easy Query Mode, pushbutton Easy Query . In Easy Query Mode you can change language, remove selected options and select service or standard mode (see section "Easy Query Mode"). • Query Mode, pushbutton Query . In Query Mode you can, on top of the things in Easy Query, select DC-link, change Robot type (within the same family) and for IRB 7600, select balancing unit (see section "Query Mode"). If Easy Query was chosen as start-up query mode, the following steps will be required to start the system: Step Action Query Mode Illustration/Info 1. Select Service/Standard motion param. Choose between standard or service motion parameters (pushbutton Stand / pushbutton Service ). 2. Choose TP Language. If there was another language than English selected in RobInstall (see section "Change options or system pack revision"), it will be possible to choose language (pushbutton English /pushbutton "Other" ). 3. Install xxx? For every option that was selected in RobInstall (see section "Change options or system pack revision") it is now possible to select Yes to keep the option, or No to remove it from the system. If Query Mode was chosen as start-up query mode, the following steps will be required to start the system: Step Action 3HAC 16245-1 Illustration/info 1. Select Service/Standard motion param. See section "Easy Query Mode", step 1. 2. Choose TP Language. See section "Easy Query Mode", step 2. A 167 8 Robot controller 8.0.9 How to Start in Query Mode Step Action 3. Illustration/info Select external axes config. You can find the article number of the DC-link used on the unit inside the controller, then use the table below to find out the configuration ID for that DC-link. 168 4. Select xxxx model. Choose Robot model type within in the same family, e.g. 1400, 6400 etc. If there are more than three options, press pushbutton SCAN to view them. 5. Install xxx? See section "Easy Query Mode", step 3. A 3HAC 16245-1 9 System directory structure 9.0.1 Media pool in the PC Chapter 9: System directory structure 9.0.1 Media pool in the PC Directory All RobotWare System Packages and Option Packages are stored in a media pool directory as shown in the table below. Two revisions of the same system package may exist in the pool. By default, after having installed RobInstall, a directory "MediaPool" will be found in the directory Program Files\ABB Robotics\, and will also be the current one. However any directory in the structure can be set up as the current media pool in the Preference window (see section "Robinstall Preferences"). xx0200000156 Naming conventions 3HAC 16245-1 Art. no./folder name Description 3HAXaaaa-1.00 RobotWare System Pack 3HAXaaaa-1, rev 00 3HAXbbbb-1.02 RobotWare System Pack 3HAXbbbb-1, rev 02 3HAXcccc-1.01 ABB Robotics external option program 3HAXcccc-1, rev 01 3HYZdddd-1.00 OEM customer external option program 3XYZdddd-1, rev 00 Each package is stored in a directory, the name of which is an article number ending with the sub-number and with the revision number as shown in the table above. All the system packs and option packs in one media pool must have the correct revision numbers in their directory names. Thus a later revision can be loaded into the program pool, to be added to the old one, without changing the article number. A 169 9 System directory structure 9.0.2 System pool in the PC 9.0.2 System pool in the PC Directory All systems created with the RobInstall will be stored in a system pool. The default name of such a system pool is "system" as shown below. Each system stored in the system pool is a directory with the name of the system as shown in the table below. By default, after installing RobInstall, a directory "system" will be found in Program Files\ABB Robotics\ and will also be the current one. However any directory in the structure can be set up as the current system directory in the Create New System window or Select System window. File system requirements 170 Directory view Folder "System 1" xx0100000260 xx0100000261 The system directory must hold these files and directories to allow software installation: • key.id (encrypted key file for the actual controller) • program.id (file with paths to selected programs in the media pool) • A syspar directory containing .cfg files to be included in the software installation procedure. All system parameter files, included when creating a system with RobInstall, are stored in this syspar directory as shown in the table in section "System Pool Directory". • A directory called Home. In this home directory the user can include any file or files, which should be downloaded to the controller together with the operating system. Such files will then be placed in the home directory of the system in the controller. A 3HAC 16245-1 9 System directory structure 9.0.3 File structure in the robot controller mass storage memory 9.0.3 File structure in the robot controller mass storage memory Files in root directory, hd0a The root directory of the mass storage memory is called hd0a. This includes several components: File name Description E.g. 3HAC6811-1.00 Control system package, named as an article number bin BootImage code BootRom.sys System configuration and description file for the mass storage memory MC.cfg Network configuration for the main computer ctrl.bin Holds e.g. revolution counter values system.dir Holds information on the current system system directories Different systems stored in the mass storage memory Directories and subdirectories Each system directory holds a number of subdirectories, defining for instance language, options, robots, etc. "Home" directory The system directory is the "home" directory for the system. When using the address "home:" in the RAPID program, this directory will be addressed. "Bin" subdirectory The subdirectory bin, containing the storage area for all system data, e.g. at power break. This means that at warm start, in addition to restoring the operating system from the control system package, all system data is restored from this directory and reloaded into the working memory. Never change these directories! Never delete or change the \bin or BootRom.sys directories in the root directory. If this is done, the controller cannot be restarted and the mass storage memory will be impossible to use. 3HAC 16245-1 A 171 9 System directory structure 9.0.4 Preparation of S4Cplus software to be installed 9.0.4 Preparation of S4Cplus software to be installed Illustration Media pool S ys tem Pack in /3haxbbbb-1.nn *.* s ignature no S ys tem pool E xt Option in /3haxcccc-1.nn *.* relkey.txt E xternal option from dis k or CD-R OM ys tem Pack from obotWare CD-R OM Created files key.id program.id My s ys tem /s ys tem_n key.id program.id keys tr.txt /s ys par *.cfg Ins erted key s trings are s aved in keys tr.txt R obotWare keys trings define the options to be included from the S ys tem Pack they belong to and E xt opt keys trings define added external option packages . All keys mus t have the s ame s erial number. xx0100000262 Files to be prepared 172 The list details what happens during preparation: • RobInstall creates a file named Key.id from the key strings specifying the options to be installed from the System Pack and the external option programs to be installed. • Unless deselected in RobInstall, the latest revision of the System Pack and External Option Programs is selected as default (see section "Change options or system pack revisions"). • These are copied from the media pool and concatenated into one target file that also holds the key.id and the syspar directory. This may then be downloaded to the controller via Ethernet or a set of diskettes. The target file is temporarily stored in the system directory before downloading or creating diskettes. A 3HAC 16245-1 9 System directory structure 9.0.5 Handling mass memory storage capacity 9.0.5 Handling mass memory storage capacity General In some cases it is very important that there is enough free space in the mass storage memory, before attempting to download new system software. How to check its capacity, and if required increase it, is detailed below. A manual check on the free space can be done in one of the following ways: Checking storage capacity from the Teach Pendant Unit Checking storage capacity through connection to the MC/CONSOLE port 1. Press the button Miscellaneous to select Service window . 2. Select Storage Capacity from the System Info menu. The Mass Storage Memory is called hd0a . 1. Connect a console to the MC/CONSOLE outlet on the controller and execute the command dosFsShow . There should always be at least 25 Mb free disk space on the controller mass storage memory before attempting to download a new system. For information on how to increase storage capacity, see below! Increasing storage capacity If the capacity of the mass storage memory is less than 25 Mb when a new controller system is to be downloaded, storage memory must be released by removing old systems from the mass storage memory. This can be done in one of the following ways: 1. Boot up on the system you would like to remove and then make a C-START (see section "C-start"). 2. Use the FileManager in the Teach Pendant Unit, see User’s Guide - File Manager, for more information on how to use the FileManager. 3. Use a third-party "ftp" client (like FTPVoyager supplied on the RobotWare CD). Removing systems using the FileManager or FTP-client may be hazardous since the \bin and BootRom.sys directories the must be kept intact. Proceed with utmost care to avoid accidentally removing such files or directories! 3HAC 16245-1 A 173 9 System directory structure 9.0.5 Handling mass memory storage capacity 174 A 3HAC 16245-1 10 Calibration 10.1.1 Types of calibration procedures Chapter 10: Calibration Section 10.1: General 10.1.1 Types of calibration procedures When to calibrate Calibrate the measurement system carefully if any of the resolver values has been changed. This may occur when parts affecting the calibration position have been replaced on the robot. Calibrate the system roughly as detailed in section Updating the revolution counter on page 183 if the contents of the revolution counter memory are lost. This may occur when: 3HAC 16245-1 • the battery is discharged • a resolver error occurs • the signal between a resolver and measurement board is interrupted • a robot axis has been moved with the control system disconnected A 175 10 Calibration 10.1.2 How to calibrate the robot system 10.1.2 How to calibrate the robot system General This section provides an overview of the procedure required when calibrating the robot system. Many of the steps in the procedure are detailed in other sections to which references are given. Procedure Step 176 Action Illustration 1. Install the robot. Detailed in the "Installation Manual". 2. Check that all required hardware is available for calibrating the robot. Required hardware is specified in the calibrating procedures for each axis. 3. Connect the calibration equipment to the robot controller and initialize it. Specified in Initialization of calibration pendulum on page 186. 4. Manually, run the robot axes to be caliUse the calibration scales fitted to each brated to a position close to the correct cal- robot axis to locate this position. ibration position. 5. Start the calibration program. Detailed in Calibration procedure on TPU on page 185. 6. Calibrate each axis or several axes in a sequence. Detailed in each axis’ calibration instruction. 7. Verify that the calibration was successfully Detailed in Post calibration procedure carried out. on page 198. A 3HAC 16245-1 10 Calibration 10.1.2 How to calibrate the robot system Additional information In addition to the basic calibration procedure detailed above, a number of calibration related actions may be performed: Action Detailed in section: How to update the robot revolution counter without per- Updating the revolution counter on forming a complete calibration page 183 How to manually check the current calibration position Checking the calibration position on page 181 An alternative calibration position for axis 1 may be defined Alternative calibration position on page 199 How to perform the alternative calibration Alternative calibrating on page 200 How to change to a new offset value for the alternative New calibration offset, axis 1 on calibration position page 202 How to retrieve a new calibration offset for the alterna- Retrieving offset values on page tive calibration position 203 How to change to a new calibration position 3HAC 16245-1 A New calibration position, axis 1 on page 201 177 10 Calibration 10.1.3 Calibration, prerequisites 10.1.3 Calibration, prerequisites General The calibration procedure may be described as comparing the direction of two sensors, the reference sensor and the calibration sensor, while running the robot to its calibration position, thus reducing the sensor difference to close to zero. All article numbers of relevant equipment are specified in their instructions respectively. Peripheral equipment The robot must be free from any peripheral equipment during calibration. Fitted welding guns and similar will cause erroneous calibration positions. Calibration order The axes must be adjusted in increasing sequence, i.e. 1 - 2 - 3 - 4 - 5 - 6. Calibration movement direction When calibrating, the axis must consistently be run towards the calibration position in the same direction, in order to avoid position errors caused by backlash in gears etc. Positive directions are shown in the figure below. This is normally handled by the robot calibration software. NOTE The figure shows an IRB 7600, but the positive direction is the same for all robots! 6+ 4+ 5+ 3+ 2+ 1+ xx0200000089 Location of sensors The positions where the calibration sensor and reference sensor should be fitted during calibration, are specified in Calibration sensor mounting positions on page 188. Location of calibration marks/ plates Where to find the calibration sensor and reference sensor respectively during calibration in Calibration scales on page 194. 178 A 3HAC 16245-1 10 Calibration 10.1.4 Calibration pendulum kit, contents 10.1.4 Calibration pendulum kit, contents General The calibration pendulum kit contains all required hardware to calibrate all robot models (except IRB 6400R) using the calibration pendulum method. These kits may be rented from ABB at this time, but not purchased. Contents of calibration pendulum kit 3HAC 15716-1 3HAC 16245-1 Qty Contents Art. no. 2 Inclinometer, Wyler Zerotronic 3HAC 12837-7 1 Cable set Wyler 3HAC 15144-1 1 Leveltronic NT/41 3HAC 15732-1 1 Calibration pendulum 3HAC 4540-1 1 Turning disk adapter 3HAC 16423-1 May be turned both ways to fit IRB 140, IRB 1400, IRB 2400 and IRB 4400. Includes all guide pins and attachment screws. Also see illustration below! 1 Adapter, turning disk 3HAC 14034-1 Fits IRB 6600 and IRB 7600 Includes all guide pins and attachment screws. Also see illustration below! 4 Batteries For battery supply of "Leveltronic NT/41" 1 Thread tap, M8 For repairing any damaged protective cover attachment holes 5 Protective covers and attachment screws For replacing any damaged protective covers 1 Location pin 3HAC 14137-1 58 mm long For IRB 6600 and IRB 7600, axis 1 1 Location pin 3HAC 14137-2 68 mm long For IRB 140, IRB 1400, IRB 2400 and IRB 4400, axis 1 1 User documentation A Rem. All required cables 179 10 Calibration 10.1.4 Calibration pendulum kit, contents Illustration, turning disk adapter May be turned both ways to fit IRB 140, IRB 1400, IRB 2400 and IRB 4400. xx0200000276 Illustration, adapter turning disk A Guide pin, 8 mm B Guide pin, 6 mm C Screw, M10 D Screw, M6 Fits IRB 6600 and IRB 7600 xx0200000278 180 A Locating shaft B Hand wheel C Turning disk, robot A 3HAC 16245-1 10 Calibration 10.2.1 Checking the calibration position Section 10.2: Preliminaries 10.2.1 Checking the calibration position General Using the program CALxxxx in the system software 3HAC 16245-1 Check the calibration position before any programming of the robot system can begin. This may be done in one of two ways: • Using the program CALxxxx in the system software (xxxx signifying the robot type; IRB xxxx) • Using the Jogging window on the teach pendant Step Action Button 1. Run the program \SYSTEM\UTILITY\SERVICE\CALIBRAT\CALxxxx in the system and follow the instructions displayed on the teach pendant. 2. Switch to MOTORS OFF when the robot stops. Check that the calibration marks for that particular axis align correctly. If they do not, update the revolution counters. 3. Check that resolver offset values in the system parameters match those on the parameter disk delivered with the robot or those established when calibrating the robot (after a repair, etc). A Calibration marks shown in Calibration scales on page 194. Detailed in Updating the revolution counter on page 183. 181 10 Calibration 10.2.1 Checking the calibration position Using the Jogging window on the teach pendant Step Action Illustration 1. Open the Jogging window. 2. Choose running axis-by-axis. 3. Manually, run the robot axis to a position where the resolver offset value read, is equal to zero. 4. Check that the calibration marks for that particular axis align correctly. If they do not, update the revolution counters ! xx0100000195 xx0100000196 182 A Shown in Calibration scales on page 194. Detailed in Updating the revolution counter on page 183. 3HAC 16245-1 10 Calibration 10.2.2 Updating the revolution counter 10.2.2 Updating the revolution counter Manually running the manipulator to the calibration position This section details the first step when updating the revolution counter; manually running the manipulator to the calibration position. Step 3HAC 16245-1 Action Illustration 1. Select axis-by-axis motion mode 2. Press the enabling device on the teach pendant and, using Shown in Calibration the joystick, move the robot manually so that the calibra- scales on page 194. tion marks lie within the tolerance zone. 3. Note that axis 6 does not have any mechanical stop and can thus be calibrated at the wrong faceplate revolution. Do not operate axis 6 manually before the robot has been calibrated. 4. When all axes have been positioned as above, store the revolution counter settings using the Teach Pendant Unit as detailed below: A 183 10 Calibration 10.2.2 Updating the revolution counter Storing the revolution counter setting This section details the second step when updating the revolution counter; storing the revolution counter setting. If a revolution counter is incorrectly updated, it will cause incorrect robot positioning, which in turn may cause damage or injury! Step 1. Action Illustration Press the button "Miscellaneous". xx0100000194 2. Select the Service window by pressing ENTER. xx0100000200 3. Select Calibration from the View menu. The Calibration window appears. xx0100000201 4. Select the desired unit and choose Rev Counter Update from the Calib menu. The Revolution Counter Update window appears. 5. Select the desired axis and press Incl to include it (it will be marked with an x) or press All to select all axes. 6. Press OK when all axes that are to be updated are marked with an x. CANCEL returns to the Calibration window. 7. Press OK again to confirm and start the update. CANCEL returns to the Revolution Counter Update window. 8. At this point, it is recommended that the revolution counter values are saved to a diskette. Not required. 9. Recheck the calibration position. Detailed in Checking the calibration position on page 181 xx0100000202 184 A 3HAC 16245-1 10 Calibration 10.2.3 Calibration procedure on TPU 10.2.3 Calibration procedure on TPU General This section details how to use the Teach Pendant Unit (TPU) when calibrating the robot using the calibration pendulum method. Procedure Step Action Illustration 1. Press the "Program" button on the TPU. 2. Select "Special", and then "Call service routine". 3. Start the program: "Calpendulum.rutin". 4. Select the required calibration procedure by pressing "START". 5. Enter the value for your choice of which robot axes to calibrate. Press OK . xx0300000009 xx0200000188 xx0200000190 Default value: All axes In this example, axis 1 was selected. 3HAC 16245-1 6. Press "0" to acknowledge the selection made. Press OK . 7. Proceed to calibrate the individual robot axes. Detailed in the calibration instructions for the robot axes. A 185 10 Calibration 10.2.4 Initialization of calibration pendulum 10.2.4 Initialization of calibration pendulum General Whenever calibration pendulum is used for calibrating the robot, the equipment must first be initialized as detailed below. The Levelmeter 2000 is shown for reference below: + 0000000 00000 Port/Sensor ° oo GON A A°oo mRAD mm/m DEG "1/12" "1/10" "/REL" mm/REL A 50 B BATT LEVELMETER 2000 + ON/MODE ZERO SELECT ENTER SEND/ESC HOLD WYLER A B OUT C C D xx0200000126 Overview A Connect sensor A here B Connect sensor B here C Connect SIO 1 in controller here D Selection pointer E Measuring unit Shown below is an outline of how to initialize the Levelmeter 2000. Detailed procedures are specified in the manual supplied by the manufacturer. Step 186 Action Info/Illustration 1. Make sure the Levelmeter 2000 has reached normal operating temperature before connecting it to anything. Also switch the power on for a couple of minutes before operating the unit. 2. Connect the Levelmeter 2000 to the COM2 port in the Shown in the figure in seccontrol cabinet through the connector marked OUT . tion General on page 186. 3. Connect sensors A and B. 4. Calibrate the robot! A Detailed in Connection of sensors on page 187. 3HAC 16245-1 10 Calibration 10.2.4 Initialization of calibration pendulum Address Step 1. Action Info/Illustration Make sure the sensors have different Detailed in the documentation supplied addresses. Any addresses will do, as long by sensor manufacturer. as they differ from each other. Found in the calibration kit box. Connection of sensors Step Result 3HAC 16245-1 Action Info/Illustration 1. Connect the sensor to the Sensor connection points. Marked A and B . Shown in the figure in section General on page 186. 2. Press ON/MODE . 3. Press ON/MODE until the dot flashes under SENSOR . 4. Press ENTER. 5. Press ZERO/SELECT arrows until a flashing "A B" is shown. 6. Press ENTER. Wait until the "A B" flashes again. 7. Press ENTER. The Levelmeter 2000 is now initialized and ready for service. A 187 10 Calibration 10.3.1 Calibration sensor mounting positions Section 10.3: Calibration 10.3.1 Calibration sensor mounting positions Introduction This section specifies the mounting positions and directions of all calibration sensors on all robot systems using the Calibration Pendulum method. Additional information on calibration, alternative calibration positions etc, may be found in the Installation Manual. Reference sensor The illustrations below show the mounting position and direction for the reference sensor : IRB 6600, IRB 7600 A xx0200000183 A 188 Calibration pendulum in reference sensor position NOTE! The pendulum is only fitted in one position at a time! A 3HAC 16245-1 10 Calibration 10.3.1 Calibration sensor mounting positions Axis 1 The illustrations below show the mounting position and direction for the calibration sensor, axis 1: IRB 6600, IRB 7600 B A C xx0200000177 3HAC 16245-1 A Calibration pendulum NOTE! The pendulum is only fitted in one position at a time! B Calibration pendulum attachment screw C Locating pin A 189 10 Calibration 10.3.1 Calibration sensor mounting positions Axis 2 The illustrations below show the mounting position and direction for the calibration sensor, axis 2: IRB 6600, IRB 7600 A xx0200000178 A 190 Calibration pendulum, axis 2 A 3HAC 16245-1 10 Calibration 10.3.1 Calibration sensor mounting positions Axis 3 The illustrations below show the mounting position and direction for the calibration sensor, axis 3: IRB 6600, IRB 7600 A xx0200000179 A Calibration sensor, axis 3 NOTE! The pendulum is only fitted in one position at a time! NOTE! The IRB 7600/2.3/500 version requires a slightly different sensor mounting position than the other versions, the sensor being turned 90°. This is shown in the following figure. A xx0300000016 Any special considerations to be taken when calibrating this robot version is detailed in section Calibrating axes 3-4, IRB 7600/2.3/500 on page 197. 3HAC 16245-1 A 191 10 Calibration 10.3.1 Calibration sensor mounting positions Axis 4 The illustrations below show the mounting position and direction for the calibration sensor, axis 4: IRB 6600, IRB 7600 A xx0200000179 A Calibration sensor, axis 4 NOTE! The pendulum is only fitted in one position at a time! NOTE! The IRB 7600/2.3/500 version requires a slightly different sensor mounting position than the other versions, the sensor being turned 90°. This is shown in the figure below. A xx0300000016 Any special considerations to be taken when calibrating this robot version is detailed in section Calibrating axes 3-4, IRB 7600/2.3/500 on page 197. 192 A 3HAC 16245-1 10 Calibration 10.3.1 Calibration sensor mounting positions Axis 5 The illustrations below show the mounting position and direction for the calibration sensor, axis 5: IRB 6600, IRB 7600 A B xx0200000180 Axis 6 A Calibration sensor, axis 5 NOTE! The pendulum is only fitted in one position at a time! B Adapter, turning disk The illustrations below show the mounting position and direction for the calibration sensor, axis 6: IRB 6600, IRB 7600 A B xx0200000180 3HAC 16245-1 A Calibration sensor, axis 6 NOTE! The pendulum is only fitted in one position at a time! B Adapter, turning disk A 193 10 Calibration 10.3.2 Calibration scales 10.3.2 Calibration scales Introduction This section specifies the calibration scale positions for all robot models. IRB 6600 The illustration below show the calibration scale positions: A B C xx0200000176 IRB 7600 A Sync scale, axis 1 B Sync scale, axes 2-5 C Sync scale, axis 6 The illustration below show the calibration scale positions: A B C xx0100000198 194 A Sync scale, axis 1 B Sync scale, axes 2-5 C Sync scale, axis 6 A 3HAC 16245-1 10 Calibration 10.3.3 Calibration, all axes 10.3.3 Calibration, all axes General This section is valid for all robot models using the calibration pendulum procedure except IRB 6400R. It details how to perform the actual fine calibration of each axis using special calibration equipment. The position to fit calibration sensors differ between different models and different axes. Sensor mounting positions Equipment Article no. Note Calibration pendulum, complete set 3HAC 15716-1 Contains all hardware required for calibration of all robot versions except IRB 6400R. The contents are specified in Calibration pendulum kit, contents on page 179. Turning disk adapter 3HAC 16423-1 May be turned both ways to fit IRB 140, IRB 1400, IRB 2400 and IRB 4400. Included in the complete set. Adapter, turning disk 3HAC 14034-1 Fits IRB 6600 and IRB 7600 Included in the complete set. Isopropanol 1177 1012-208 For cleaning the sensor attachment points The position of the calibration sensors are shown in Calibration sensor mounting positions on page 188. Procedure Step 3HAC 16245-1 Action Illustration 1. Run the robot manually to the calibration position of the axis to be calibrated. 2. Make a rough calibration. 3. Turn the calibration equipment on, to allow it to reach operating temperature and stabilize for a couple of minutes. 4. Remove any protective covers from the reference sensor, calibration sensor and locating pin attachment points. The same calibration pendulum is used as a "calibration sensor" and as a "reference sensor" depending on its function at the time. In the instruction below, the pendulum will be called "calibration sensor" or reference sensor" depending on the function. 5. Clean the reference sensor, calibration sensor and locating pin attachment points with isopropanol . Art. no. specified in section General on page 195. 6. Valid for axis 1 only! Fit the locating pin to the manipulator base. Make sure the attachment surface is clean and free from any nicks and burrs. Shown in Calibration sensor mounting positions on page 188. A Detailed in Updating the revolution counter on page 183. 195 10 Calibration 10.3.3 Calibration, all axes Step 7. Action Illustration Connect the measurement cable from the calibration sensor to the Levelmeter 2000 unit. + 00 0 0 0 0 0 0 0 0 0 ° oo GON Port/Sensor A° o o "1/12" mRAD "1/10" mm/m "/REL" DEG mm/REL A 50 A B B AT T LE V E LM E T E R 2 00 0 + Z E R O O N /M O D E S E LE C T E N TE R S E N D /E S C H O L D W YL ER A B O U T C C D xx0200000126 • A: Connect sensor A here • B: Connect sensor B here • C: Connect SIO 1 in controller here • D: Measuring unit • E: Selection pointer 8. Start the calibration program from the TPU, The position where to fit the referand follow the instructions given, incl. fitting ence sensor and calibration sensor the calibration sensor when requested. respectively, are shown in CalibraNOTE! After fitting the sensor on the manipu- tion sensor mounting positions on page 188. lator as specified on the TPU, clicking OK NOTE that no additional tool is will start manipulator movement ! Make sure no personnel is within the working required for fitting the calibration pendulum for axes 1-3! range of the robot! Fitting the pendulum to the turning disk requires an adapter (included in the complete set). NOTE that there are two adapters! Article number specified in section General on page 195. The way of handling the calibration program prior to the actual calibration of each axis is detailed in Calibration procedure on TPU on page 185. 9. Click OK . A number of menus will flash by briefly on the TPU, but no action is required on behalf of the operator until a specific action is displayed. 10. Confirm the position of all calibrated axes Detailed in Post calibration procewhen the calibration has been performed sat- dure on page 198. isfactorily. 11. Disconnect all calibration equipment and refit all protective covers. 196 A 3HAC 16245-1 10 Calibration 10.3.4 Calibrating axes 3-4, IRB 7600/2.3/500 10.3.4 Calibrating axes 3-4, IRB 7600/2.3/500 General Due to the fact that the upper arm tube is slightly shorter on the version than on others, the calibration sensor position on the upper arm is changed. This applies to calibrating axes 3 and 4 of the IRB 7600/2.3/500 only. A xx0300000020 A Cable holder attachment point Procedure Step 3HAC 16245-1 Action Info/Illustration 1. Remove any cable holders by unscrew- Shown in the figure in section General on ing their respective attachment screws. page 197. This is to facilitate fitting the calibration sensor. 2. Perform the calibration procedure as with any other version. The system software automatically compensates for the sensor being turned 90°. A 197 10 Calibration 10.4.1 Post calibration procedure Section 10.4: After calibration 10.4.1 Post calibration procedure General Perform the following procedure after calibrating any manipulator axes. The procedure is intended to verify that all calibration positions are correct. Procedure Step 198 Action Illustration 1. Run the calibration home position program twice. Do not change the position of the manipulator axes after running the program! Detailed in Checking the calibration position on page 181. 2. Check all calibration positions . Detailed in Checking the calibration position on page 181. 3. Repeat the check as above. 4. Adjust the calibration marks when the calibration is done. 5. The system parameters will be saved to the storage memory at power off. 6. Change the values on a new label and stick it on top of the label located on the lower arm. 7. Remove any calibration equipment from the manipulator. A Shown in Calibration scales on page 194. 3HAC 16245-1 10 Calibration 10.5.1 Alternative calibration position Section 10.5: Alternative calibration 10.5.1 Alternative calibration position General The manipulator may be calibrated in any of three positions. The regular calibration instructions detailed for each axis are intended for calibration position 0, i.e. the normal position. Calibration instructions for positions Right (1) and Left (2) are detailed in Alternative calibrating on page 200. Illustration The illustration shows the three available calibrating positions. Y A B X C xx0100000258 3HAC 16245-1 A Calibration position 2 +90°, left (1.570796) B Calibration position 0 C Calibration position 1 -90°, right (-1.570796) A 199 10 Calibration 10.5.2 Alternative calibrating 10.5.2 Alternative calibrating General The manipulator may be calibrated in any of three positions, shown in Alternative calibration position on page 199. Procedure Step 200 Action Illustration 1. Calibrate the robot in position 0 for all axes. Set an alternative calibration position before installation if the final installation makes it impossible to reach the calibration 0 position. 2. Run the calibration program CALxxx in the system\SYSTEM\UTILITY\SERVICE\CALIBRAT\. (xxx = robot version, e.g. CAL6400) 3. Select Normal position, and check the calibration marks for each axis. 4. Run the calibration program again and select the desired calibration position (Left or Right) as shown in Alternative calibration position on page 199. 5. Change to the new calibration offset for axis 1, as detailed in New calibration offset, axis 1 on page 202. 6. Note the new calibration offset on the label, located on the frame to the left of motor axis 1 (remove the cover between axes 2 and 3). The new calibration offset values can be found as detailed in Retrieving offset values on page 203. 7. Change to the new calibration position on axis 1 as detailed in New calibration position, axis 1 on page 201. 8. Restart the robot by selecting Restart from the File menu. 9. Move the sync marks for axis 1 on the base to the new position. 10. The system parameters will be saved to the storage memory at power off. A 3HAC 16245-1 10 Calibration 10.5.3 New calibration position, axis 1 10.5.3 New calibration position, axis 1 Procedure Use this instruction to change to a new calibration position for axis 1 during definition of a new calibration position. Step 1. Action Illustration Press the "Miscellaneous" button xx0100000194 2. Select the System parameters window by pressing ENTER. 3. Select Manipulator from the Topics menu. 4. Select Arm from the Types menu. 5. Select axis 1. 6. Change Cal pos to 1.570796 or -1.570796 depending on the selected calibration position. The angle is measured in radians as shown in Alternative calibration position on page 199. xx0100000200. 3HAC 16245-1 A 201 10 Calibration 10.5.4 New calibration offset, axis 1 10.5.4 New calibration offset, axis 1 Procedure Use this instruction when changing to a new calibration offset for axis 1 during definition of a new calibration position. Step Action Illustration 1. Press the "Miscellaneous" button. 2. Select the Service window by pressing ENTER. xx0100000194 xx0100000200 3. Select Calibration from the View menu. The calibration window appears. 4. Select Calibrate from the Calib menu. 5. Select axis 1 (no other axes). 6. Confirm by pressing OK twice. xx0100000201 202 A 3HAC 16245-1 10 Calibration 10.5.5 Retrieving offset values 10.5.5 Retrieving offset values Procedure Use this instruction when retrieving new offset values for axis 1 during definition of a new calibration position. Step Action Illustration 1. Press the "Miscellaneous" button. 2. Select the System parameters window by pressing ENTER. 3. Select Motor from the Types menu. 4. Select axis 1 and press ENTER. 5. Note the Cal offset value. xx0100000194 xx0100000200 xx0100000200 3HAC 16245-1 A 203 10 Calibration 10.5.5 Retrieving offset values 204 A 3HAC 16245-1 11 Decommissioning 11.0.1 Balancing device, IRB 7600 and IRB 6600/6650 Chapter 11: Decommissioning 11.0.1 Balancing device, IRB 7600 and IRB 6600/6650 General This information is valid for all versions of IRB 6600/6650 as well as IRB 7600! There is much energy stored in the balancing device. Therefore a special procedure is required to dismantle it. The coil springs inside the balancing device exert a potentially lethal force unless dismantled properly. Required equipment Equipment, etc. Spare part no. Art. no. Standard toolkit 3HAC 15571-1 Note The contents are defined in section Standard toolkit on page 22! Cutting torch For opening housing and cutting coils Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. These procedures include references to the tools required. Do not under any circumstances, deal with the balancing device in any other way than that detailed in the product documentation! For example, attempting to open the balancing device is potentially lethal! Procedure The instruction below details how to cut open the balancing device housing and removing the tension in the coil springs before opening the device. Step 3HAC 16245-1 Action Info/Illustration 1. Remove the balancing device from the manipulator. Detailed in "Removal of balancing device" in the Repair Manual. 2. Place it on a workbench or similar. Make sure it is clamped in position with a vice or similar. A 205 11 Decommissioning 11.0.1 Balancing device, IRB 7600 and IRB 6600/6650 Step 3. Action Info/Illustration Open a hole in the side of the housing as Use a cutting torch. shown in the figure. 450-500 mm 450-500 mm 450 mm = IRB 6600 500 mm = IRB 7600 xx0200000082 4. 206 Cut the coils of the three springs inside the housing as specified below: • Outer spring: cut at least five (5) coils! • Middle spring: cut at least four (4) coils! • Inner spring: cut at least four (4) coils! 5. After double-checking the number of coils cut, remove the end cover of the balancing device. 6. Dismantle the balancing device and sort its parts for the recycling plant. A Use a cutting torch. 3HAC 16245-1 Repair Manual, part 1 Industrial Robot IRB 6600 - 225/2.55 IRB 6600 - 175/2.8 IRB 6600 - 175/2.55 IRB 6650 - 200/2.75 IRB 6650 - 125/3.2 M2000A Repair Manual, part 1, IRB 6600/6650, M2000A 3HAC 16247-1 Revision A The information in this manual is subject to change without notice and should not be construed as a commitment by ABB. ABB assumes no responsibility for any errors that may appear in this manual. In no event shall ABB be liable for incidental or consequential damages arising from use of this manual and products described herein. This manual and parts thereof must not be reproduced or copied without ABB’s written permission, and contents thereof must not be imparted to a third party nor be used for any unauthorized purpose. Contravention will be prosecuted. Additional copies of this manual may be obtained from ABB at its then current charge. ©Copyright 2003 ABB All rights reserved. ABB Automation Technology Products AB Robotics SE-721 68 Västerås Sweden Table of Contents 0.0.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 0.0.2 Product Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 Chapter 1: Safety, service 5 1.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Section 1.1: General information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1.1.1 Safety, service - General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 1.1.2 Limitation of Liability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 1.1.3 Related information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 Section 1.2: Safety risks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.1 Safety risks related to gripper. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.2 Safety risks related to tools/workpieces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.3 Safety risks related to pneumatic/hydraulic systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.4 Safety risks during operational disturbances . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.5 Safety risks during installation and service . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 1.2.6 Risks associated with live electric parts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 Section 1.3: Safety actions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.1 Safety fence dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.2 Fire extinguishing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.3 Emergency release of the manipulator’s arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.4 Brake testing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.5 Risk of disabling function "Reduced speed 250 mm/s". . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.3.6 Safe use of the Teach Pendant Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.3.7 Work inside the manipulator’s working range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 Chapter 2: Reference information 13 2.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13 Section 2.1: Reference information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 2.1.1 Applicable Safety Standards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 2.1.2 Screw joints . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15 2.1.3 Weight specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17 2.1.4 Standard toolkit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18 2.1.5 Special tools, IRB 6600/6650/7600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19 2.1.6 Performing a leak-down test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21 2.1.7 Lifting equipment and lifting instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22 Chapter 3: Repair activities, manipulator 23 3.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 Section 3.1: Complete manipulator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24 3.1.1 Removal of cable harness. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24 3.1.2 Refitting of cable harness. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .30 3.1.3 Removal of complete arm system . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .36 3.1.4 Refitting of complete arm system . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .39 Section 3.2: Upper arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .42 3.2.1 Removal of turning disk. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .42 3.2.2 Refitting of turning disk . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .44 3.2.3 Removal of complete wrist unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .47 3.2.4 Refitting of complete wrist unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .50 3.2.5 Removal of upper arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .54 3.2.6 Refitting of upper arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .57 Section 3.3: Lower arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .62 3.3.1 Removal of complete lower arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .62 3.3.2 Refitting of complete lower arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .67 3HAC 16247-1 i Table of Contents Section 3.4: Frame and base . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 3.4.1 Removal of SMB related equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 3.4.2 Refitting of SMB related equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75 3.4.3 Removal of brake release unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 3.4.4 Refitting of brake release unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 3.4.5 Removal of balancing device. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82 3.4.6 Refitting of balancing device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 3.4.7 Unloading the balancing device. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89 3.4.8 Restoring the balancing device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91 Section 3.5: Motors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 3.5.1 Removal of motor, axis 1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 3.5.2 Refitting of motor, axis 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 3.5.3 Removal of motor axis 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 3.5.4 Refitting of motor axis 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 3.5.5 Removal of motor, axis 3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 3.5.6 Refitting of motor, axis 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 3.5.7 Removal of motor, axis 4. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109 3.5.8 Refitting of motor, axis 4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 111 3.5.9 Removal of motor, axis 5. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114 3.5.10 Refitting of motor, axis 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 3.5.11 Removal of motor, axis 6. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120 3.5.12 Refitting of motor, axis 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122 Section 3.6: Gearboxes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125 3.6.1 Removal of gearbox, axis 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125 3.6.2 Refitting of gearbox, axis 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128 3.6.3 Removal of gearbox axis 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132 3.6.4 Refitting of gearbox axis 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137 3.6.5 Removal of gearbox, axis 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142 3.6.6 Refitting of gearbox, axis 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145 3.6.7 Removal of gearbox, axis 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 149 3.6.8 Refitting of gearbox, axis 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151 Chapter 4: Repair activities, controller cabinet 155 4.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155 Section 4.1: Complete controller cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156 4.1.1 Replacement of battery unit, controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156 4.1.2 Replacement of I/O and gateway units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 158 4.1.3 Replacement of bleeder resistor. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160 4.1.4 Putting the computer unit in the service position. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 162 4.1.5 Replacement of mass storage memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165 4.1.6 Replacement of internal cooling fan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168 4.1.7 Replacement of drive units and rectifier . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171 4.1.8 Replacement of system fan unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 174 4.1.9 Replacement of power supply unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 176 4.1.10 Replacement of Peltier Cooler power supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178 Chapter 5: Appendix 1: Part Lists 181 5.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 181 Section 5.1: Part List, Manipulator IRB 6600/6650 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 182 5.1.1 Mechanical stop ax 1, 3HAC 12812-2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 183 5.1.2 Base incl frame ax 1, 3HAC 12685-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 183 5.1.3 Axis 3-4, (robot v. 175/2.55), 3HAC 10746-3. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 184 5.1.4 Axis 3-4, (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75), 3HAC 10746-1 . . . . . . . . . . . . . 184 5.1.5 Axis 3-4, Foundry (robot v. 175/2.55), 3HAC 10746-5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 185 5.1.6 Axis 3-4, Foundry (robot v. 225/2.25, 175/2.8, 125/3.2, 200/2.75), 3HAC 10746-4 . . . . . . 185 ii 3HAC 16247-1 Table of Contents 5.1.7 Wrist (robot v. 175/2.55) 3HAC 8114-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .189 5.1.8 Wrist (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-3 . . . . . . . . . . . . . . . . . .189 5.1.9 Wrist Foundry (robot v. 175/2.55) 3HAC 8114-6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .189 5.1.10 Wrist Foundry (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-5 . . . . . . . . . .190 5.1.11 Material set manipulator, 3HAC 13263-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .194 5.1.12 Mtrl.set ax 1-2, 3HAC 13264-1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .195 5.1.13 Mtrl set balancing device, 3HAC 13265-1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .198 5.1.14 Arm extension set, 250 mm, 3HAC 12311-4. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .199 5.1.15 Arm extension set, 450 mm, 3HAC 12311-5. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .199 Chapter 6: Appendix 2: Foldouts 201 6.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .201 6.0.2 Base incl. Frame. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .203 6.0.3 Frame-Lower arm 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .205 6.0.4 Frame-Lower arm 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .207 6.0.5 Upper arm. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .209 6.0.6 Wrist complete . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .211 3HAC 16247-1 iii Table of Contents iv 3HAC 16247-1 0.0.1 Overview 0.0.1 Overview About This Manual This information product is a manual containing instructions for repairing the complete robot system, mechanically as well as electrically. Usage This manual should be used during repair work. Who Should Read This Manual? This manual is intended for: Prerequisites Organization of Chapters • repair personnel in the user's organization. • repair personnel in other organizations. The reader should... • be a trained repair craftsman • have the required knowledge of mechanical repair work OR • have the required knowledge of electrical repair work. The information product is organized in the following chapters: Chapter Contents 1 Safety 2 Reference information 3 Manipulator 4 Controller 6 Appendix References Reference Document Id Circuit Diagrams, Manipulator 3HAC 13347-1 Circuit Diagrams, Controller 3HAC 14189-2 Revisions Revision Description 0 First edition A 3HAC 16247-1 • Various corrections in text and in figures due to reconstructions, new spare part numbers, new tools, etc. • Manual completed with references to pagenumbers and numbering of sections (manipulator sections). • Manual completed with version IRB 6650. A 1 0.0.1 Overview 2 A 3HAC 16247-1 0.0.2 Product Documentation 0.0.2 Product Documentation General The complete product documentation kit for the robot, including controller, manipulator and any hardware option, consists of the manuals listed below: Installation and Commissioning Manual The Installation and Commissioning Manual contains the following information: Repair Manual Maintenance Manual • Safety, Service • Reference Information • Unpacking • On-site Installation • Electrical connections • Start-up • Installation of controller software • System directory structure • Calibration • If there is any, model specific information The Repair Manual contains the following information: • Safety, Service • Reference Information • Remove/Refitting instructions for all manipulator details considered spare parts • Remove/Refitting instructions for all controller cabinet details considered spare parts • If there is any, model specific information The Maintenance Manual contains the following information: • Safety, Service • Reference Information • Maintenance schedules • Instructions for all maintenance activities specified in the maintenance schedule, for example cleaning, lubrication, inspection etc. • If there is any, model specific information The information is generally divided into separate chapters for the manipulator and the controller, respectively. Software manuals The software documentation consists of a wide range of manuals, ranging from manuals for basic understanding of the operating system to manuals for entering parameters during operation. A complete listing of all available software manuals is available from ABB Robotics. 3HAC 16247-1 A 3 0.0.2 Product Documentation Hardware option manual Each hardware option is supplied with its own documentation. Each document set contains the types of information specified above: • Installation information • Repair information • Maintenance information In addition, spare part information is supplied for the complete option. 4 A 3HAC 16247-1 1 Safety, service 1.0.1 Introduction Chapter 1: Safety, service 1.0.1 Introduction Definitions This chapter details safety information for service personnel i.e. personnel performing installation, repair and maintenance work. Sections The chapter "Safety, service" is divided into the following sections: 1. General information contains lists of: • Safety, service -general • Limitation of liability • Referenced documents 2. Safety risks lists dangers relevant when servicing the robot system. The dangers are split into different categories: • Safety risks related to gripper/end effector • Safety risks related to tools/workpieces • Safety risks related to pneumatic/hydraulic systems • Safety risks during operational disturbances • Safety risks during installation and service • Risks associated with live electric parts 3. Safety actions details actions which may be taken to remedy or avoid dangers. • Safety fence dimensions • Fire extinguishing • Emergency release of the manipulator´s arm • Brake testing • Risk of disabling function "Reduced speed 250 mm/s" • Safe use of the Teach Pendant Unit enabling device • Work inside the manipulator´s working range 3HAC 16247-1 A 5 1 Safety, service 1.1.1 Safety, service - General Section 1.1: General information 1.1.1 Safety, service - General Validity and responsibility The information does not cover how to design, install and operate a complete system, nor does it cover all peripheral equipment, which can influence the safety of the total system. To protect personnel, the complete system must be designed and installed in accordance with the safety requirements set forth in the standards and regulations of the country where the robot is installed. The users of ABB industrial robots are responsible for ensuring that the applicable safety laws and regulations in the country concerned are observed and that the safety devices necessary to protect people working with the robot system have been designed and installed correctly. Personnel working with robots must be familiar with the operation and handling of the industrial robot, described in the applicable documents, e.g. User’s Guide and Product Manual. Connection of external safety devices Apart from the built-in safety functions, the robot is also supplied with an interface for the connection of external safety devices. Via this interface, an external safety function can interact with other machines and peripheral equipment. This means that control signals can act on safety signals received from the peripheral equipment as well as from the robot. In the Product Manual - Installation and Commissioning, instructions are provided for connecting safety devices between the robot and the peripheral equipment. 1.1.2 Limitation of Liability General Any information given in this information product regarding safety, must not be construed as a warranty by ABB Robotics that the industrial robot will not cause injury or damage even if all safety instructions have been complied with. 1.1.3 Related information General The list below specifies documents which contain useful information: Documents 6 Type of information Detailed in document Installation of safety devices Installation and Commissioning Manual Changing robot modes User’s Guide Start-up Restricting the working space Installation and Commissioning Manual On-site installation Manipulator A Section 3HAC 16247-1 1 Safety, service 1.2.1 Safety risks related to gripper Section 1.2: Safety risks 1.2.1 Safety risks related to gripper Ensure that a gripper is prevented from dropping a workpiece, if such is used. 1.2.2 Safety risks related to tools/workpieces Safe handling It must be possible to turn off tools, such as milling cutters, etc., safely. Make sure that guards remain closed until the cutters stop rotating. It should be possible to release parts by manual operation (valves). Safe design Grippers/end effectors must be designed so that they retain workpieces in the event of a power failure or a disturbance of the controller. 1.2.3 Safety risks related to pneumatic/hydraulic systems General Residual energy Safe design Special safety regulations apply to pneumatic and hydraulic systems. • Residual energy may be present in these systems so, after shutdown, particular care must be taken. • The pressure in pneumatic and hydraulic systems must be released before starting to repair them. • Gravity may cause any parts or objects held by these systems to drop. • Dump valves should be used in case of emergency. • Shot bolts should be used to prevent tools, etc., from falling due to gravity. 1.2.4 Safety risks during operational disturbances General Qualified personnel Extraordinary risks 3HAC 16247-1 • The industrial robot is a flexible tool which can be used in many different industrial applications. • All work must be carried out professionally and in accordance with the applicable safety regulations. • Care must be taken at all times. • Remedial action must only be carried out by qualified personnel who are familiar with the entire installation as well as the special risks associated with its different parts. If the working process is interrupted, extra care must be taken due to risks other than those associated with regular operation. Such an interruption may have to be rectified manually. A 7 1 Safety, service 1.2.5 Safety risks during installation and service 1.2.5 Safety risks during installation and service General risks during installation and service Nation/region specific regulations Non-voltage related risks To be observed by the supplier of the complete system • The instructions in the Product Manual - Installation and Commissioning must always be followed. • Emergency stop buttons must be positioned in easily accessible places so that the robot can be stopped quickly. • Those in charge of operations must make sure that safety instructions are available for the installation in question. • Those who install the robot must have the appropriate training for the robot system in question and in any safety matters associated with it. To prevent injuries and damage during the installation of the robot system, the regulations applicable in the country concerned and the instructions of ABB Robotics must be complied with. • Safety zones, which have to be crossed before admittance, must be set up in front of the robot's working space. Light beams or sensitive mats are suitable devices. • Turntables or the like should be used to keep the operator out of the robot's working space. • The axes are affected by the force of gravity when the brakes are released. In addition to the risk of being hit by moving robot parts, you run the risk of being crushed by the tie rod. • Energy, stored in the robot for the purpose of counterbalancing certain axes, may be released if the robot, or parts thereof, is dismantled. • When dismantling/assembling mechanical units, watch out for falling objects. • Be aware of stored heat energy in the controller. • Never use the robot as a ladder, i.e. do not climb on the robot motors or other parts during service work. There is a serious risk of slipping because of the high temperature of the motors or oil spills that can occur on the robot. • The supplier of the complete system must ensure that all circuits used in the safety function are interlocked in accordance with the applicable standards for that function. • The supplier of the complete system must ensure that all circuits used in the emergency stop function are interlocked in a safe manner, in accordance with the applicable standards for the emergency stop function. 1.2.6 Risks associated with live electric parts Voltage related risks, general Voltage related risks, controller 8 • Although troubleshooting may, on occasion, have to be carried out while the power supply is turned on, the robot must be turned off (by setting the mains switch to OFF) when repairing faults, disconnecting electric leads and disconnecting or connecting units. • The mains supply to the robot must be connected in such a way that it can be turned off outside the robot’s working space. A danger of high voltage is associated with the following parts: • Be aware of stored electrical energy (DC link) in the controller. A 3HAC 16247-1 1 Safety, service 1.2.6 Risks associated with live electric parts • Units inside the controller, e.g. I/O modules, can be supplied with power from an external source. • The mains supply/mains switch • The power unit • The power supply unit for the computer system (230 VAC) • The rectifier unit (400-480 VAC and 700 VDC. Note: Capacitors!) • The drive unit (700 VDC) • The service outlets (115/230 VAC) • The power supply unit for tools, or special power supply units for the machining process • The external voltage connected to the control cabinet remains live even when the robot is disconnected from the mains. • Additional connections Voltage related risks, manipulator A danger of high voltage is associated with the manipulator in: Voltage related risks, tools, material handling devices, etc Tools, material handling devices, etc., may be live even if the robot system is in the OFF position. Power supply cables which are in motion during the working process may be damaged. 3HAC 16247-1 • The power supply for the motors (up to 800 VDC) • The user connections for tools or other parts of the installation (max. 230 VAC, see Installation and Commissioning Manual) A 9 1 Safety, service 1.3.1 Safety fence dimensions Section 1.3: Safety actions 1.3.1 Safety fence dimensions General Fit a safety fence or enclosure around the robot to ensure a safe robot installation. Dimensioning Dimension the fence or enclosure to enable it to withstand the force created if the load being handled by the robot is dropped or released at maximum speed. Determine the maximum speed from the maximum velocities of the robot axes and from the position at which the robot is working in the work cell (see Product Specification - Description, Robot Motion). Also consider the maximum possible impact caused by a breaking or malfunctioning rotating tool or other device fitted to the manipulator. 1.3.2 Fire extinguishing Use a CARBON DIOXIDE (CO 2 ) extinguisher in the event of a fire in the robot (manipulator or controller)! 1.3.3 Emergency release of the manipulator’s arm Description In an emergency situation, any of the manipulator’s axes may be released manually by pushing the brake release buttons on the manipulator or on an optional external brake release unit. How to release the brakes is detailed in section "Manually releasing the brakes". The manipulator arm may be moved manually on smaller robot models, but larger models may require using an overhead crane or similar. Increased injury Before releasing the brakes, make sure that the weight of the arms does not increase the pressure on the trapped person, which may further increase any injury! 1.3.4 Brake testing When to test During operation the holding brakes of each axis motor wear normally. A test may be performed to determine whether the brake can still perform its function. How to test The function of each axis’ motor holding brakes may be checked as detailed below: 1. Run each manipulator axis to a position where the combined weight of the manipulator arm and any load is maximized (max. static load). 2. Switch the motor to the MOTORS OFF position with the Operating mode selector on the controller. 3. Check that the axis maintains its position. If the manipulator does not change position as the motors are switched off, then the brake function is adequate. 10 A 3HAC 16247-1 1 Safety, service 1.3.5 Risk of disabling function "Reduced speed 250 mm/s" 1.3.5 Risk of disabling function "Reduced speed 250 mm/s" Do not change "Transm gear ratio" or other kinematic parameters from the Teach Pendant Unit or a PC. This will affect the safety function Reduced speed 250 mm/s. 1.3.6 Safe use of the Teach Pendant Unit The enabling device is a push button located on the side of the Teach Pendant Unit (TPU) which, when pressed halfway in, takes the system to MOTORS ON. When the enabling device is released or pushed all the way in, the robot is taken to the MOTORS OFF state. To ensure safe use of the Teach Pendant Unit, the following must be implemented: The enabling device must never be rendered inoperative in any way. During programming and testing, the enabling device must be released as soon as there is no need for the robot to move. The programmer must always bring the Teach Pendant Unit with him/her, when entering the robot’s working space. This is to prevent anyone else taking control over the robot without the programmer knowing. 1.3.7 Work inside the manipulator’s working range If work must be carried out within the robot’s work envelope, the following points must be observed: - The operating mode selector on the controller must be in the manual mode position to render the enabling device operative and to block operation from a computer link or remote control panel. - The robot’s speed is limited to max. 250 mm/s when the operating mode selector is in position < 250 mm/s. This should be the normal position when entering the working space. The position 100% ”full speed”may only be used by trained personnel who are aware of the risks that this entails. - Pay attention to the rotating axes of the manipulator! Keep a distance to the axes in order not to get entangled with hair or clothing. Also be aware of any danger that may be caused by rotating tools or other devices mounted on the manipulator or inside the cell. - Test the motor brake on each axis, according to section Brake testing on page 10. 3HAC 16247-1 A 11 1 Safety, service 1.3.7 Work inside the manipulator’s working range 12 A 3HAC 16247-1 2 Reference information 2.0.1 Introduction Chapter 2: Reference information 2.0.1 Introduction General 3HAC 16247-1 This chapter presents generic pieces of information, complementing the more specific information in the following chapters. A 13 2 Reference information 2.1.1 Applicable Safety Standards Section 2.1: Reference information 2.1.1 Applicable Safety Standards Standards, general Standards, robot cell 14 The robot is designed in accordance with the requirements of: • EN 775 - Robot safety. • EN 292-1 - Basic terminology. • EN 292-2 - Technical principles. • EN 418 - Emergency stop. • EN 563 - Temperatures of surfaces. • EN 954-1 - Safety related parts of control systems. • EN 60204-1 - Electrical equipment of machines. • EN 1050 - Principles for risk assessment. • ANSI/RIA 15.06-1999 - Industrial robots, safety requirements. • DIN 19258 - Interbus-S, International Standard The following standards are applicable when the robot is part of a robot cell: • EN 953 - Fixed and moveable guards • EN 811 - Safety distances to prevent danger zones being reached by the lower limbs. • EN 349 - Minimum gaps to avoid crushing of parts of the human body. • EN 294 - Safety distances to prevent danger zones being reached by the upper limbs. • EN 1088 - Interlocking devices • EN 999 - The positioning of protective equipment in respect of approach speeds of the human body. • ISO 11 161 - Industrial automation systems - Safety of intergrated manufacturing systems. A 3HAC 16247-1 2 Reference information 2.1.2 Screw joints 2.1.2 Screw joints General This section details how to tighten the various types of screw joints on the manipulator as well as the controller. The instructions and torque values are valid for screw joints comprising metallic materials and do not apply to soft or brittle materials. Any instructions given in the repair, maintenance or installation procedure description override any value or procedure given here, i.e. these instruction are only valid for standard type screw joints. UNBRAKO screws UNBRAKO is a special type of screw recommended by ABB in certain screw joints. It features special surface treatment (Gleitmo as described below), and is extremely resistant to fatigue. Whenever used, this is specified in the instructions and in such cases no other type of replacement screw is allowed. Using other types of screw will void any warranty and may potentially cause serious damage or injury! Gleitmo treated screws Gleitmo is a special surface treatment to reduce the friction when tightening the screw joint. Screws treated with Gleitmo may be reused 3-4 times before the coating disappears. After this the screw must be discarded and replaced with a new one. When handling screws treated with Gleitmo, protective gloves of nitrile rubber type should be used. Screws lubricated in other ways Screws lubricated with Molycote 1000 (or another lubricant) should only be used when specified in the repair, maintenance or installation procedure descriptions. In such cases, proceed as follows: 1. Lubricate the thread of the screw. 2. Lubricate between the plain washer and screw head. 3. Tighten to the torque specified in section "Tightening torque" below. Screw dimensions of M8 or larger must be tightened with a torque wrench. Screw dimensions of M6 or smaller may be tightened without a torque wrench if this is done by trained and qualified personnel. 3HAC 16247-1 Lubricant Art. no. Molycote 1000 (molybdenum disulphide grease) 1171 2016-618 A 15 2 Reference information 2.1.2 Screw joints Tightening torque Screws with slotted or cross recess head Below are tables specifying the torque values for different screw joint types: Dimension Tightening torque (Nm) Class 4.8 "dry" M2.5 0.25 M3 0.5 M4 1.2 M5 2.5 M6 5.0 Dimension Tightening torque (Nm) Class 8.8 "dry" Tightening torque (Nm) Class 10.9 "dry" Tightening torque (Nm) Class 12.9 "dry" M5 6 - - M6 10 - - M8 24 34 40 M10 47 67 80 M12 82 115 140 M16 200 290 340 Dimension Tightening torque (Nm) Class 10.9 Tightening torque (Nm) Class 12.9 M8 28 34 M10 55 66 M12 96 115 M16 235 280 Screws with hexagon socket head, “dry” Screws with hexagon socket head, lubricated 16 A 3HAC 16247-1 2 Reference information 2.1.3 Weight specifications 2.1.3 Weight specifications Definition In all repair and maintenance instructions, weights of the components handled are sometimes specified. All components exceeding 22 kg (50 lbs) are high-lighted in this way. ABB recommends the use of lifting equipment when handling components with a weight exceeding 22 kg to avoid inflicting injury. A wide range of lifting tools and devices is available for each manipulator model. Example Below is an example of how a weight specification is presented: The motor weighs 65 kg! All lifting equipment used must be dimensioned accordingly! 3HAC 16247-1 A 17 2 Reference information 2.1.4 Standard toolkit 2.1.4 Standard toolkit General All service (repairs, maintenance and installation) instructions contain lists of tools required to perform the specified activity. All special tools required are listed directly in the instructions while all the tools that are considered standard are gathered in the Standard toolkit and defined in the table below. In this way, the tools required are the sum of the Standard Toolkit and any tools listed in the instruction. Contents, standard toolkit, 3HAC 15571-1 18 Qty Art. no. Tool Rem. 1 - Ring-open-end spanner 8-19mm 1 - Socket head cap 5-17mm 1 - Torx socket no:20-60 1 - Box spanner set 1 - Torque wrench 10-100Nm 1 - Torque wrench 75-400Nm 1 - Ratchet head for torque wrench 1/2 2 - Hexagon-headed screw M10x100 1 - Socket head cap no:14, socket 40mm bit L 100mm 1 - Socket head cap no:14, socket 40mm bit L 20mm To be shorted to 12mm 1 - Socket head cap no:6, socket 40mm bit L 145mm A 3HAC 16247-1 2 Reference information 2.1.5 Special tools, IRB 6600/6650/7600 2.1.5 Special tools, IRB 6600/6650/7600 General All service (repairs, maintenance and installation) instructions contain lists of tools required to perform the specified activity. The required tools are a sum of standard tools, defined in section Standard toolkit on page 18, and of special tools, listed directly in the instructions and also gathered in the table below. Special tools, IRB 6600/6650/7600 The table below is an overview of all the special tools required when performing service activities on the IRB 6600/6650/7600. The tools are gathered in two kits: Basic Toolkit (3HAC 15571-3) and Extended Toolkit (3HAC 15571-2). The special tools are also listed directly in the current instructions. 3HAC 16247-1 Description IRB 66X0/ IRB 7600/ Art. no. Qty Qty Angel bracket a a 68080011-LP Bolts (M16 x 60) for Mech stop axis 3 2 - 3HAB 3409-86 Bolts (M16 x 80) for Mech stop axis 3 - 2 3HAB 3409-89 Cal. tool a a 68080011-GM Calibration bracket a - 3HAC 13908-9 Calibration tool ax1 a a 3HAC 13908-4 CalPen (Calibration Pendulum) 1 1 3HAC 15716-1 Extension 300mm for bits 1/2" 1 1 3HAC 12342-1 Fixture lower arm 1 - 3HAC 13659-1 Fixture lower arm - 1 3HAC 13660-1 Gearbox crank 1 - 3HAC 16488-1 Guide pins M12 x 150 2 - 3HAC 13056-2 Guide pins M12 x 200 2 - 3HAC 13056-3 Guide pins M12 x 250 1 - 3HAC 13056-4 Guide pins M8 x 100 2 - 3HAC 15520-1 Guide pins M8 x 150 2 - 3HAC 15520-2 Guide pins sealing - b 3HAC 14445-1 Guide pins sealing b - 3HAC 14446-1 Guide pins M10 x 100 2 2 3HAC 15521-1 Guide pins M10 x 150 2 2 3HAC 15521-2 Guide pins M16 x 150 - 2 3HAC 13120-2 Guide pins M16 x 200 - 2 3HAC 13120-3 Guide pins M16 x 250 - 1 3HAC 13120-4 Guide pins M16 x 300 2 2 3HAC 13120-5 Guide pins sealing ax 2, 3, 100mm 1 - 3HAC 14628-2 Guide pins sealing ax 2, 3, 80mm 1 - 3HAC 14628-1 Guide pins sealing ax 2, 3, 100mm - 1 3HAC 14627-3 Guide pins sealing ax 2, 3, 80mm - 1 3HAC 14627-2 Hydraulic cylinder 1 1 3HAC 11731-1 A 19 2 Reference information 2.1.5 Special tools, IRB 6600/6650/7600 Description IRB 66X0/ IRB 7600/ Art. no. Qty Qty Hydraulic pump 80Mpa 1 1 3HAC 13086-1 Hydraulic pump 80Mpa (Glycerin) b b 3HAC 13086-2 Levelmeter 2000 kit a a 6369901-348 Lifting device, base 1 1 3HAC 15560-1 Lifting device, manipulator 1 1 3HAC 15607-1 Lifting device, upper arm 1 - 3HAC 15994-1 Lifting device, upper arm - 1 3HAC 15536-1 Lifting eye VLBG M12 1 1 3HAC 16131-1 Lifting eye M12 2 2 3HAC 14457-3 Lifting eye M16 2 2 3HAC 14457-4 Lifting tool (chain) 1 1 3HAC 15556-1 Lifting tool, gearbox ax 2 1 - 3HAC 13698-1 Lifting tool, gearbox ax 2 - 1 3HAC 12731-1 Lifting tool, lower arm b b 3HAC 14691-1 Lifting tool, motor ax 1, 4, 5 1 1 3HAC 14459-1 Lifting tool, motor ax 2, 3, 4 1 1 3HAC 15534-1 Lifting tool, wrist unit 1 - 3HAC 13605-1 Lifting tool, wrist unit - 1 3HAC 12734-1 Measuring pin a - 3HAC 13908-5 Mech stop ax 3 2 - 3HAC 12708-1 Mech stop ax 3 - 2 3HAC 12708-2 Press tool, ax 2 bearing 1 - 3HAC 13527-1 Press tool, ax 2 bearing - 1 3HAC 13453-1 Press tool, ax 2 shaft 1 1 3HAC 13452-1 Press tool, balancing device shaft 1 1 3HAC 17129-1 Press tool, balancing device 1 1 3HAC 15767-1 Puller tool, balancing device shaft 1 1 3HAC 12475-1 Removal tool, wheel unit - 1 3HAC 15814-1 Removal tool, motor M10x 2 2 3HAC 14972-1 Removal tool, motor M12x 2 2 3HAC 14631-1 Removal tool, motor M12x 2 2 3HAC 14973-1 Rotation tool 1 1 3HAC 17105-1 Sensor plate a 1 3HAC 0392-1 Support, base 1 1 3HAC 15535-1 Sync. adapter a a 3HAC 13908-1 Tool set balancing device 1 - 3HAC 15943-2 Tool set balancing device - 1 3HAC 15943-1 Turn disk fixture a a 3HAC 68080011-GU Washers for Mech stop axis 3 2 2 3HAA 1001-186 Note a) Calibration tools for IRB 6600/6650/7600 when CalPen is not used (standard). Note b) Special tools that may be rent from ATRP/S. 20 A 3HAC 16247-1 2 Reference information 2.1.6 Performing a leak-down test 2.1.6 Performing a leak-down test General After refitting any motor and any gearbox, the integrity of all seals enclosing the gearbox oil must be tested. This is done in a leak-down test. Required equipment Equipment, etc. Spare part no. Art. no. Leakdown tester Note 3HAC 0207-1 Leak detection spray Procedure Step 3HAC 16247-1 Action Note/Illustration 1. Finish the refitting procedure of the motor or gear in question. 2. Remove the topmost oil plug on the gear in Art. no. specified above! question, and replace it with the leakdown tester . Adapters may be required, which are included in the leakdown tester kit. 3. Apply compressed air, and raise the pres- Recommended value: 0.2 - 0.25 bar sure with the knob until the correct value is (20 - 25 kPa) shown on the manometer. 4. Disconnect the compressed air supply. 5. Wait for approx. 8-10 minutes. No pressure If the compressed air is significantly loss must be detected. colder or warmer than the gearbox to be tested, a slight pressure increase or decrease respectively may occur. This is quite normal. 6. Was any pressure drop evident? Localize the leak as detailed below. Remove the leakdown tester, and refit the oil plug. The test is complete. 7. Spray suspected leak areas with leak detection spray . Bubbles indicate a leak. 8. When the leak has been localized: take the necessary measures to correct the leak. A Art. no. specified above! 21 2 Reference information 2.1.7 Lifting equipment and lifting instructions 2.1.7 Lifting equipment and lifting instructions General Many repair and maintenance activities require different pieces of lifting equipment, which are specified in each activity instruction. However, how to use each piece of lifting equipment is not detailed in the activity instruction, but in the instruction delivered with each piece of lifting equipment. This implies that the instructions delivered with the lifting equipment should be stored for later reference. 22 A 3HAC 16247-1 3 Repair activities, manipulator 3.0.1 Introduction Chapter 3: Repair activities, manipulator 3.0.1 Introduction Definitions This chapter details all repair activities recommended for the manipulator, including for any external units of the manipulator. It is made up of separate units, each detailing a specific repair activity, e.g. Removal or Refitting of a certain component on the manipulator. Each unit contains all information required to perform the activity, e.g. spare parts numbers, required special tools and materials. The chapter is divided into: 3HAC 16247-1 • Removal/refitting instructions for all the spare parts on the manipulator • Remaining instructions for all the spare parts in e.g. the manipulators external units, if any. A 23 3 Repair activities, manipulator 3.1.1 Removal of cable harness Section 3.1: Complete manipulator 3.1.1 Removal of cable harness Location complete cable harness The cable harness is located throughout the manipulator as shown in the figure below. E H J G F O C B K A D L M N xx0200000210 24 A Connector at manipulator base, R1.MP and R1.SMB B Connectors at motor 1; R2.FB1 and R2.MP1 C Connectors at motor 2; R2.FB2 and R2.MP2 D Connectors at serial measurement board; R1.SMB1-3, R1.SMB4-6, R1.SMB1.7, R2.FB7 and R2.SMB. Battery connector X3 R1.G and R2.G. Connectors at brake release unit X8, X9 and X10. E Connectors at motor 3; R2.FB3 and R2.MP3 and for signal lamp R2.H1 and R2.H2 F Connectors at motor 4; R2.FB4 and R2.MP4 G Connectors at cable harness separation; R2.M5/6 H Connectors at cable harness division, inside of upper arm tube; R3.FB5 and R3.MP5. Connectors at motor 5; R4.FB5 and R4.MP5. J Connectors at motor 6; R3.FB6 and R3.MP6 K Rear cover plate L Connector R1.MP M Connector R1.SMB N Connection of earth cable O Velcro strap that secures the cable harness to the arm house A 3HAC 16247-1 3 Repair activities, manipulator 3.1.1 Removal of cable harness Required equipment Equipment, etc. Spare part no. Art. no. Circuit Diagram 3HAC 13347-1 Included in Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal, cable harness, axes 1-4 Note These procedures include references to the tools required. The procedure below details how to remove the cable harness, axes 1-4. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The cable harnesses are sensitive to mechanical damage! They must be handled with care, especially the connectors, in order to avoid damaging them! Step 1. 3HAC 16247-1 Action Note/Illustration In order to facilitate refitting of cable harness, Axes 2 and 3 may be tilted slightly to run the manipulator to the specified position: improve access. • Axis 1: 0 ° • Axis 2: 0 ° • Axis 3: 0 ° • Axis 4: 0 ° • Axis 5: +90 ° • Axis 6: no significance 2. Remove the rear cover plate on the manipulator by unscrewing its attachment screws. 3. Disconnect the earth cable. 4. Disconnect connectors R1.MP and R1.SMB. 5. Pull the cable and connectors up through the center of the frame. 6. Disconnect all connectors at motor 1 and motor 2. A Shown in the figure Location complete cable harness on page 24! Specified in the figure Location complete cable harness on page 24! 25 3 Repair activities, manipulator 3.1.1 Removal of cable harness Step Action Note/Illustration 7. Open the SMB cover carefully. The cable between the battery and the SMBunit may stay connected, in order to avoid recalibration of the robot. Be careful not to let the weight of the cover strain the cable! In order to remove the cover completely, the connector R1.G must be disconnected! This causes a necessary recalibration of the robot! 8. Disconnect connectors R2.SMB, R1.SMB13, R1.SMB4-6. Disconnect X8, X9 and X10. R 2.S MB R 1.S MB1-3 R 1.S MB4-6 R 1.G X8, X9, X10 R 2.G xx0200000118.wmf 9. Unscrew the four screws securing the cable gland. This releases the cable harness from the frame. 10. Remove the adapter plate from the harness by removing its two attachment screws and the velcro strap. Note! Different manipulator versions are fitted with different plate versions. Make sure the correct one is used to avoid cable failure. 11. Remove the bracket securing the cables inside the lower arm by unscrewing the nuts from the stud bolts securing the clamp to the lower arm. FB3 FB4 FB5 FB6 MP3 MP4 MP5 MP6 xx0100000142.wmf 12. Remove the upper bracket securing the cables to the arm house by unscrewing its two attachment screws. MP6 MP3 FB6 FB5 MP5 MP FB3 FB4 xx0100000143.wmf 13. Disconnect connector R2.M5/6 at the rear cable division point. Shown in the figure Location complete cable harness on page 24! 14. Disconnect all connectors at motor 3 and motor 4. Specified in the figure Location complete cable harness on page 24! 15. Gently pull the cable harness out. 26 A 3HAC 16247-1 3 Repair activities, manipulator 3.1.1 Removal of cable harness Location of cable harness ax 5-6 The location of the cable harness, axes 5-6, is shown in the figure below. B A F G H C D xx0200000213 3HAC 16247-1 A Cable bracket, wrist unit B Cable bracket, upper arm tube C Connectors at motor axis 5; R4.FB5 and R4.MP5 D Connectors in upper arm tube; R3.FB5 and R3.MP5 F Cable attachment, rear G Connectors at cable harness division point; R2.M5/6 H Connectors at motor, axis 6; R3.FB6 and R3.MP6 A 27 3 Repair activities, manipulator 3.1.1 Removal of cable harness Removal, cable harness, axes 5-6 The procedure below details how to remove the upper cable harness. The separate cable that goes from the connection point inside of the upper arm tube to the motor, axis 5, is not included in this procedure. The removal of that cable is described further down in section Removal, cable harness, axis 5 on page 29. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The cable harnesses are sensitive to mechanical damage! They must be handled with care, especially the connectors, in order to avoid damaging them! Axis 5 must be oriented in the correct position (+90 °) to allow opening the motor 6 cover! Step 1. Action Note/Illustration Remove the cover, wrist unit and the cover, upper arm tube. A B xx0200000214 • A: cover, wrist unit • B: cover, upper arm tube 2. Remove the cover of motor, axis 6 and dis- Specified in the figure Location of cable connect all connectors beneath. harness ax 5-6 on page 27! 3. Loosen the cable bracket on top of the Shown in the figure Location of cable wrist unit by unscrewing the three attach- harness ax 5-6 on page 27! ment screws. Two of the attachment screws are located C visible at the rear attachment and the third B is located at the bottom of the cable bracket, in the center. xx0200000254 28 • B: Attachment screws, rear of cable bracket, 2 pcs • C: Attachment screw, bottom of cable bracket, 1 pc 4. Pick out the cabling from motor, axis 6. 5. Loosen the cable bracket in the upper arm Shown in the figure Location of cable tube by unscrewing the two screws on top harness ax 5-6 on page 27! of the tube. 6. Disconnect the two connectors (R3.FB5 and R3.MP5) in the tube. 7. Remove eventual cable straps from the harness. A Shown in the figure Location of cable harness ax 5-6 on page 27! 3HAC 16247-1 3 Repair activities, manipulator 3.1.1 Removal of cable harness Step Action Note/Illustration 8. Remove the cable attachment, rear. Shown in the figure Location of cable harness ax 5-6 on page 27! 9. Disconnect connectors R2.M5/6 at the cable harness division point. Shown in the figure Location of cable harness ax 5-6 on page 27! 10. Gently pull the cable harness out. Removal, cable harness, axis 5 The procedure below details how to remove the cable, axis 5. Step 3HAC 16247-1 Action Note/Illustration 1. Remove the complete wrist unit. Detailed in Removal of complete wrist unit on page 47. 2. Remove the cover of motor, axis 5. 3. Disconnect all connectors at motor, axis 5. 4. Remove the cable gland cover at the cable exit by unscrewing its two attachment screws. 5. Remove the cable, axis 5. A 29 3 Repair activities, manipulator 3.1.2 Refitting of cable harness 3.1.2 Refitting of cable harness Location of cable harness The cable harness is located throughout the manipulator as shown in the figure below. E H J G F O C B K A D L M N xx0200000210 30 A Connector at manipulator base, R1.MP and R1.SMB B Connectors at motor 1; R2.FB1 and R2.MP1 C Connectors at motor 2; R2.FB2 and R2.MP2 D Connectors at serial measurement board; R1.SMB1-3, R1.SMB4-6, R1.SMB1.7, R2.FB7 and R2.SMB. Battery connector X3 R1.G and R2.G. Brake release unit connectors X8, X9 and X10 E Connectors at motor 3; R2.FB3 and R2.MP3 and for signal lamp R2.H1 and R2.H2 F Connectors at motor 4; R2.FB4 and R2.MP4 G Connectors at cable harness separation; R2.M5/6 H Connectors at cable harness division, inside of upper arm tube; R3.FB5 and R3.MP5. Connectors at motor 5; R4.FB5 and R4.MP5. J Connectors at motor 6; R3.FB6 and R3.MP6 K Rear cover plate L Connector R1.MP M Connector R1.SMB N Connection of earth cable O Velcro strap that secures the cable harness to the arm house A 3HAC 16247-1 3 Repair activities, manipulator 3.1.2 Refitting of cable harness Required equipment Equipment, etc. Spare part no. Art. no. Note Cable harness, axes 1-4 3HAC 14940-1 IRB 6600 Cable harness, axes 1-4 3HAC 16331-1 IRB 6650 Cable harness, axes 5-6 3HAC 14140-1 Cable harness, axis 5 3HAC 14139-1 Circuit Diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Refitting, cable harness, axes 1-4 These procedures include references to the tools required. The procedure below details how to refit the cable harness, axes 1-4. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The cable harnesses are sensitive to mechanical damage! They must be handled with care, especially the connectors, in order to avoid damaging them! Step 1. 3HAC 16247-1 Action Note/Illustration In order to facilitate refitting of cable harness, Axes 2 and 3 may be tilted slightly to run the manipulator to the specified position: improve access. • Axis 1: 0 degrees • Axis 2: 0 degrees • Axis 3: 0 degrees • Axis 4: 0 degrees • Axis 5: +90 degrees • Axis 6: no significance 2. Pull the cable and connectors down through Make sure the cables are not twisted the center of the frame. with each other or with eventual customer harnesses! Make a note of the correct positions of the connectors! 3. Reconnect connectors R1.MP and R1.SMB at the rear cover plate. Make a note of the correct positions of the connectors! 4. Reconnect the earth cable. Shown in the figure Location of cable harness on page 30! A 31 3 Repair activities, manipulator 3.1.2 Refitting of cable harness Step Action Note/Illustration 5. Refit the rear cover plate on the manipulator with its attachment screws. 6. Reconnect all connectors at motor 1 and motor 2. 7. Secure the gland plate with four attachment screws from inside the SMB recess. Specified in the figure Location of cable harness on page 30! MP2 MP1 MP4 SMB MP3 MP5 MP6 xx0100000141 8. Reconnect connectors R2.SMB, R1.SMB13, R1.SMB4-6. Reconnect X8, X9 and X10. Reconnect R1.G if it has been disconnected. X8, X9, X10 R2.S MB R1.S MB1-3 R1.S MB4-6 R1.G R 2.G xx0200000118 9. Secure the SMB cover with its attachment screws. 10. Secure the correct adapter plate to the harness with its two attachment screws. 11. Pull the cable harness through the lower arm. 12. Refit the bracket securing the cables inside the lower arm. Note! Different manipulator versions are fitted with different plate versions. Make sure the correct one is used to avoid cable failure. FB3 FB4 FB5 FB6 MP3 MP4 MP5 MP6 xx0100000142 13. Refit the bracket securing the cables to the arm house. Make sure not to twist the harness! MP6 MP3 FB6 FB5 MP5 MP FB3 FB4 xx0100000143 14. 32 Reconnect all connectors at motor 3 and motor 4. A Specified in the figure Location of cable harness on page 30! 3HAC 16247-1 3 Repair activities, manipulator 3.1.2 Refitting of cable harness Step Location of cable harness axes 5-6 Action Note/Illustration 15. Reconnect connector R2.M5/6 gently at the rear cable division point. Be careful not to bend the attachment plate when fastening the screws! Shown in the figure Location of cable harness on page 30! M6, 2 pcs. 16. Secure the cable harness to the arm house with a velcro strap. Shown in the figure Location of cable harness on page 30! The cable harness of the axes 5-6 is located as shown in the figure below. B A F G H C D xx0100000145 Refitting, cable harness, axes 5-6 3HAC 16247-1 A Cable bracket, wrist unit B Cable bracket, upper arm tube C Connectors at motor axis 5; R4.FB5 and R4.MP5 D Connectors in upper arm tube; R3.FB5 and R3.MP5 F Cable attachment, rear G Connectors at cable harness division point; R2.M5/6 H Connectors at motor, axis 6; R3.FB6 and R3.MP6 The procedure below details how to refit the upper arm cable harness. The separate cable that goes from the connection point inside of the upper arm tube to the motor, axis 5, is not included in this procedure. The refitting of that cable is described further down in section Refitting, cable harness axis 5 on page 35. A 33 3 Repair activities, manipulator 3.1.2 Refitting of cable harness Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The cable harnesses are sensitive to mechanical damage! They must be handled with care, especially the connectors, in order to avoid damaging them! Axis 5 must be oriented in the correct position (+90 °) to allow opening the motor 6 cover! Step 1. Action Note/Illustration The manipulator is required to be positioned in the following position: • Axis 4: 0 degrees • Axis 5: +90 degrees • Axis 6: no significance 2. Gently insert the cable harness from the rear into the upper arm. 3. Connect the two connectors inside the upper Shown in the figure Location of cable arm tube, R3.FB5 and R3.MP5 and secure harness axes 5-6 on page 33! the cable bracket with the two attachment screws to the tube. 4. Place the cabling to motor, axis 6, correctly on the upper arm and gently pull the connectors through the hole on top of wrist unit to motor, axis 6. A xx0200000185 • 5. In case of excess cable length: put a loop of cable in this area with cable straps (A). The cables are longer in order to fit different upper arm lengths. Fasten the cable bracket, wrist unit with Also shown in the figure Location of three attachment screws, two of them visible cable harness axes 5-6 on page 33! at the rear attachment point and the third located on the bottom of the cable bracket, in C the center. B xx0200000254 6. 34 • B: Attachment screws, rear of cable bracket. • C: Attachment screw, bottom of cable bracket. Reconnect the connectors to motor, axis 6 and refit the motor cover. A 3HAC 16247-1 3 Repair activities, manipulator 3.1.2 Refitting of cable harness Step 7. Action Note/Illustration Refit the cover, upper arm and the cover, wrist unit. Make sure the cabling is placed correctly when refitting the covers, and does not get jammed. A B xx0200000214 Refitting, cable harness axis 5 • A: cover, wrist unit • B: cover, upper arm tube 8. Refit eventually removed cable straps to the harness. 9. Refit the cable attachment, rear. 10. Reconnect connector R2.M5/6 gently at the Shown in the figure Location of cable rear cable division point with two screws, M6. harness axes 5-6 on page 33! Be careful not to bend the attachment plate when fastening the screws! Shown in the figure Location of cable harness axes 5-6 on page 33! The procedure below details how to refit the cable, axis 5. Step Action Note/Illustration 1. Reconnect all connectors at motor, axis 5. 2. Refit the cable gland cover at the cable exit with its two attachment screws. 3. Refit the cover of motor, axis 5. 4. Refit the complete wrist unit. Detailed in section Refitting of complete wrist unit on page 50. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 35 3 Repair activities, manipulator 3.1.3 Removal of complete arm system 3.1.3 Removal of complete arm system Location of arm system The complete arm system is defined as the complete manipulator except for the base and gearbox axis 1, i.e. the upper and lower arms, balancing device and frame. This is shown in the figure below. A B C F G D H E xx0200000224 A Upper arm B Lower arm C Frame D Gearbox, axis 1 E Base attachment screws F Balancing device G Block for calibration H Motor axis 1 Required equipment Equipment, etc. Spare part no. Art. no. Lifting device, manipulator 36 Note 3HAC 15607-1 Instruction 3HAC 15971-2 enclosed! A 3HAC 16247-1 3 Repair activities, manipulator 3.1.3 Removal of complete arm system Equipment, etc. Spare part no. Art. no. Standard toolkit Note 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal, arm system These procedures include references to the tools required. The procedure below details how to lift and remove the complete arm system. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The complete arm system weighs 1300 kg! All lifting equipment used must be dimensioned accordingly! Step 1. Action Note/Illustration Make sure the manipulator is posiManually releasing the brakes is detailed in tioned as shown in figure to the right. If "Manually releasing the brakes" in the it is not, position it that way. Installation Manual. 50 ° m xx0100000103 3HAC 16247-1 2. Drain the oil from gearbox axis 1. Detailed in "Oil change, gearbox axis 1" in the Maintenance Manual. 3. Remove the motor, axis 1. Detailed in section Removal of motor, axis 1 on page 93. 4. Run the overhead crane to a position above the manipulator. A 37 3 Repair activities, manipulator 3.1.3 Removal of complete arm system Step 38 Action Note/Illustration 5. Fit the lifting device and adjust it as detailed in enclosed instruction. Art. no. specified in Required equipment on page 36! Make sure the lift is done completely level! How to adjust the lift is described in the enclosed instruction to the lifting device! Follow the instructions before continuing the lift! 6. Remove the block for calibration from Shown in the figure Location of arm system the bottom of the frame. on page 36! 7. Remove the arm system from the base Shown in the figure Location of arm system by unscrewing its 24 attachment on page 36! screws. 8. Lift the arm system and secure it in a safe area. A Make sure all hooks and attachments maintain in correct position while lifting the manipulator! Always move the manipulator at very low speeds, making sure it does not tip. 3HAC 16247-1 3 Repair activities, manipulator 3.1.4 Refitting of complete arm system 3.1.4 Refitting of complete arm system Location of arm system The complete arm system is defined as the complete manipulator except for the base and gearbox axis 1, i.e. the upper and lower arms, balancing device and frame. This is shown in the figure below. A B C F G D H E xx0200000224 A Upper arm B Lower arm C Frame D Gearbox, axis 1 E Base attachment screws and washers (24 pcs) F Balancing device G Block for calibration H Motor axis 1 Required equipment Equipment, etc. Spare part no. Art. no. Lifting device, manipulator 3HAC 16247-1 Note 3HAC 15607-1 Instruction 3HAC 15971-2 enclosed! A 39 3 Repair activities, manipulator 3.1.4 Refitting of complete arm system Equipment, etc. Spare part no. Art. no. Note Guide pins, M12 x 130 Used to guide the complete arm system when refitting. Always use the guide pins in pairs! Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Refitting, arm system These procedures include references to the tools required. The procedure below details how to lift and refit the complete arm system. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The complete arm system weighs 1300 kg! All lifting equipment used must be dimensioned accordingly! Step Action Note/Illustration 1. Fit the lifting device as detailed in enclosed Art. no. specified in Required equipinstruction. ment on page 36! 2. Lift the complete arm system and move it Make sure all the hooks and attachat very low speed, making sure it does not ments maintain in correct position tip! while lifting the manipulator! Make sure the lift is done completely level, adjust the length of the chains as detailed in enclosed instruction! 3. Fit two guide pins, M12 x 130, to the frame attachment holes, as shown in the figure to the right. Fit one guide pin next to the guiding hole (for the spring pin in the gearbox) and the other guide pin straight across the frame. A A B xx0300000070 The figure above shows the frame, with a view from below. • A: Attachment holes for the guide pins, M12. • 40 A B: Guiding hole for the spring pin located in the gearbox, axis 1. 3HAC 16247-1 3 Repair activities, manipulator 3.1.4 Refitting of complete arm system Step Action Note/Illustration 4. Look through the empty mounting hole of This is a complex task to be performed motor 1 to assist in aligning the assembly with utmost care in order to avoid injury during refitting of the arm system. or damage! The guiding pin in the gearbox must be fitted to the guiding hole of the frame. Lower the arm system with guidance from the guide pins previously fitted to the frame. 5. Refit 22 of the 24 attachment screws before the arm system is completely lowered. 6. Remove the guide pins and secure the arm Shown in the figure Location of arm system to the base with its 24 attachment system on page 39! screws and washers. M12 x 70, 12.9 quality UNBRAKO, tightening torque: 115 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 7. Refit the block for calibration at the bottom Shown in the figure Location of arm of the frame. system on page 39! 8. Refit the motor axis 1. 9. Refill the gearbox axis 1 with lubricating oil. Detailed in "Oil change, gearbox axis 1" in the Maintenance Manual. 10. Recalibrate the robot. Detailed in section Refitting of motor, axis 1 on page 95. Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 41 3 Repair activities, manipulator 3.2.1 Removal of turning disk Section 3.2: Upper arm 3.2.1 Removal of turning disk Location of turning disk The turning disk is located in the front of the wrist housing, as shown in the figure below. The two different robot versions result in different designs of the turning disks. A more detailed view of the component and its position may be found in the Foldout section Wrist complete on page 211. B B A A E2 E1 D C xx0200000217 A Turning disk B Wrist unit C Oil plug, draining D Oil plug, filling E1 Attachment screws, turning disk for robot version 175/2.55 (6 pcs) E2 Attachment screws, turning disk for robot version 225/2.55, 175/2.8, 125/3.2 or 200/ 2.75 (12 pcs) Required equipment Equipment, etc. Spare part no. Art. no. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. 42 Note These procedures include references to the tools required. A 3HAC 16247-1 3 Repair activities, manipulator 3.2.1 Removal of turning disk Removal, turning disk The procedure below details how to remove the turning disk. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Step 3HAC 16247-1 Action Note/Illustration 1. Remove any equipment fitted to the turning disk. 2. Run the robot to a position where the oil Shown in the figure Location of turnplug, draining of axis 6 gearbox faces down- ing disk on page 42! wards. 3. Drain the oil from gearbox 6. Detailed in "Oil change, gearbox axis 6" in the Maintenance Manual. 4. Remove the turning disk by unscrewing its attachment screws . Shown in the figure Location of turning disk on page 42! A 43 3 Repair activities, manipulator 3.2.2 Refitting of turning disk 3.2.2 Refitting of turning disk Location of turning disk The turning disk is located in the front of the wrist housing, as shown in the figure below. The two different robot versions result in different designs of the turning disks. A more detailed view of the component and its position may be found in the Foldout section Wrist complete on page 211. B B A A E2 E1 D C xx0200000217 44 A Turning disk B Wrist housing C Oil plug, draining D Oil plug, filling E1 Attachment screws, turning disk for robot version 175/2.55 (6 pcs) E2 Attachment screws, turning disk for robot version 225/2.55, 175/2.8, 125/3.2 or 200/ 2.75 (12 pcs) A 3HAC 16247-1 3 Repair activities, manipulator 3.2.2 Refitting of turning disk Required equipment Equipment, etc. Spare part no. Art. no. Note Turning disk, dia 200 3HAC 9744-5 For robot version 175/2.55. O-rings are not included! Turning disk, dia 200 3HAC 13752-1 For robot version 225/2.55, 175/ 2.8, 125/3.2 or 200/2.75. O-rings are not included! O-ring 3HAB 3772-65 (1 pc) 2152 0431-20 (6 pcs) For robot v. 175/2.55. Must be replaced when replacing the turning disk! O-ring 3HAB 3772-64 (1 pc) 3HAB 3772-61 (12 pcs) For robot v. 225/2.55, 175/2.8, 125/3.2 or 200/2.75. Must be replaced when replacing the turning disk! Grease 3HAB 3537-1 Used to lubricate the o-rings. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Refitting, turning disk These procedures include references to the tools required. The procedure below details how to refit the turning disk. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. 3HAC 16247-1 A 45 3 Repair activities, manipulator 3.2.2 Refitting of turning disk Step 1. Action Note/Illustration Lubricate the turning disk o-ring Art. no. specified in Required equipment on with grease. page 45! Fit the o-ring to the rear of the turning disk. Fit also the 6 or 12 pcs of o-rings (depending on robot version), when refitting the attachment screws. xx0200000218 • A: Sealing surface, o-ring 2. Secure the turning disk with its attachment screws. Robot v. 175/2.55: 6 pcs, M14 x 25, tightening torque: 175 Nm. Robot v. 225/2.55, 175/2.8, 125/3.2 or 200/ 2.75: 12 pcs, M12 x 30, 12.9 quality UNBRAKO, tightening torque: 100 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 3. Refill the gearbox 6 with oil. Detailed in "Oil change, gearbox axis 6" in the Maintenance Manual. 4. Refit any equipment removed during disassembly, to the turning disk. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 46 A 3HAC 16247-1 3 Repair activities, manipulator 3.2.3 Removal of complete wrist unit 3.2.3 Removal of complete wrist unit Location of wrist unit The wrist unit is located in the frontmost part of the upper arm as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Wrist complete on page 211. A H I B C G D E F xx0200000184 3HAC 16247-1 A Wrist unit B Turning disk C Cover, wrist unit D Cover, upper arm tube E Connectors, upper arm tube, with cable bracket (R3.FB5, R3.MP5) F Cable bracket, cables motor axis 6 G Suffusion to lifting tool, wrist unit H Wrist unit attachment screws and washers I Upper arm tube A 47 3 Repair activities, manipulator 3.2.3 Removal of complete wrist unit Required equipment Equipment etc. Spare part no. Art. no. Lifting tool, wrist unit 3HAC 13605-1 Circuit diagram 3HAC 13347-1 Included in Repair Manual, part 2 Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Removal, wrist unit Note These procedures include references to the tools required. The procedure below details how to remove the complete wrist unit. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Axis 5 must be oriented in the correct position (+90 °) to allow opening the motor 6 cover! The complete wrist unit weighs 165 kg! All lifting equipment used must be dimensioned accordingly! Step 48 Action Note/Illustration 1. Remove all equipment fitted to the turning disk. 2. Turn axis 4 to a position where the cover, upper Shown in the figure Location of arm tube and wrist unit, faces upwards. Also wrist unit on page 47! turn axis 5 so that the turning disc faces to the side in order to allow access to the motor 6 cover. 3. Remove the cover, wrist unit, on top of the wrist unit. Shown in the figure Location of wrist unit on page 47! 4. Remove the cover, upper arm tube. Shown in the figure Location of wrist unit on page 47! 5. Remove the cover of motor, axis 6 and disconnect all connectors beneath. A 3HAC 16247-1 3 Repair activities, manipulator 3.2.3 Removal of complete wrist unit Step 6. Action Note/Illustration Loosen the cable bracket on top of the wrist by Shown in the figure Location of unscrewing the three attachment screws. wrist unit on page 47! Two of the attachment screws are located visiC ble at the rear of the bracket (B) and the third located at the bottom of the cable bracket, in B the center (C), shown in the figure to the right. xx0200000254 • B: Attachment screws, rear of cable bracket, 2 pcs • C: Attachment screw, bottom of cable bracket, 1 pc 7. Pick out the cabling from motor, axis 6 and place it safely on the tube. 8. Loosen the cable bracket in the upper arm tube by unscrewing the two screws on top of the tube. Shown in the figure Location of wrist unit on page 47! 9. Disconnect the motor axis 5 by disconnecting the two connectors in the upper arm tube (R3.FB5, R3.MP5). Shown in the figure Location of wrist unit on page 47! 10. Fit the lifting device to the wrist unit. Art. no. specified in Required equipment on page 48! 11. Slightly raise the wrist unit to unload the screw joint, facilitating removing the attachment screws. 12. Remove the wrist unit attachment screws and washers . Shown in the figure Location of wrist unit on page 47! 13. Pull the wrist unit out, lift it away and place it on a secure surface. 3HAC 16247-1 A 49 3 Repair activities, manipulator 3.2.4 Refitting of complete wrist unit 3.2.4 Refitting of complete wrist unit Location of wrist unit The wrist unit is located in the frontmost part of the upper arm as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Wrist complete on page 211. A H I B C G D E F xx0200000184 50 A Wrist unit B Turning disk C Cover, wrist unit D Cover, upper arm tube E Connectors, upper arm tube, with cable bracket (R3.FB5, R3.MP5) F Cable bracket, cables motor axis 6 G Suffusion to lifting tool, wrist unit H Attachment screws and washers, wrist unit I Upper arm tube A 3HAC 16247-1 3 Repair activities, manipulator 3.2.4 Refitting of complete wrist unit Required equipment Refitting, wrist unit Equipment etc. Spare part no. Art. no. Note Wrist, 175/2.55 3HAC 16627-1 Includes complete axis 6, 3HAC 9744-1/3HAC 16032-1 (Foundry). Includes rotational motor incl. gearbox, 3HAC 7941-29. Wrist, 225/2.55, 175/2.8, 3HAC 16626-1 125/3.2 or 200/2.75 Includes complete axis 6, 3HAC 13890-1/2 (Foundry). Includes rotational motor incl. gearbox, 3HAC 7941-30. Guide pin M12 x 200 3HAC 13056-3 Always use guide pins in pairs! Lifting tool, wrist unit 3HAC 13605-1 Standard toolkit The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. These procedures include references to the tools required. The procedure below details how to refit the complete wrist unit. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Axis 5 must be oriented in the correct position (+90 °) to allow opening the motor 6 cover! The complete wrist unit weighs 165 kg! All lifting equipment used must be dimensioned accordingly! Step 3HAC 16247-1 Action Note/Illustration 1. Fit two guide pins, M12 in the upper arm tube, in two of the wrist unit attachment screw holes. Art. no. specified in Required equipment on page 51! Shown in the figure Location of wrist unit on page 50! 2. Fit the lifting tool to the wrist unit. Art. no. specified Location of wrist unit on page 50! A 51 3 Repair activities, manipulator 3.2.4 Refitting of complete wrist unit Step Action Note/Illustration 3. Lift the wrist unit and guide it to the upper arm tube with help of the guide pins. Make sure the cabling from motor, axis 5 is safely run into the arm tube and doesn´t get into a scrape. 4. Secure the wrist unit with 10 of the 12 attach- Shown in the figure Location of wrist ment screws and washers. unit on page 50! 12 pcs: M12 x 50, 12.9 quality UNBRAKO, tightening torque: 115 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 5. Remove the guide pins and secure the two remaining attachment screws as detailed above. 6. Remove the lifting tool from the wrist unit. 7. Reconnect the motor axis 5 by connecting the two connectors inside the upper arm tube (R3.FB5, R3.MP5) and secure the cable bracket with the two attachment screws to the tube. 8. In order to have access to motor 6 cover, the axis 5 must be positioned +90 degrees. Place the cabling to motor, axis 6, correctly on the upper arm and gently pull the connectors through the hole on top of wrist unit to motor, axis 6. Shown in the figure Location of wrist unit on page 50! A xx0200000185 Put a loop of cable in this area with cable straps (A), if necessary. The cables are longer to fit to different upper arm lengths. 9. Fasten the cable bracket at top of wrist unit Shown in the figure Location of wrist with three attachment screws. Two of them unit on page 50! are visible at the rear attachment point (B) and the third is located on the bottom of the C cable bracket, right in the center (C), shown B in the figure to the right. xx0200000254 • B: Attachment screws, rear of cable bracket • C: Attachment screw, bottom of cable bracket 10. Reconnect the connectors to motor, axis 6 and refit the motor cover. 52 11. Refit the cover, upper arm tube. Shown in the figure Location of wrist unit on page 50! 12. Refit the cover, wrist unit. Shown in the figure Location of wrist unit on page 50! A 3HAC 16247-1 3 Repair activities, manipulator 3.2.4 Refitting of complete wrist unit Step Action Note/Illustration 13. Recalibrate the robot! Detailed in "Calibration" in the Installation Manual. 14. Refit any equipment previously removed from the turning disk. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 53 3 Repair activities, manipulator 3.2.5 Removal of upper arm 3.2.5 Removal of upper arm Location of upper arm The upper arm is located on top of the manipulator as shown in the figure below. The complete upper arm includes the wrist unit but this instruction also describes how to remove the upper arm when there is no wrist unit mounted. Note! The lifting device is attached differently depending on whether the wrist unit is mounted on the upper arm or not. The attachment points are shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Upper arm on page 209. B A H G B F E C D xx0200000163 54 A 3HAC 16247-1 3 Repair activities, manipulator 3.2.5 Removal of upper arm A Attachment hole for lifting eye, M12 B Attachment for lifting device, upper arm (2 pcs if there is no wrist unit mounted) C Oil plug, draining, gearbox axis 3 D Connectors at cable harness division; R2.M5/6 E Motor, axis 3 F Motor, axis 4 G Attachment screws and washers, upper arm H Sealing, axis 2/3 (between lower arm and gearbox axis 3) Required equipment Equipment Spare part no. Art. no. Lifting eye, VLBG M12 3HAC 16131-1 Lifting device, upper arm 3HAC 15994-1 Lifting tool (chain) 3HAC 15556-1 To be used together with lifting eye, M12 and lifting device, upper arm. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Removal, upper arm Note/Illustration These procedures include references to the tools required. The procedure below details how to remove the upper arm. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The complete upper arm weighs 380 kg without any additional equipment fitted! Use a suitable lifting device to avoid injury to personnel! Step 3HAC 16247-1 Action Note/Illustration 1. Remove all equipment fitted to turning disk. 2. Move the manipulator arm to a horisontal position. Shown in the figure Location of Run axis 4 so that the attachment hole for lifting eye upper arm on page 54! is faced upwards! A 55 3 Repair activities, manipulator 3.2.5 Removal of upper arm Step 56 Action Note/Illustration 3. Fit the lifting eye, VLBG M12 to the attachment hole on the upper arm, if the wrist unit is mounted. Art. no. specified in Required equipment on page 55! Shown in the figure Location of upper arm on page 54! 4. Upper arm including wrist unit: Fit one of the pieces included in lifting device, upper arm to the attachment for lifting device on the upper arm. Art. no. specified in Required equipment on page 55! Fasten the lifting device on the front attachment, as shown in the figure above! 5. Upper arm without wrist unit: Fit the lifting device, upper arm to the attachments for lifting device . Art. no. specified in Required equipment on page 55! The attachments are shown in the figure Location of upper arm on page 54! 6. Fasten the lifting tool (chain) onto the lifting eye, the lifting device and an overhead crane. Art. no. specified in Required equipment on page 55! 7. Drain the oil from gearbox axis 3. Detailed in "Oil change, gearbox axis 3" in the Maintenance Manual. 8. Disconnect connector R2.M5/6 at the cable harShown in the figure Location of ness division as well as all remaining connections upper arm on page 54! to the upper arm. 9. Remove the cover on top of the motors, axis 3 and 4 and disconnect all connectors inside motors. 10. Remove all brackets securing cabling to the upper arm by unscrewing their attachment screws respectively. 11. Raise the lifting equipment to take the weight of the upper arm. 12. Carefully remove the attachment screws and wash- Shown in the figure Location of ers, upper arm. upper arm on page 54! 13. Lift the upper arm and place it on a secure surface. Make sure the lift is done completely level! In case of necessary adjustments, use the shortening loops on the lifting tool (chain), but make sure to place the chain the right way through the loops! 14. Remove the sealing, axis 2/3 from the lower arm. Shown in the figure Location of upper arm on page 54! A 3HAC 16247-1 3 Repair activities, manipulator 3.2.6 Refitting of upper arm 3.2.6 Refitting of upper arm Location of upper arm The upper arm is located on top of the manipulator as shown in the figure below. The complete upper arm includes the wrist unit but this instruction also describes how to refit the upper arm when there is no wrist unit mounted. Note! The lifting device is attached differently depending on whether the wrist unit is mounted on the upper arm or not. The attachment points are shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Upper arm on page 209. B A H G B F E C D xx0200000163 3HAC 16247-1 A 57 3 Repair activities, manipulator 3.2.6 Refitting of upper arm A Attachment hole for lifting eye, M12 B Attachment for lifting device, upper arm (2 pcs if there is no wrist unit mounted) C Oil plug, draining, gearbox axis 3 D Connectors at cable harness division; R2.M5/6 E Motor, axis 3 F Motor, axis 4 G Attachment screws and washers, upper arm H Sealing, axis 2/3 (between lower arm and gearbox axis 3) Required equipment Equipment Spare part no. Art. no. Sealing, axis 2/3 3HAC 12443-2 Always use a new sealing when reassembling! Washer, axis 3 (3 pcs) 3HAC 12703-1 To be replaced if damaged. Lifting eye, VLBG M12 3HAC 16131-1 Lifting device, upper arm 3HAC 15994-1 Lifting tool (chain) 3HAC 15556-1 To be used together with lifting eye, M12 and lifting device, upper arm. Guide pins, sealing axis 2/3 80 mm 3HAC 14628-1 For guiding "Sealing, axis 2/3". Guide pins, sealing axis 2/3 100 mm 3HAC 14628-2 For guiding "Sealing, axis 2/3". Power supply 24 VDC, max 1,5A. For releasing the brakes. Rotation tool, motor 3HAC 17105-1 Used to rotate the motor shaft beneath the motor cover, when brakes are released with 24 VDC power supply. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Refitting, upper arm Note These procedures include references to the tools required. The procedure below details how to refit the upper arm. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. 58 A 3HAC 16247-1 3 Repair activities, manipulator 3.2.6 Refitting of upper arm Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The complete upper arm weighs 380 kg without any additional equipment fitted! Use a suitable lifting device to avoid injury to personnel! Step 1. Action Note/Illustration Fit the two guide pins, sealing axis 2/3 in Always use a new sealing when reastwo of the attachment screw holes on sembling! gearbox 3, see figure beside. Art. no. specified in Required equipGuide the new sealing, axis 2/3 into posi- ment on page 58! tion with the guide pins, on gearbox 3. A B C xx0200000166 3HAC 16247-1 • A: Holes for guide pins on the gearbox. • B: Holes in the gearbox, axis 3, for the attachment screws, upper arm (33 pcs). • C: Gearbox attachment screws (not affected in this instruction). 2. Fit the lifting eye, VLBG M12 to the attach- Art. no. specified in Required equipment hole on the upper arm, if there is a ment on page 58! wrist unit mounted. Shown in the figure Location of upper arm on page 57! 3. Upper arm including wrist unit: Fit one of the pieces included in the lifting device, upper arm to the attachment for the lifting device on the upper arm. Fasten the lifting device on the front attachment, as shown in figure above! 4. Upper arm without wrist unit: Fit the lift- Art. no. specified in Required equiping device, upper arm to the attachments ment on page 58! for the lifting device on the upper arm. Shown in the figure Location of upper arm on page 57! 5. In order to release the brake, connect the Connect to connector R2.MP3 24 VDC power supply to motor axis 3, • +: pin 2 after removing the motor cover. • -: pin 5 A Art. no. specified in Required equipment on page 58! Shown in the figure Location of upper arm on page 57! 59 3 Repair activities, manipulator 3.2.6 Refitting of upper arm Step Action Note/Illustration 6. Fasten the lifting tool (chain) onto the lift- Art. no. specified in Required equiping eye, the lifting device and an overhead ment on page 58! crane. 7. Lift the upper arm and run to its mounting position. Make sure the lift is done completely level! 8. Fit in the gearbox attachment holes with the attachment holes on the lower arm with the guide pins. It may be necessary to turn the gear by rotating the motor pinion with a rotation tool, motor beneath the motor cover. Art. no. specified in Required equipment on page 58! A xx0200000165 The rotation tool is used beneath the motor cover, directly on the motor shaft as shown in figure above. • A: Rotation tool 60 9. Fit the three washers to be placed beneath the attachment screws. Shown in the figure Location of upper arm on page 57! 10. Insert 31 of the 33 attachment screws, upper arm into the attachment holes in the lower arm. Do not remove the guide pins until the attachment screws are tightened as detailed below. Shown in the figure Location of upper arm on page 57! Removing the plastic mechanical stops may be required before fitting the upper arm. If guide pins are removed before the screws are tightened, the sealing can be involuntarily moved into wrong position. 11. Secure the lower arm to gearbox axis 3, with the attachment screws. 33 pcs: M12 x 50; 12.9 quality UNBRAKO, tightening torque: 120 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 12. Remove the guide pins and fit the two remaining attachment screws. Tighten them as detailed above! 13. Disconnect the brake release voltage and remove the rotation tool from the motor. 14. Remove the lifting devices. 15. Refit any cabling removed during the removal process. 16. Reconnect all connectors inside motors, axis 3 and 4. Refit the motor covers. 17. Reconnect connector R2.M5/6 gently at the cable harness division point, with 2 screws, M6. Be careful not to bend the attachment plate when fastening the screws! A 3HAC 16247-1 3 Repair activities, manipulator 3.2.6 Refitting of upper arm Step Action Note/Illustration 18. Perform a leakdown test. Detailed in Performing a leak-down test on page 21. 19. Refill the gearbox with oil. Detailed in "Oil change, gearbox axis 3" in the Maintenance Manual. 20. Recalibrate the robot. Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 61 3 Repair activities, manipulator 3.3.1 Removal of complete lower arm Section 3.3: Lower arm 3.3.1 Removal of complete lower arm Location of lower arm The lower arm is located as shown in the figure below. A more detailed view of the component and its position may be found in the Foldout section Frame-Lower arm 2 on page 207. A D B C xx0200000255 62 A Lower arm B Pivot point, axis 2 C Front shaft, balancing device, including securing screw D Attachment for lifting eye, M12, balancing device A 3HAC 16247-1 3 Repair activities, manipulator 3.3.1 Removal of complete lower arm Attachment points, lower arm The lower arm attachment points are located as shown in the figure below: • The figure (1) shows gearbox axis 3, but the location of sealing axis 2/3 in relation to the gearbox is identical for axis 2. • The figure (2) shows a cut view through the lower arm pivot point in axis 2 (item B in the figure above!). 201 A B (1) (2) C 404 401 202 204 406 402 403 D 405 409 E xx0200000031 3HAC 16247-1 A Gear box B Lower arm C Balancing device piston rod ear D Frame E Shaft hole 201 Sealing, axis 2/3 202 Attachment screw 204 Washer 401 Bearing 402 Thrust washer 403 Bushing 404 Retaining ring 405 Shaft 406 Protection plug 409 Protection washer A 63 3 Repair activities, manipulator 3.3.1 Removal of complete lower arm Required equipment Equipment, etc. Spare part no. Art. no. Lifting tool, lower arm 3HAC 14691-1 Tool that may be rent from ATRP/S. Press tool, axis 2 shaft 3HAC 13452-1 Lifting eye, M12 3HAC 14457-3 Used to lift the balancing device. Puller tool, balancing device shaft 3HAC 12475-1 Used to pull out the shaft from the balancing device front ear. Hydraulic pump 80Mpa 3HAC 13086-1 To be used together with the press tool, axis 2 shaft and the puller tool. Hydraulic pump 80 Mpa (Glycerin) 3HAC 13086-2 To be used together with the press tool, axis 2 shaft and the puller tool. Retaining ring plier - Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Removal, lower arm Note These procedures include references to the tools required. The procedure below details how to remove the complete lower arm. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The lower arm weighs 160 kg! All lifting equipment used must be dimensioned accordingly! Do not under any circumstances, deal with the balancing device in any other way than that detailed in the product documentation! For example, attempting to open the balancing device is potentially lethal! Step 64 Action Note/Illustration 1. Remove the upper arm. Detailed in section Removal of upper arm on page 54. 2. Disconnect and remove the cables from Detailed in section Removal of cable harinside the lower arm. ness on page 24. Release any cable attachments. A 3HAC 16247-1 3 Repair activities, manipulator 3.3.1 Removal of complete lower arm Step Action Note/Illustration 3. Apply the lifting eye to the balancing device and raise to unload the device. Art. no. specified in Required equipment on page 64. Attachment shown in the figure Location of lower arm on page 62. 4. Unload the balancing device in order to Detailed in section Unloading the balancmake the piston rod and front ear adjust- ing device on page 89. able when pulling the front shaft out. 5. Remove the securing screw from the balancing device front shaft. 6. Apply the shaft puller tool to the shaft through the hole in the frame. The shaft has a M20 thread diameter and a 35 mm depth of thread, as shown 35 in the figure to the right. xx0300000056 Pull the shaft out using the puller tool Note! The dimension of the shaft puller and the hydraulic pump. tool is M20. Do not mix up with the shaft press tool used when mounting the shaft. Art. no. specified in Required equipment on page 64. 7. Lower the balancing device until it rests safely against the bottom of the frame. 8. Move the lower arm backwards to the lowest position possible. 9. Apply the lifting tool to the lower arm. Shown in the figure Location of lower arm on page 62. xx0300000015 10. Drain the oil from gearbox 2. 11. 3HAC 16247-1 Art. no. specified in Required equipment on page 64! Detailed in "Oil change, gearbox 2" in the Maintenance Manual. Raise the tool to unload the lower arm. 12. Remove the protection plug. Shown in the figure Attachment points, lower arm on page 63! 13. Remove the protection washer and the retaining ring. Shown in the figure Attachment points, lower arm on page 63! Use a plier for the retaining ring. A 65 3 Repair activities, manipulator 3.3.1 Removal of complete lower arm Step Action Note/Illustration 14. Fit the press (/puller) tool to the shaft as Art. no. specified in Required equipment shown in the figure to the right and on page 64! mount the hydraulic pump to it. 15. Pull the shaft out. 16. Remove the lower arm attachment screws and washers that attaches the lower arm to the gearbox 2. 17. Lift the lower arm down and place it on a secure surface. 18. Remove the bearing and thrust washer from the shaft hole in the lower arm. 19. Remove the sealing from the lower arm. Shown in the figure Attachment points, lower arm on page 63! On reassembly a new sealing must be used! xx0300000010 66 A Shown in the figure Attachment points, lower arm on page 63! Shown in the figure Attachment points, lower arm on page 63! On reassembly a new bearing must be used! 3HAC 16247-1 3 Repair activities, manipulator 3.3.2 Refitting of complete lower arm 3.3.2 Refitting of complete lower arm Location of lower arm The lower arm is located as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Frame-Lower arm 2 on page 207 A D B C xx0200000255 3HAC 16247-1 A Lower arm B Pivot point, axis 2 C Front shaft, balancing device, including securing screw D Attachment for lifting eye, M12, balancing device A 67 3 Repair activities, manipulator 3.3.2 Refitting of complete lower arm Attachment points, lower arm The lower arm attachment points are located as shown in the figure below: • The figure (1) shows gearbox axis 3, but the location of sealing axis 2/3 in relation to the gearbox is identical for axis 2. • The figure (2) shows a cut view through the lower arm pivot point in axis 2 (item B in the figure above!). 201 A B (1) (2) C 404 401 202 204 406 402 403 D 405 409 E xx0200000031 68 A Gear box B Lower arm C Balancing device piston rod ear D Frame E Shaft hole 201 Sealing, axis 2/3 202 Attachment screw 204 Washer 401 Bearing 402 Thrust washer 403 Bushing 404 Retaining ring 405 Shaft 406 Protection plug 409 Protection washer A 3HAC 16247-1 3 Repair activities, manipulator 3.3.2 Refitting of complete lower arm Required equipment Equipment, etc. Spare part no. Art. no. Bearing 3HAC 12441-2 Always use a new bearing when reassembling! Sealing, axis 2/3 3HAC 12443-2 Always use a new sealing when reassembling! VK-cover VK 120 x 12 3HAA 2166-23 Mount on new lower arm or replace if damaged. Lifting tool, lower arm 3HAC 14691-1 Tool to be rent from ATRP. Two guidings, 3HAC 14446-1, must be used for guiding the sealing, axis 2/3. Guidings 3HAC 14446-1 For guiding the sealing axis 2/3. Rotation tool, motor 3HAC 17105-1 Used to rotate the motor pinion and gear if necessary, when brakes are released. Power supply 24 VDC, 1.5 A. For releasing the brakes. Press tool, axis 2 shaft 3HAC 13452-1 Press tool, axis 2 bearing 3HAC 13453-1 Hydraulic pump 80 Mpa 3HAC 13086-1 To be used together with the press tools. Hydraulic pump 80 Mpa (Glycerin) 3HAC 13086-2 To be used together with the press tools. Tool that may be rent from ATRP/S. Retaining ring plier - Grease 3HAB 3537-1 Isopropanol 1177 1012-208 For cleaning the shaft. Standard toolkit 3HAC 15571-1 Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Refitting, lower arm Note For lubricating shaft hole. The contents are defined in section Standard toolkit on page 18! These procedures include references to the tools required. The procedure below details how to refit the complete lower arm. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. 3HAC 16247-1 A 69 3 Repair activities, manipulator 3.3.2 Refitting of complete lower arm The lower arm weighs 160 kg! All lifting equipment used must be dimensioned accordingly! Step Action Note/Illustration 1. Fit a new VK-cover on a new lower arm Part no. specified in Required equipment or replace the existing if damaged. on page 69! 2. Fit two guidings in the attachment holes Art no. specified in Required equipment of the lower arm. on page 69! A xx0200000262 A: Attachment holes for the two guidings 3. Fit the new sealing, axis 2/3 on the guidings. Always use a new sealing when reassembling! Art no. specified in Required equipment on page 69! 4. Apply the lifting tool to the lower arm. Art no. specified in Required equipment on page 69! 5. Lift the lower arm and run it to its mounting position. 6. In case the holes of the lower arm and Connect power supply to connector the ones of the gearbox axis 2 doesn´t R2.MP2 match, use power supply to release the • +: pin 2 motor axis 2 brakes and rotate the pin• -: pin 5 ion and gear with the rotational tool. A xx0200000165 The rotation tool (A) is used beneath the motor cover, directly on the motor shaft as shown in figure above. Art no. specified in Required equipment on page 69! 7. 70 Secure the lower arm with 31 of the 33 attachment screws and washers in gearbox 2. A 33 pcs: M12 x 50, 12.9 quality UNBRAKO, tightening torque: 120 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. Shown in the figure Attachment points, lower arm on page 68! 3HAC 16247-1 3 Repair activities, manipulator 3.3.2 Refitting of complete lower arm Step Action Note/Illustration 8. Remove the guidings and secure the two remaining screws as detailed above! 9. Clean the shaft with isopropanol. 10. Apply grease to the shaft hole. 11. Art no. specified in Required equipment on page 69! Art no. specified in Required equipment on page 69! Push the shaft in by hand. D E F A B C xx0300000014 • A: Retaining ring • B: Protection washer • C: Bearing • D: Thrust washer • E: Shaft • F: Protection plug 12. Apply the press tool, axis 2 shaft against the shaft. Art no. specified in Required equipment on page 69! 13. Tighten the M16 nut. Tightening torque: 20 Nm. 14. Set the indicator to zero and press the Approx. force: 30-50 kN. shaft in with the hydraulic cylinder of the press tool. 15. Increase the pressure of the glycerin pump to 50 kN. 16. Check the measurement dial readout. Correct value: 2.45 mm ±0.15 mm. 17. Remove the press tool, axis 2 shaft. Release the pressure from the glycerin pump first, then from the hydraulic cylinder (approximately 1/2 minute after), in order to avoid movement of the shaft. 18. Refit the thrust washer to the shaft. Shown in the figure Attachment points, lower arm on page 68! 19. Apply grease to the location of the shaft Art no. specified in Required equipment where the bearing is to be mounted. on page 69! 20. Press the bearing in with the press tool, Always use a new bearing when reassemaxis 2 bearing. bling! Art no. specified in Required equipment on page 69! 3HAC 16247-1 21. Refit the protection washer and the retaining ring. Shown in the figure Attachment points, lower arm on page 68! 22. Refit the protection plug. Shown in the figure Attachment points, lower arm on page 68! A 71 3 Repair activities, manipulator 3.3.2 Refitting of complete lower arm Step Action Note/Illustration 23. Refit and restore the balancing device. Detailed in section Refitting of balancing device on page 85. 24. Refit the upper arm. Detailed in section Refitting of upper arm on page 57. 25. Perform a leak-down test. Detailed in section Performing a leakdown test on page 21. 26. Refill the gearbox with oil. Detailed in section "Oil change, gearbox axis 2" in the Maintenance Manual. 27. Refit and reconnect all cables inside the Detailed in section Refitting of cable harlower arm. ness on page 30. Resecure any cable attachments. 28. Recalibrate the robot! Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 72 A 3HAC 16247-1 3 Repair activities, manipulator 3.4.1 Removal of SMB related equipment Section 3.4: Frame and base 3.4.1 Removal of SMB related equipment Location of SMB related equipment The SMB related equipment (SMB = serial measurement board) is located on the left hand side of the frame as shown in the figure below. (IRB 7600 shown.) Note that the manipulator is shown with the SMB cover already removed! A B C D E F G H xx0200000203 A Attachment screw, SMB battery cover B SMB battery cover C SMB battery D Cable, battery/SMB board E SMB cover F Attachment screw, SMB cover G SMB unit H Pins Required equipment Equipment, etc. Spare part. no. Art. no. Removal, battery Note Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Circuit Diagram 3HAC 13347-1 Included in Repair Manual, part 2 The procedure below details how to remove the SMB battery. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! 3HAC 16247-1 A 73 3 Repair activities, manipulator 3.4.1 Removal of SMB related equipment - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Follow these instruction to prevent the unit to be damaged from ESD: The unit is sensitive to electrostatic discharge. It will be destroyed if subjected to electrostatic voltages. Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Removal, SMB unit Action Note/Illustration 1. Remove the SMB battery cover by unscrew- Shown in the figure Location of ing its attachment screws. SMB related equipment on page 73! 2. Disconnect the cable, battery/SMB board from the battery. 3. Remove the SMB battery. Shown in the figure Location of Battery includes protection circuits. Replace it SMB related equipment on page 73! only with the specified spare part or with an ABB approved eqvivalent. Shown in the figure Location of SMB related equipment on page 73! The procedure below details how to remove the SMB unit. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Follow these instruction to prevent the unit to be damaged from ESD: The unit is sensitive to electrostatic discharge. It will be destroyed if subjected to electrostatic voltages. Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step 74 Action Note/Illustration 1. Remove the SMB cover by unscrewing Shown in the figure Location of SMB its attachment screws. related equipment on page 73! 2. Remove the connectors X8, X9 and X10 from the brake release board, if need of more space. 3. Remove the locknut and washer from the pins securing the board. 4. Gently disconnect the connectors from Connectors R1.SMB1-3, R1.SMB4-6 and the SMB unit when pulling the board out. R2.SMB 5. Disconnect the battery cable from the SMB unit. A Shown in the figure Location of SMB related equipment on page 73! 3HAC 16247-1 3 Repair activities, manipulator 3.4.2 Refitting of SMB related equipment 3.4.2 Refitting of SMB related equipment Location of SMB related equipment The SMB related equipment (SMB = serial measurement board) is located on the left hand side of the frame as shown in the figure below. (IRB 7600 shown.) Note that the manipulator is shown with the SMB cover already removed! A B C D E F G H xx0200000203 A Attachment screw, SMB battery cover B SMB battery cover C SMB battery D Cable, battery/SMB board E SMB cover F Attachment screw, SMB cover G SMB unit H Pins Required equipment Equipment, etc. Spare part no. Art. no. 3HAC 16247-1 SMB Unit 3HAC 13149-1 SMB Battery 3HAC 16831-1 Note Battery includes protection circuits. Replace it only with given spare part no. or an ABB approved eqvivalent. Cable, battery/SMB board 3HAC 13151-1 Circuit Diagram 3HAC 13347-1 Included in Repair Manual, part 2 Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! A 75 3 Repair activities, manipulator 3.4.2 Refitting of SMB related equipment Refitting, battery The procedure below details how to refit the SMB battery. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Follow these instruction to prevent the unit to be damaged from ESD: The unit is sensitive to electrostatic discharge. It will be destroyed if subjected to electrostatic voltages. Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Refitting, SMB unit Action Note/Illustration 1. Reconnect the cable, battery/SMB board to Art. no. is specified in Required equipthe battery and fit the SMB battery. ment on page 75! Shown in the figure Location of SMB related equipment on page 75! 2. Secure the SMB battery cover with its attachment screws . Shown in the figure Location of SMB related equipment on page 75 3. Recalibrate the robot. Detailed in "Calibration" in the Installation Manual. The procedure below details how to refit the SMB unit. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Follow these instruction to prevent the unit to be damaged from ESD: The unit is sensitive to electrostatic discharge. It will be destroyed if subjected to electrostatic voltages. Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step 76 Action Note/Illustration 1. Connect the battery cable to the SMB board. 2. Fit the SMB unit onto the pins and con- Art. no. is specified in Required equipment nect all connectors to the board. on page 75! Shown in the figure Location of SMB related equipment on page 75! R1.SMB1-3, R1.SMB4-6 and R2.SMB 3. Secure the SMB unit to the pins with the locknut and washer. A 3HAC 16247-1 3 Repair activities, manipulator 3.4.2 Refitting of SMB related equipment Step Action Note/Illustration 4. If disconnected, reconnect the connectors X8, X9 and X10 to the brake release board. 5. Secure the SMB cover with its attach- Shown in the figure Location of SMB ment screws. related equipment on page 75! 6. Recalibrate the robot! Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 77 3 Repair activities, manipulator 3.4.3 Removal of brake release unit 3.4.3 Removal of brake release unit Location of brake release unit The brake release unit is located together with the SMB unit on the left hand side of the frame, right below the gearbox, axis 2, as shown in figure below (IRB 7600 shown). Some of the early designs are equipped with a separate box on the frame, with the brake release unit inside, not shown in the figure. B A C E F D xx0200000226 A Brake release unit B Attachment screws, brake release unit (4 pcs) C Buttons D SMB battery pack E SMB cover F Attachment screws, SMB cover Required equipment Equipment, etc. Spare part no. Art. no. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. 78 Note These procedures include references to the tools required. A 3HAC 16247-1 3 Repair activities, manipulator 3.4.3 Removal of brake release unit Removal, brake release unit The procedure below details how to remove the brake release unit. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Follow these instruction to prevent the unit to be damaged from ESD: The unit is sensitive to electrostatic discharge. It will be destroyed if subjected to electrostatic voltages. Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Open the SMB cover by unscrewing the attachment screws. Let the battery stay connected, to avoid the need of synchronization of the robot! Shown in the figure Location of brake release unit on page 78! 2. Disconnect the connectors X8, X9 and X10 from the brake release unit. B A 2 2 2 1 1 1 C xx0200000129 • A: Connector X8 • B: Connector X9 • C: Connector X10 Location of brake release unit shown in the figure Location of brake release unit on page 78! 3HAC 16247-1 3. Unscrew the four attachment screws, brake release unit. 4. Remove the brake release unit from the plate. A Shown in the figure Location of brake release unit on page 78! 79 3 Repair activities, manipulator 3.4.4 Refitting of brake release unit 3.4.4 Refitting of brake release unit Location of brake release unit The brake release unit is located together with the SMB unit on the left hand side of the frame, right below the gearbox, axis 2, as shown in figure below (IRB 7600 shown). Some early designs are equipped with a separate box on the frame, with the brake release unit inside, not shown in the figure. B A C E F D xx0200000226 A Brake release unit B Attachment screws, brake release unit (4 pcs) C Buttons D SMB battery pack E SMB cover F Attachment screws, SMB cover Required equipment Equipment, etc. 80 Spare part no. Art. no. Note Brake release unit with buttons 3HAC 16035-1 Located together with the SMB-unit at the left hand side of the frame. Brake release circuit 3HAC 14301-1 The early version, where brake release unit is located in a separate box on the frame. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! A 3HAC 16247-1 3 Repair activities, manipulator 3.4.4 Refitting of brake release unit Equipment, etc. Spare part no. Art. no. Note Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Refitting, brake release unit These procedures include references to the tools required. The procedure below details how to refit the brake release unit. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Follow these instruction to prevent the unit to be damaged from ESD: The unit is sensitive to electrostatic discharge. It will be destroyed if subjected to electrostatic voltages. Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Fasten the brake release unit on the plate Shown in the figure Location of brake with the attachment screws. release unit on page 80! Art. no. specified in Required equipment on page 80! 2. Connect the connectors X8, X9 and X10 to the brake release unit. B A 2 2 2 1 1 1 C xx0200000129 3. Close the SMB cover with attachment screws. If the battery has been disconnected the robot must be synchronized. • A: Connector X8 • B: Connector X9 • C: Connector X10 Shown in the figure Location of brake release unit on page 80! Eventual synchronization detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 81 3 Repair activities, manipulator 3.4.5 Removal of balancing device 3.4.5 Removal of balancing device Location of balancing device The balancing device is located on rear top of the frame as shown in the figure below. A C I,J D, E H G B L K F xx0200000223 A Balancing device B Hole for lower arm locking screw C Attachment hole for lifting eye D Rear cover E Support shaft inside (included in balancing device 3HAC 14678-1) F Attachment screws, rear cover G Balancing device front eye, including shaft and securing screw H Hole in the frame through which shaft puller tool is to be inserted I Bearing attachment J Parallel pin (inside bearing attachment) K Plug L Attachment screws, bearing attachments Required equipment Equipment, etc 82 Spare part no. Art. no. Note Locking screw 3HAA 1001-266 M16 x 60. For securing the lower arm. Lifting eye, M12 3HAC 14457-3 Press tool, balancing device 3HAC 15767-1 Puller tool, balancing device shaft 3HAC 12475-1 A 3HAC 16247-1 3 Repair activities, manipulator 3.4.5 Removal of balancing device Equipment, etc Removal, balancing device Spare part no. Art. no. Note Hydraulic cylinder 3HAC 11731-1 To be used with press tool 3HAC 15767-1. Hydraulic pump 3HAC 13086-1 To be used with hydraulic cylinder, 3HAC 11731-1. Securing screw 9ADA 183-66 M12 x 35, 2 pcs required. For securing the bearing attachments to the balancing device when lifting. Guide pin, M16 x 300 3HAC 13120-5 Always use guide pins in pairs Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! The procedure below details how to remove the balancing device. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Do not under any circumstances, deal with the balancing device in any other way than that detailed in the product documentation! For example, attempting to open the balancing device is potentially lethal! The balancing device weighs 210 kg! All lifting equipment used must be dimensioned accordingly! Step Action Note/Illustration 1. Run the lower arm to a position close to the calibration position. 2. Secure the lower arm to the frame by inserting the locking screw (1) into the hole. 1 xx0200000454 Art. no. specified in Required equipment on page 82! 3. 3HAC 16247-1 Apply lifting eye to the balancing device, and raise to unload the device. A Art. no. specified in Required equipment on page 82! 83 3 Repair activities, manipulator 3.4.5 Removal of balancing device Step 84 Action Note/Illustration 4. Unload the balancing device with the press tool in order to make the piston rod and front ear adjustable when pulling the shaft out. Art. no. specified in Required equipment on page 82! Detailed in Unloading the balancing device on page 89. 5. Remove the securing screw from the shaft. Shown in the figure Location of balancing device on page 82! 6. Apply the shaft puller tool to the shaft through the hole in the frame. The shaft has a M20 thread diameter and a 35 mm depth of thread, as shown in the 35 figure to the right. xx0300000056 Pull the shaft out using the puller tool and Note! The dimension of the shaft puller the hydraulic pump. tool is M20. Do not mix up with the shaft press tool used when mounting the shaft. Art. no. specified in Required equipment on page 82! The hole in the frame is shown in the figure Location of balancing device on page 82! 7. Restore the balancing device. 8. Secure the two bearing attachments to the Shown in the figure Location of balancbalancing device by replacing the plug on ing device on page 82! the outside of each attachment, with a 2pcs: M12 x 35. screw. 9. Remove the two bearing attachments from Shown in the figure Location of balancthe frame by unscrewing their four attach- ing device on page 82! ment screws. Make sure the parallel pins inside are not lost! 10. Fit two guide pins, through the upper holes of the bearing attachments, to the frame. 11. Lift the balancing device gently backwards Note! Make sure not to burden the to a secure area, allowing the bearing guide pins with the weight of the balattachments to slide on the guide pins. ancing device! A Detailed in Restoring the balancing device on page 91. Art. no. specified in Required equipment on page 82! 3HAC 16247-1 3 Repair activities, manipulator 3.4.6 Refitting of balancing device 3.4.6 Refitting of balancing device Location of balancing device The balancing device is located on rear top of the frame as shown in the figure below. A C I,J D, E H G B L K F xx0200000223 A Balancing device B Hole for lower arm locking screw C Attachment hole for lifting eye D Rear cover E Support shaft inside (included in balancing device 3HAC 14678-1) F Attachment screws, rear cover G Balancing device front eye shaft, including securing screw H Hole through which shaft puller tool is to be inserted I Bearing attachment J Parallel pin (inside bearing attachment) K Plug L Attachment screws, bearing attachments Required equipment 3HAC 16247-1 Equipment Spare part no. Art. no. Note Balancing device 3HAC 16198-1 IRB 6600. Includes balancing device 3HAC 14678-1! Includes o-rings 3HAB 3772-44. Balancing device 3HAC 16907-1 IRB 6650. Includes balancing device 3HAC 16189-1! Includes o-rings 3HAB 3772-44. A 85 3 Repair activities, manipulator 3.4.6 Refitting of balancing device Equipment Spare part no. Art. no. O-ring 3HAB 3772-44 Locking screw 3HAA 1001-266 M16 x 60. For securing the lower arm. Securing screw 9ADA 183-66 M12 x 35, 2 pcs required. For securing the bearing attachments to the balancing device when lifting. Bearing grease 3HAB 3537-1 For lubricating the o-rings and the shaft. Grease 3HAA 1001-294 80 ml, Optimol PDO. For lubrication of spherical roller bearing in ear, in case of new balancing device. 3 pcs, to be replaced if damaged! Locking liquid Loctite 243. To apply to the securing screw in the shaft. Grease pump To lubricate spherical roller bearing. Guide pin, M16 x 300 3HAC 13120-5 Lifting eye, M12 3HAC 14457-3 Press tool, balancing device 3HAC 15767-1 Press tool, balancing device shaft 3HAC 17129-1 Hydraulic cylinder 3HAC 11731-1 To be used with press tool 3HAC 15767-1 and press tool, shaft 3HAC 17129-1. Hydraulic pump 3HAC 13086-1 To be used with hydraulic cylinder 3HAC 11731-1. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Refitting, balancing device Note Always use guide pins in pairs. These procedures include references to the tools required. The procedure below details how to refit the balancing device. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. 86 A 3HAC 16247-1 3 Repair activities, manipulator 3.4.6 Refitting of balancing device Do not under any circumstances, deal with the balancing device in any other way than that detailed in the product documentation! For example, attempting to open the balancing device is potentially lethal! The balancing device weighs 210 kg! All lifting equipment used must be dimensioned accordingly! Step 1. Action Note/Illustration Secure the lower arm to the frame by inserting the locking screw into the hole (1). 1 xx0200000454 Art. no. specified in Required equipment on page 85! 3HAC 16247-1 2. Secure the bearing attachments to the bal- Shown in the figure Location of balancing device with two screws, on the out- ancing device on page 85! side of the attachments. M12 x 35, 2 pcs. 3. Refit the two parallel pins in the frame. 4. Fit two guide pins to the upper holes in the frame, where the bearing attachments are to be attached. 5. Fit the lifting eye to the balancing device. 6. Lift the balancing device and bring it forward, Note! Make sure not to burden the gliding the bearing attachments on to the guide pins with the weight of the balguide pins (upper holes). ancing device! 7. Remove the guide pins. 8. Secure the rear of the balancing device by Shown in the figure Location of balfastening the two bearing attachments to the ancing device on page 85! frame with their four attachment screws. 4 pcs, M16x70, 12.9 quality UNBRAKO, tightening torque: 300 Nm ±45 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 9. Remove the screws from outside of the bearing attachments and refit the plugs. 10. Raise the balancing device to a position where the front shaft may be inserted through the piston shaft front eye. A Shown in the figure Location of balancing device on page 85! Art. no. specified in Required equipment on page 85! 87 3 Repair activities, manipulator 3.4.6 Refitting of balancing device Step Action Note/Illustration 11. Unload the balancing device with the press tool. Detailed in Unloading the balancing device on page 89. Art. no. specified in Required equipment on page 85! For an easier reassembling of the shaft, the piston rod may be pressed out more than necessary and then pressed in when fitting the shaft. 12. Lubricate the shaft with grease. Art. no. specified in Required equipment on page 85! 13. Apply the shaft press tool to the lubricatedshaft through the hole in the frame. Fit the shaft using the shaft press tool and the hydraulic pump. The shaft and the hole in the frame are shown in the figure Location of balancing device on page 85! Art. no. specified in Required equipment on page 85! Note! Make sure the shaft is pressed all the way to the bottom. 14. Refit the securing screw in to the shaft using M16x180, tightening torque: 50 Nm. locking liquid. Locking liquid specified in Required equipment on page 85! 15. When assembling a new device: Lubricate the bearing in the ear with grease through the lubricating nipple, with a grease pump. Fill until excessive grease pierces between the shaft and the sealing spacer. Art. no. and amount specified in Required equipment on page 85! Lubrication further detailed in "Lubrication, balancing device bearing" in the Maintenance Manual. 16. Restore the balancing device. Detailed in Restoring the balancing device on page 91. 17. Remove the locking screw (1) that secures the lower arm to the frame. 1 xx0200000454 When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 88 A 3HAC 16247-1 3 Repair activities, manipulator 3.4.7 Unloading the balancing device 3.4.7 Unloading the balancing device Press tool and hydraulic cylinder This section implies that the lower arm is already secured according to the instruction for the current repair activity, e.g removal of the balancing device. The figure below shows the hydraulic cylinder mounted on the press tool. A C B 1 0 D xx0200000174 A Bolt (4 pcs) B Hydraulic cylinder C Fix plate D Moving pin with marking Required equipment Equipment, etc. 3HAC 16247-1 Spare part no. Art. no. Note Press tool, balancing device 3HAC 15767-1 Hydraulic cylinder 3HAC 11731-1 To be used with press tool 3HAC 15767-1. Hydraulic pump 3HAC 13086-1 To be used with hydraulic cylinder, 3HAC 11731-1. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18. A 89 3 Repair activities, manipulator 3.4.7 Unloading the balancing device Unloading the balancing device The procedure below details how to unload the balancing device, using the press tool 3HAC 15767-1. How to remove the press tool, is detailed in section Restoring the balancing device on page 91. Do not under any circumstances, deal with the balancing device in any other way than that detailed in the product documentation! For example, attempting to open the balancing device is potentially lethal! Step 1. Action Note/Illustration Remove the rear cover of the balancing device, by unscrewing the attachment screws (E). E xx0200000175 • 90 E: Rear cover attachment screws (4 pcs) 2. Remove the support shaft. 3. Remove the o-ring. 4. Mount the press tool, balancing device to the rear of the balancing device with enclosed bolts. Tighten them properly! Art. no. specified in Required equipment on page 89! See the figure Press tool and hydraulic cylinder on page 89! 5. Fit the hydraulic cylinder to the press tool. Art. no. specified in Required equipment on page 89! See the figure Press tool and hydraulic cylinder on page 89! 6. Connect the hydraulic pump to the cylinder. Art. no. specified in Required equipment on page 89! 7. Increase the pressure and press until See the figure Press tool and hydraulic the marking on the moving pin indicates cylinder on page 89! the correct position (flushed with the sur- Do not apply more pressure than necesface). sary, it could damage bearings and sealings at the shaft. 8. Turn the fix plate to position 1 in order to See the figure Press tool and hydraulic lock the tool in loaded condition. cylinder on page 89! 9. Unload the hydraulic cylinder. 10. The hydraulic cylinder may now be removed from the tool, when necessary. A 3HAC 16247-1 3 Repair activities, manipulator 3.4.8 Restoring the balancing device 3.4.8 Restoring the balancing device Press tool and hydraulic cylinder Restoration is done after repair work that has included the unloading of the balancing device. The figure below shows the hydraulic cylinder mounted on the press tool. A C B 1 0 D xx0200000174 A Bolt (4 pcs) B Hydraulic cylinder C Fix plate D Moving pin with marking Required equipment Equipment, etc. Spare part no. Art. no. 3HAC 16247-1 Note Hydraulic cylinder 3HAC 11731-1 To be used with press tool 3HAC 15767-1. Hydraulic pump 3HAC 13086-1 To be used with hydraulic cylinder, 3HAC 11731-1. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18. A 91 3 Repair activities, manipulator 3.4.8 Restoring the balancing device Restoring the balancing device The procedure below details how to restore the balancing device, i.e. removing the press tool 3HAC 15767-1. Do not under any circumstances, deal with the balancing device in any other way than that detailed in the product documentation! For example, attempting to open the balancing device is potentially lethal! Step 92 Action Note/Illustration 1. Refit the hydraulic cylinder to the press tool, in case it has been removed. Shown in the figure Press tool and hydraulic cylinder on page 91! 2. Press with the cylinder and the hydraulic Shown in the figure Press tool and pump until the fix plate is movable again. hydraulic cylinder on page 91! Turn the fix plate to position 0. Do not apply more pressure than necessary, it could damage bearings and sealings at the shaft. 3. Unload the cylinder and make sure the moving pin indicates that the tool has returned to its starting position. 4. Remove the hydraulic cylinder. 5. Remove the press tool by unscrewing the Shown in the figure Press tool and bolts. hydraulic cylinder on page 91! 6. Lubricate and refit the o-ring at the rear of the balancing device. 7. Refit the support shaft and the lubricated Make sure the o-rings are seated propo-ring. erly! 8. Refit the rear cover to the balancing device with its attachment screws. A Shown in the figure Press tool and hydraulic cylinder on page 91! 4 pcs: M10x30, tightening torque: 50 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 3HAC 16247-1 3 Repair activities, manipulator 3.5.1 Removal of motor, axis 1 Section 3.5: Motors 3.5.1 Removal of motor, axis 1 Location of motor The motor axis 1 is located on the left hand side of the manipulator as shown in the figure below. xx0200000200 A Motor, axis 1 B Motor attachment screws and washers Required equipment Equipment, etc. Spare part no. Art. no. Lifting tool, motor axis 1, 4, 5 3HAC 14459-1 Removal tool, motor M12 3HAC 14631-1 Always use the removal tools in pairs! Power supply 3HAC 16247-1 Note 24 VDC, 1.5 A. For releasing the brakes. Circuit Diagram 3HAC 13347-1 Included in Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! A 93 3 Repair activities, manipulator 3.5.1 Removal of motor, axis 1 Removal The procedure below details how to remove motor, axis 1. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step Action Note/Illustration 1. Remove the cover for connector access on top of the motor by unscrewing its four attachment screws. 2. Remove the cable gland cover at the cable exit by unscrewing its two attachment screws. xx0200000199 • A: Cable gland cover Make sure the gasket is not damaged! 3. Disconnect all connectors beneath the motor cover. 4. Apply lifting tool, motor axis 1, 4, 5 to the motor. Art. no. specified in Required equipment on page 93! 5. In order to release the brakes, connect the 24 Connect to connector R2.MP1 VDC power supply. • +: pin 2 • 6. Remove the motor by unscrewing its four attachment screws and plain washers. -: pin 5 Shown in the figure Location of motor on page 93! 7. If required, press the motor out of position by Art. no. specified in Required equipfitting removal tool, motor to the motor attach- ment on page 93! ment screw holes. Always use the removal tools in pairs! 8. Lift the motor to get the pinion away from the gear and disconnect the brake release voltage. 9. Remove the motor by gently lifting it straight up. 94 A 3HAC 16247-1 3 Repair activities, manipulator 3.5.2 Refitting of motor, axis 1 3.5.2 Refitting of motor, axis 1 Location of motor The motor axis 1 is located on the left hand side of the manipulator as shown in the figure below. xx0200000200 A Motor, axis 1 B Motor attachment screws and washers Required equipment Equipment, etc. Spare part no. Art. no. Note Motor, axis 1 3HAC 15879-1 Includes motor 3HAC 14673-6. Includes pinion 3HAC 11350-1. Includes o-ring 2152 2012-430. O-ring 2152 2012-430 Must be replaced when reassembling motor! Grease 3HAB 3537-1 Lifting tool, motor axis 1, 4, 5 3HAC 14459-1 Power supply 3HAC 16247-1 Used to lubricate the o-ring. 24 VDC, max. 1,5 A. For releasing the brakes. Circuit Diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! A 95 3 Repair activities, manipulator 3.5.2 Refitting of motor, axis 1 Equipment, etc. Spare part no. Art. no. Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Refitting, motor Note These procedures include references to the tools required. The procedure below details how to refit motor, axis 1. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step Action Note/Illustration 1. Make sure the o-ring on the circumference of the Art no. specified in Required motor is seated properly. Lightly lubricate the o- equipment on page 95! ring with grease. 2. Apply lifting tool, motor axis 1, 4, 5 to the motor. Art no. specified in Required equipment on page 95! 3. In order to release the brake, connect the 24 VDC power supply. Connect to connector R2.MP1 • +: pin 2 • -: pin 5 4. Fit the motor, making sure the motor pinion is properly mated to gearbox of axis 1. Make sure the motor is turned the right way, i.e. connections forwards. Make sure the motor pinion does not get damaged! 5. Secure the motor with four attachment screws and plain washers. M10 x 40, tightening torque: 50 Nm. 6. Disconnect the brake release voltage. 7. Reconnect all connectors beneath the motor cover. 8. Refit the cable gland cover at the cable exit with Make sure the cover is tightly its two attachment screws. sealed! 9. Refit the motor cover with its four attachment screws. Make sure the cover is tightly sealed! 10. Recalibrate the robot! Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 96 A 3HAC 16247-1 3 Repair activities, manipulator 3.5.3 Removal of motor axis 2 3.5.3 Removal of motor axis 2 Location of motor The motor axis 2 is located on the left hand side of the manipulator as shown in the figure below. B D A C xx0200000169 A Motor axis 2 B Hole for lock screw C Cable gland cover (located on the lower side of the motor) D Motor attachment holes (4 pcs) Required equipment Equipment etc. Spare part no. Art. no. Locking screw 3HAA 1001-266 M16 x 60. For securing the lower arm. Lifting tool, motor axis 2, 3, 4 3HAC 15534-1 Power supply 3HAC 16247-1 Note 24 VDC, 1.5 A. For releasing the brakes. Removal tool, motor M12 3HAC 14631-1 Always use the removal tools in pairs! Guide pin, M10 x 150 3HAC 15521-2 For guiding the motor. Guides are to be used in pairs! A 97 3 Repair activities, manipulator 3.5.3 Removal of motor axis 2 Equipment etc. Spare part no. Art. no. Circuit diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Removal, motor Note These procedures include references to the tools required. The procedure below details how to remove the motor, axis 2. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The motor weighs 27 kg! All lifting equipment used must be dimensioned accordingly! Step Action Note/Illustration 1. Run the manipulator to a position close enough to Shown in the figure Location of its calibration position, to allow the lock screw to motor on page 97! be inserted into the hole for lock screw. 2. Lock the lower arm by inserting the lock screw into Art. no. specified in Required the hole. equipment on page 97! 3. Drain the oil from gearbox, axis 2. 4. Remove the cover on top of the motor by unscrewing its four attachment screws. 5. Remove the cable gland cover at the cable exit by Shown in the figure Location of unscrewing its two attachment screws. motor on page 97! Make sure the gasket is not damaged! 6. Disconnect all connectors beneath the motor cover. 7. In order to release the brake, connect the 24 VDC Connect to connector R2.MP2 power supply. • +: pin 2 Detailed in "Oil change, gearbox axis 2" in the Maintenance Manual. • 8. 98 -: pin 5 Remove the motor by unscrewing its four attachment screws and plain washers. A 3HAC 16247-1 3 Repair activities, manipulator 3.5.3 Removal of motor axis 2 Step 3HAC 16247-1 Action Note/Illustration 9. Fit the two guide pins in the two lower motor attachment holes. Art. no. specified in Required equipment on page 97! Shown in the figure Location of motor on page 97! 10. If required, press the motor out of position by fitting removal tool, motor to the remaining motor attachment holes. Art. no. specified in Required equipment on page 97! Shown in the figure Location of motor on page 97! Always use the removal tools in pairs! 11. Remove the removal tools and fit the lifting tool, motor axis 2, 3, 4 to the motor. Art. no. specified in Required equipment on page 97! 12. Lift the motor to get the pinion away from the gear. Make sure the motor pinion does not get damaged! 13. Remove the motor by gently lifting it straight out and place it on a secure surface. Disconnect the brake release voltage. A 99 3 Repair activities, manipulator 3.5.4 Refitting of motor axis 2 3.5.4 Refitting of motor axis 2 Location of motor The motor, axis 2, is located on the left hand side of the manipulator as shown in the figure below. B D A C xx0200000169 A Motor axis 2 B Hole for lock screw C Cable gland cover (located on the lower side of the motor) D Motor attachment holes (4 pcs) Required equipment 100 Equipment, etc. Spare part no. Art. no. Note Motor axis 2, 175/ 2.55 3HAC 15882-1 Includes motor 3HAC 14673-6. Includes pinion 3HAC 10122-15. Includes o-ring 2152 2012-430 Motor axis 2, 225/ 2.55, 175/2.8, 125/ 3.2 and 200/2.75 3HAC 15885-1 Includes motor 3HAC 14673-9. Includes pinion 3HAC 10122-15. Includes o-ring 2152 2012-430. O-ring 2152 2012-430 Must be replaced when reassembling motor! Grease 3HAB 3537-1 For lubricating the o-ring! Guide pin, M10 x 150 3HAC 15521-2 For guiding the motor. Guides are to be used in pairs! Lifting tool, motor axis 2, 3, 4 3HAC 15534-1 A 3HAC 16247-1 3 Repair activities, manipulator 3.5.4 Refitting of motor axis 2 Equipment, etc. Spare part no. Art. no. Note Power supply 24 VDC, 1.5 A. For releasing the brakes. Rotation tool, motor pinion 3HAC 17105-1 Used to rotate the motor pinion when mating it to the gear, when brakes are released with 24VDC power supply. Circuit diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Refitting, motor These procedures include references to the tools required. The procedure below details how to refit the motor axis 2. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The motor weighs 27 kg! All lifting equipment used must be dimensioned accordingly! Step 3HAC 16247-1 Action Note/Illustration 1. Make sure the o-ring on the circumference of Art. no. specified in Required equipthe motor is seated properly. Lightly lubricate ment on page 100! the o-ring with grease. 2. In order to release the brake, remove the Connect to connector R2.MP2 cover on top of the motor and connect the 24 • +: pin 2 VDC power supply. • -: pin5 3. Fit the lifting tool, motor axis 2, 3, 4 to the motor. Art. no. specified in Required equipment on page 100! 4. Fit the two guide pins in the two lower motor attachment holes. Art. no. specified in Required equipment on page 100! Shown in the figure Location of motor on page 100! 5. Lift the motor and guide it on to the guide pins, as close to the correct position as possible without pushing the motor pinion into the gear. See that the motor is turned the right direction, i.e. the cables facing downwards. A 101 3 Repair activities, manipulator 3.5.4 Refitting of motor axis 2 Step Action Note/Illustration 6. Remove the lifting tool and allow the motor to rest on the guide pins. 7. Use the rotation tool in order to rotate the Art. no. specified in Required equipmotor pinion when mating it to the gear (see ment on page 100! figure beside). Fit the motor, making sure the motor pinion is A properly mated to the gear of gearbox axis 2 and that it doesn´t get damaged. xx0200000165 The rotation tool is used beneath the motor cover, directly on the motor shaft as shown in figure above. • A: Rotation tool 8. Remove the guide pins. 9. Secure the motor with four attachment screws M10 x 40, tightening torque: 50 Nm. and plain washers. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 10. Remove the lifting tool. 11. Disconnect the brake release voltage. 12. Reconnect all connectors beneath the motor cover. Connect in accordance with markings on connectors. 13. Refit the cable gland cover at the cable exit with its two attachment screws. Shown in the figure Location of motor on page 100! 14. Refit the cover on top of the motor with its four Make sure the cover is tightly attachment screws. sealed! 15. Remove the lock screw from the hole for lock Shown in the figure Location of screw. motor on page 100! 16. Perform a leak down test. Detailed in Performing a leak-down test on page 21. 17. Refill the gearbox with oil. Detailed in "Oil change, gearbox axis 2" in the Maintenance Manual. 18. Recalibrate the robot. Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 102 A 3HAC 16247-1 3 Repair activities, manipulator 3.5.5 Removal of motor, axis 3 3.5.5 Removal of motor, axis 3 Location of motor The motor axis 3 is located on the left hand side of the manipulator as shown in the figure below. A B C xx0200000186 A Motor, axis 3 B Cable gland cover, motor axis 3 C Attachment screws and washers (4 pcs) Required equipment Equipment, etc. Spare part no. Art. no. Power supply 3HAC 16247-1 Note 24 VDC, 1.5 A. For releasing the brakes. Removal tool, motor M12 3HAC 14631-1 Always use the removal tools in pairs! Guide pin, M10 x 150 3HAC 15521-2 For guiding the motor. Always use guide pins in pairs. Mech stop axis 3 3HAC 12708-1 Used to fix axis 3 (one method of three, see step one in the removal procedure). Use attachment screws 3HAB 3409-86 (M16 x 60). Washers for Mech stop axis 3 3HAA 1001-186 Circuit Diagram 3HAC 13347-1 A Included in the Repair Manual, part 2. 103 3 Repair activities, manipulator 3.5.5 Removal of motor, axis 3 Equipment, etc. Spare part no. Art. no. Standard toolkit Note 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Removal, motor These procedures include references to the tools required. The procedure below details how to remove motor, axis 3. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The motor weighs 27 kg! All lifting equipment used must be dimensioned accordingly! Step 1. Action Note/Illustration Unload the manipulator upper arm by either: • Use a fork lift to rest the upper arm onto. • Use lifting slings and an overhead crane to rest the upper arm. • Use a mechanical stop to rest the upper arm. Fit the mechanical stop in the attachment hole (A) with tightening torque: 115 Nm. B A xx0300000051 The upper arm must be positioned as horizon- Fit the mechanical stop to the third tal as possible! and final attachment hole (A), below the fixed stop (B) in the upper arm. See the figure above! 104 2. Drain the oil from gearbox axis 3. 3. Remove any equipment hindering access to motor axis 3. 4. Remove the cover on top of the motor by unscrewing its four attachment screws. 5. Remove the cable gland cover at the cable exit by unscrewing its two securing screws. 6. Disconnect all connectors beneath the motor cover. A Detailed in "Oil change, gearbox axis 3" in the Maintenance Manual. Shown in the figure Location of motor on page 103! Make sure the gasket is not damaged! 3HAC 16247-1 3 Repair activities, manipulator 3.5.5 Removal of motor, axis 3 Step Action Note/Illustration 7. Release the brake by connecting the 24 VDC Connect to connector R2.MP3 power supply. • +: pin 2 Make sure the weight of the complete upper • -: pin 5 arm rests safely on the mechanical stops, the fork lift or the lifting slings before removing the motor. 8. Unscrew the motors four attachment screws and plain washers . Shown in the figure Location of motor on page 103! 9. Fit the two guide pins in the two lower motor attachment screw holes. Art. no. specified in Required equipment on page 103! 10. Press the motor out of position by fitting removal tool, motor to the motor attachment screw holes. Art. no. specified in Required equipment on page 103! Always use the removal tools in pairs! 11. Apply the lifting tool, motor axis 2 ,3, 4 to the motor. Art. no. specified in Required equipment on page 103! 12. Lift the motor to get the pinion away from the gear. 13. Remove the motor by gently lifting it straight Make sure the motor pinion is not out and disconnect the brake release voltage. damaged! 3HAC 16247-1 A 105 3 Repair activities, manipulator 3.5.6 Refitting of motor, axis 3 3.5.6 Refitting of motor, axis 3 Location of motor The motor axis 3 is located on the left hand side of the manipulator as shown in the figure below. A B C xx0200000186 A Motor axis 3 B Cable gland cover, motor axis 3 C Motor attachment holes (4 pcs) Required equipment 106 Equipment, etc. Spare part no. Art. no. Note Motor axis 3, 175/ 2.55 3HAC 15882-1 Includes motor 3HAC 14673-6. Includes pinion 3HAC 10122-15. Includes o-ring 2152 2012-430. Motor axis 3, 225/ 2.55, 175/2.8, 125/ 3.2 and 200/2.75 3HAC 15885-1 Includes motor 3HAC 14673-9. Includes pinion 3HAC 10122-15. Includes o-ring 2152 2012-430. O-ring 2152 2012-430 Must be replaced when reassembling motor! Grease 3HAB 3537-1 Guide pin, M10 x 100 3HAC 15521-1 For guiding the motor. Guide pin, M10 x 150 3HAC 15521-2 For guiding the motor. Rotation tool, motor pinion 3HAC 17105-1 Used to rotate the motor pinion when mating it to the gear, when brakes are released with 24 VDC power supply. A For lubricating the o-ring. 3HAC 16247-1 3 Repair activities, manipulator 3.5.6 Refitting of motor, axis 3 Equipment, etc. Spare part no. Art. no. Note Power supply 24 VDC, max. 1.5 A. For releasing the brakes. Circuit Diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Refitting, motor These procedures include references to the tools required. The procedure below details how to refit motor, axis 3. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The motor weighs 27 kg! All lifting equipment used must be dimensioned accordingly! Step Action Note/Illustration 1. Make sure the o-ring on the circumference of the motor is seated properly. Lightly lubricate it with grease . Art no. specified in Required equipment on page 106! 2. Fit the lifting tool, motor axis 2, 3, 4 to the Art no. specified in Required equipment motor. on page 106! 3. Fit the two guide pins in the two lower motor attachment holes. 4. Lift the motor and guide it onto the guide pins, as close to the correct position as possible without pushing the motor pinion into the gear. 5. Remove the lifting tool and allow the motor stay on the guide pins. 6. In order to release the brake, connect the Connect to connector R2.MP3 24 VDC power supply. • +: pin 2 Art no. specified in Required equipment on page 106! Shown in the figure Location of motor on page 106! • 3HAC 16247-1 A -: pin 5 107 3 Repair activities, manipulator 3.5.6 Refitting of motor, axis 3 Step 7. Action Note/Illustration Use the rotation tool in order to rotate the motor pinion when mating it to the gear! Fit the motor, making sure the motor pinion is properly mated to the gear of gearbox, axis 3. Art no. specified in Required equipment on page 106! Make sure the motor pinion does not get damaged! Make sure the motor is turned the right direction, i.e. the cables facing forwards. A xx0200000165 The rotation tool is used beneath the motor cover, directly on the motor shaft as shown in figure above. • A: Rotation tool. 8. Remove the guide pins. 9. Secure the motor with four attachment screws and plain washers. 10. Disconnect the brake release voltage. 11. Reconnect all connectors beneath the motor cover. Connect in accordance with markings on connectors. 12. Refit the cable gland cover at the cable exit with its two attachment screws. Make sure the cover is tightly sealed! Shown in the figure Location of motor on page 106! 13. Refit the cover on top of the motor with its Make sure the cover is tightly sealed! four attachment screws. 14. Remove the equipment used to unload the upper arm: • Fork lift • Lifting slings • Mech stop 4 pcs: M10 x 40, tightening torque: 50 Nm. 15. Perform a leak-down test. Detailed in section Performing a leakdown test on page 21. 16. Refill the gearbox with oil. Detailed in "Oil change, gearbox axis 3" in the Maintenance Manual. 17. Recalibrate the robot! Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 108 A 3HAC 16247-1 3 Repair activities, manipulator 3.5.7 Removal of motor, axis 4 3.5.7 Removal of motor, axis 4 Location of motor The motor axis 4 is located on the left hand side of the upper arm as shown in the figure below. C A B xx0200000202 A Motor, axis 4 B Cable gland cover, motor axis 4 C Motor attachment screws and washers Required equipment Equipment, etc. Spare part no. Art. no. Power supply 24 VDC, 1.5 A. For releasing the brakes. Removal tool, motor M10 3HAC 14972-1 Always use the removal tools in pairs! Guide pin, M8 x 150 3HAC 15520-2 For guiding the motor. Always use the guide pins in pairs. Circuit Diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. 3HAC 16247-1 Note These procedures include references to the tools required. A 109 3 Repair activities, manipulator 3.5.7 Removal of motor, axis 4 Removal, motor The procedure below details how to remove motor, axis 4. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step Action Note/Illustration 1. Run the robot to a position where the upper arm is pointed straight up. This position enables the motor to be replaced without draining the gear oil, which in turn saves time. 2. Remove the cable gland cover at the cable exit Shown in the figure Location of of the motor by unscrewing its two attachment motor on page 109! screws. Make sure the gasket is not damaged! 3. Remove the cover on top of the motor by unscrewing its four attachment screws. 4. Disconnect all connectors beneath the motor cover. 5. In order to release the brake, connect the 24 VDC power supply. Connect to connector R2.MP4 • +: pin 2 • 110 -: pin 5 6. Unscrew the motors four attachment screws and Shown in the figure Location of plain washers. motor on page 109! 7. Fit the two guide pins, M8 in two of the motor attachment screw holes. 8. If required, press the motor out of position by fit- Art. no. specified in Required ting removal tool, motor M10 to the motor attach- equipment on page 109! ment screw holes. Always use the removal tools in pairs! 9. Lift the motor to get the pinion away from the gear and disconnect the brake release voltage. 10. Remove the motor by gently lifting it straight out. Make sure the motor pinion is not damaged! A 3HAC 16247-1 3 Repair activities, manipulator 3.5.8 Refitting of motor, axis 4 3.5.8 Refitting of motor, axis 4 Location of motor The motor axis 4 is located on the left hand side of the upper arm as shown in the figure below. C A B xx0200000202 A Motor, axis 4 B Cable gland cover, motor axis 4 C Motor attachment holes (4 pcs) Required equipment Equipment, etc. Spare part no. Art. no. Note Motor axis 4, 175/ 2.55 3HAC 15887-1 Includes motor 3HAC 14673-7. Includes pinion 3HAC 12260-1. Includes o-ring 2152 2012-430. Motor axis 4, 225/ 2.55, 175/2.8, 125/ 3.2 and 200/2.75 3HAC 15889-1 Includes motor 3HAC 14673-10. Includes pinion 3HAC 12260-1. Includes o-ring 2152 2012-430. O-ring 2152 2012-430 Must be replaced when reassembling motor! Grease 3HAC 3537-1 Used to lubricate the o-ring. Guide pin, M8 x 100 3HAC 15520-1 For guiding the motor. Guide pin, M8 x 150 3HAC 15520-2 For guiding the motor. Rotation tool, motor pinion 3HAC 17105-1 Used to rotate the motor pinion when mating it to the gear, when brakes are released with 24 VDC power supply. Power supply 24 VDC, max. 1,5 A. For releasing the brakes. Circuit Diagram 3HAC 16247-1 3HAC 13347-1 A Included in the Repair Manual, part 2. 111 3 Repair activities, manipulator 3.5.8 Refitting of motor, axis 4 Equipment, etc. Spare part no. Art. no. Standard toolkit Note 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Refitting, motor These procedures include references to the tools required. The procedure below details how to refit motor, axis 4. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step Action Note/Illustration 1. Make sure the o-ring on the circumference Art. no. specified in Required equipof the motor is seated properly. Lightly lubri- ment on page 111! cate the o-ring with grease . 2. In order to release the brakes, connect the Connect to connector R2.MP4 24 VDC power supply. • +: pin 2 • 112 -: pin 5 3. Fit the two guide pins, M8 in two of the motor attachment holes. Art. no. specified in Required equipment on page 111! Shown in the figure Location of motor on page 111! 4. Fit the motor, with guidance of the pins, making sure the motor pinion is properly mated to the gear of gearbox 4. Make sure the motor pinion does not get damaged! A 3HAC 16247-1 3 Repair activities, manipulator 3.5.8 Refitting of motor, axis 4 Step 5. Action Note/Illustration Use the rotation tool in order to rotate the motor pinion when mating it to the gear! Fit the motor, making sure the motor pinion is properly mated to the gear, axis 4. Art. no. specified in Required equipment on page 111! Make sure the motor pinion does not get damaged! Make sure the motor is turned the right direction, i.e. the cables facing forwards. A xx0200000165 The rotation tool is used beneath the motor cover, directly on the motor shaft as shown in figure above. • A: Rotation tool. 6. Remove the guide pins. 7. Secure the motor with four attachment screws and plain washers. 8. Disconnect the brake release voltage. 9. Reconnect all connectors beneath the motor cover. 10. Refit the cover on top of the motor with its four attachment screws. 11. 4 pcs: M8 x 25, tightening torque: 24 Nm. Make sure the cover is tightly sealed! Refit the cable gland cover at the cable exit Shown in the figure Location of motor with its two attachment screws. on page 111! 12. Perform a leak-down test if gearbox has been drained. Detailed in section Performing a leakdown test on page 21. 13. Refill the gearbox with oil if drained. Detailed in "Oil change, axis 4 gearbox" in the Maintenance Manual. 14. Recalibrate the robot! Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 113 3 Repair activities, manipulator 3.5.9 Removal of motor, axis 5 3.5.9 Removal of motor, axis 5 Location of motor The motor axis 5 is located inside the upper arm tube, but attached to the wrist unit, as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Wrist complete on page 211. C B A xx0200000204 A Motor, axis 5 B Upper arm tube C Wrist unit Required equipment Equipment, etc. Spare part no. Art. no. Power supply 24 VDC, 1.5 A. For releasing the brakes. Removal tool, motor M10 3HAC 14972-1 Always use the removal tools in pairs! Measuring tool 6896 134-GN Guide pin, M8 x 100 motor 3HAC 15520-1 For guiding the motor. Guide pin, M8 x 150 motor 3HAC 15520-2 For guiding the motor. Nipple 6896 134-AA TREDO-washer 114 Note For pressing out the pinion, motor 5. Use as a seal when pressing out the pinion, motor 5. Nipple 6896 901-282 For pressing out the pinion, motor 5. Oil injector 6369 901-280 For pressing out the pinion, motor 5. Circuit Diagram 3HAC 13347-1 Included in the Repair Manual, part 2 A 3HAC 16247-1 3 Repair activities, manipulator 3.5.9 Removal of motor, axis 5 Equipment, etc. Spare part no. Art. no. Standard toolkit Note 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Removal, motor These procedures include references to the tools required. The procedure below details how to remove motor, axis 5. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step Action Note/Illustration 1. Drain the oil from gearbox axis 5. Detailed in "Oil change, gearbox axis 5" in the Maintenance Manual. 2. Remove the wrist unit. Detailed in section Removal of complete wrist unit on page 47. 3. Place the wrist unit safely on a workbench, in a fixture or similar. 4. Remove the cover on top of the motor by unscrewing its four attachment screws. 5. Remove the cable gland cover at the cable exit by unscrewing its two attachment screws. 6. Disconnect all connectors beneath the motor cover and remove the separate cable of the axis 5 motor. 7. In order to release the brake, connect the Connect to either: 24 VDC power supply. - connector R4.MP5 (in the motor): • + : pin 2 • - : pin 5 - connector R3.MP5 (on the separate cable, if not removed): • +: pin C • 3HAC 16247-1 -: pin D 8. Remove the motor by unscrewing its four attachment screws and plain washers. 9. Fit the two guide pins in two of the motor Art. no. specified in Required equipment attachment screw holes. on page 114! A 115 3 Repair activities, manipulator 3.5.9 Removal of motor, axis 5 Step 116 Action Note/Illustration 10. If required, press the motor out of position Art. no. specified in Required equipment by fitting removal tool, motor, M10 to the on page 114! motor attachment screw holes. Always use the removal tools in pairs and diagonally! 11. Lift the motor to get the pinion away from Make sure the motor pinion is not damthe gear and disconnect the brake aged! release voltage. 12. Remove the motor by gently lifting it straight out. 13. Measure the distance between the motor Art. no. specified in Required equipment flange, included eventual shims, and the on page 114! outer surface of the pinion, with measur- Make a note of the distance. ing tool. 14. Press out the pinion from the dismounted motor, with equipment specified in table above. The pinion is matched with the beveral gear for axis 5. When the motor is replaced the pinion must be removed from the dismounted motor and mounted onto the new motor shaft. If the pinion is damaged the complete wrist unit must be replaced! A Keep track of the shims between the motor flange and the wrist housing. Replacing the complete wrist unit is detailed in sections Removal of complete wrist unit on page 47 /Refitting of complete wrist unit on page 50. 3HAC 16247-1 3 Repair activities, manipulator 3.5.10 Refitting of motor, axis 5 3.5.10 Refitting of motor, axis 5 Location of motor The motor axis 5 is located inside the upper arm tube, but attached to the wrist unit, as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Wrist complete on page 211. C B A xx0200000204 A Motor, axis 5 B Upper arm tube C Wrist unit Required equipment Equipment, etc. 3HAC 16247-1 Spare part no. Art. no. Note Motor axis 5, 175/2.55 3HAC 14673-7 Does not include pinion. Use the pinion from the motor to be replaced. Includes o-ring 2152 2012-430. Motor axis 5, 225/ 3HAC 14673-10 2.55, 175/2.8, 125/3.2 and 200/2.75 Does not include pinion. Use the pinion from the motor to be replaced. Includes o-ring 2152 2012-430. Set of shim, motor 3HAC 7941-28 Used to obtain the correct distance between motor flange and outer surface of motor pinion. O-ring 2152 2012430 Must be replaced when reassembling motor! Grease 3HAC 3537-1 For lubricating the o-ring. Isopropanol 1177 1012-208 For cleaning motor pinion and motor pinion hole. Mineral oil CS 320 For lubrication of pinion shaft and pinion hole. Press fixture 3HAC 4850-1 For pressing the pinion on to the new motor. A 117 3 Repair activities, manipulator 3.5.10 Refitting of motor, axis 5 Equipment, etc. Spare part no. Art. no. Note Measuring tool 6896 134-GN Guide pin, M8 x 100 3HAC 15520-1 For guiding the motor. Guide pin, M8 x 150 3HAC 15520-2 For guiding the motor. Power supply 24 VDC, 1.5 A. For releasing the brakes. Circuit Diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Refitting, motor These procedures include references to the tools required. The procedure below details how to refit motor, axis 5. Please observe the following before commencing any repair work on the manipulator: Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. securing the lower arm with fixtures before removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step 118 Action Note/Illustration 1. Make sure the o-ring on the circumference Art. no. specified in Required equipof the motor is seated properly. Lightly lubri- ment on page 117! cate the o-ring with grease. 2. Clean the motor pinion and the motor pinion Art. no. specified in Required equiphole in the motor, with isopropanol. ment on page 117! 3. Apply a thin film of mineral oil to the pinion Art. no. specified in Required equipshaft and the pinion hole in order to make ment on page 117! the pinion run smoothly and to achieve an even friction torque when assembling the pinion. 4. Place the motor and pinion in the press fixture. Art. no. specified in Required equipment on page 117! 5. Press the pinion onto the new motor and check the pressing force. For an axis diameter of 15.5 mm, use min. pressing force: 18.5 kN and max. pressing force: 39.5 kN. If the pressing force is outside the given range or if the pinion "jumps" in bit by bit, it must be dismounted, checked, cleaned and oiled before it is assembled once again! A 3HAC 16247-1 3 Repair activities, manipulator 3.5.10 Refitting of motor, axis 5 Step Action Note/Illustration 6. Measure the distance between the motor flange and the outer surface of the pinion with the measuring tool. Modify the distance with shims in order to obtain the same distance as measured when dismounting the old motor (+ 0-0,05 mm). 7. In order to release the brake, connect the 24 Connect to either: VDC power supply. - connector R4.MP5 (in the motor): • +: pin 2 • -: pin 5 - connector R3.MP5 (on the separate cable, if not removed): • +: pin C • - : pin D 8. Fit the two guide pins in two of the motor attachment holes. Art. no. specified in Required equipment on page 117! 9. Fit the motor, with guidance from the pins, making sure the motor pinion is properly mated to the gear of axis 5. Make sure the motor pinion does not get damaged! 10. Secure the motor with four attachment screws and plain washers. 11. 4 pcs: M8 x 25; tightening torque: 24 Nm. Disconnect the brake release voltage. 12. Refit the separate cable of the axis 5 motor and reconnect all connectors beneath the motor cover. 13. Refit the cable gland cover at the cable exit with its two attachment screws. 14. Refit the cover on top of the motor with its four attachment screws. Make sure the cover is tightly sealed! 15. Refit the wrist unit. Detailed in section Refitting of complete wrist unit on page 50. 16. Perform a leak-down test. Detailed in Performing a leak-down test on page 21. 17. Refill the gear with oil. Detailed in "Oil change, gearbox axis 5" in the Maintenance Manual. 18. Recalibrate the robot. Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 119 3 Repair activities, manipulator 3.5.11 Removal of motor, axis 6 3.5.11 Removal of motor, axis 6 Location of motor The motor axis 6 is located in the center of the wrist unit as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Wrist complete on page 211. A B xx0200000222 A Wrist unit B Motor, axis 6 Required equipment Equipment, etc. Spare part no. Art. no. Power supply 120 Note 24 VDC, 1.5 A. For releasing the brakes. Removal tool, motor M10 3HAC 14972-1 Always use the removal tools in pairs! Circuit Diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! A 3HAC 16247-1 3 Repair activities, manipulator 3.5.11 Removal of motor, axis 6 Equipment, etc. Spare part no. Art. no. Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Removal, motor Note These procedures include references to the tools required. The procedure below details how to remove the motor, axis 6. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step Action Note/Illustration 1. Run the robot to a position where the motor in axis 6 is pointed straight up. This position enables the motor to be replaced without draining the gear oil, which in turn saves time. 2. Remove the rear motor cover by unscrewing six attachment screws. 3. Disconnect all connectors beneath the cover. 4. In order to release the brake, connect the 24 VDC Connect to connector R3.MP6 power supply. • +: pin 2 • 3HAC 16247-1 -: pin 5 5. Remove the motor by unscrewing its four attachment screws and plain washers. 6. If required, press the motor out of position by fitting Art. no. specified in Required removal tool, motor to the motor attachment screw equipment on page 120! holes. Always use the removal tools in pairs! 7. Lift the motor carefully to get the pinion away from Make sure the motor pinion is the gear and disconnect the brake release voltage. not damaged! 8. Remove the motor by gently lifting it straight out. A 121 3 Repair activities, manipulator 3.5.12 Refitting of motor, axis 6 3.5.12 Refitting of motor, axis 6 Location of motor The motor axis 6 is located in the center of the wrist unit as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Wrist complete on page 211. A B xx0200000222 A Wrist unit B Motor, axis 6 Required equipment Equipment, etc. 122 Spare part no. Art. no. Note Motor axis 6, 175/2.55 3HAC 15990-1 Includes motor 3HAC 14673-8. Includes pinion 3HAC 10122-24. Includes o-ring 2152 2012-430. Motor axis 6, 225/ 3HAC 15991-1 2.55, 175/2.8, 125/3.2 and 200/2.75 Includes motor 3HAC 14673-8. Includes pinion 3HAC 11173-3. Includes o-ring 2152 2012-430. O-ring 2152 2012-430 Must be replaced when reassembling motor! Guide pin, M8 x 100 3HAC 15520-1 For guiding the motor. Guide pin, M8 x 150 3HAC 15520-2 For guiding the motor. A 3HAC 16247-1 3 Repair activities, manipulator 3.5.12 Refitting of motor, axis 6 Equipment, etc. Spare part no. Art. no. Note Power supply 24 VDC, 1.5 A. For releasing the brakes. Grease 3HAB 3537-1 For lubricating the o-ring Circuit Diagram 3HAC 13347-1 Included in Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Refitting, motor These procedures include references to the tools required. The procedure below details how to refit motor, axis 6. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step Action Note/Illustration 1. Make sure the o-ring on the circumference of Art. no. specified in Required equipthe motor is seated properly. Lightly lubricate ment on page 122! the o-ring with grease. 2. In order to release the brake, connect the 24 VDC power supply. Connect to connector R3.MP6 • +: pin 2 • 3HAC 16247-1 -: pin 5 3. Fit the two guide pins in two of the motor attachment holes. Art. no. specified in Required equipment on page 122! 4. Fit the motor, with guidance from the pins, making sure the motor pinion is properly mated to the gear of gearbox, axis 6. Make sure the pinion on the motor shaft is not damaged! 5. Remove the guide pins. 6. Secure the motor with four attachment screws 4 pcs: M8 x 25, tightening torque: and plain washers. 24 Nm. 7. Disconnect the brake release voltage. 8. Reconnect all connectors beneath the motor cover. 9. Refit the cover on top of the motor with its six Make sure the cover is tightly attachment screws. sealed! 10. Recalibrate the robot. A Detailed in "Calibration" in the Installation Manual. 123 3 Repair activities, manipulator 3.5.12 Refitting of motor, axis 6 When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 124 A 3HAC 16247-1 3 Repair activities, manipulator 3.6.1 Removal of gearbox, axis 1 Section 3.6: Gearboxes 3.6.1 Removal of gearbox, axis 1 Location of gearbox The axis 1 gearbox is located between the frame and base as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Base incl. Frame on page 203. B A C xx0300000015 A Gearbox, axis 1 B Frame C Base - Attachment screws, base to gearbox (not shown in figure) Required equipment Equipment, etc. 3HAC 16247-1 Spare part no. Art. no. Note Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Support, base and gear 1 3HAC 15535-1 Lifting device, base and gear 1 3HAC 15560-1 Lifting tool (chain) 3HAC 15556-1 A 125 3 Repair activities, manipulator 3.6.1 Removal of gearbox, axis 1 Equipment, etc. Spare part no. Art. no. Note Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal, gearbox These procedures include references to the tools required. The procedure below details how to remove gearbox, axis 1. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The gear box weighs 155 kg! All lifting equipment used must be dimensioned accordingly! The base (without gearbox 1) weighs 263 kg! All lifting equipment used must be dimensioned accordingly! Step 1. Action Note/Illustration Move the robot to its most stable position, shown in the figure to the right. . xx0300000022 126 2. Drain the oil from gearbox 1. 3. Disconnect all cabling in the rear of the manipulator base and remove the cable support plate underneath the inside of the base. 4. Pull the disconnected cabling up through the center of gearbox 1. 5. Remove the complete arm system. Detailed in section Removal of complete arm system on page 36. A Detailed in "Oil change, gearbox, axis 1" in the Maintenance Manual. 3HAC 16247-1 3 Repair activities, manipulator 3.6.1 Removal of gearbox, axis 1 Step Action Note/Illustration 6. Remove the manipulator’s attachment screws to unfasten the base from the foundation. 7. Attach the lifting device, base and gear 1 and theand lifting tool (chain) , to the gearbox. Art. no. specified in Required equipment on page 125! 8. Lift the manipulator base to allow fitting the support, base and gear 1 on each sides of the base. Art. no. specified in Required equipment on page 125! 9. Fit the support, base. Make sure the base remains in a stable position before performing any work underneath the base! 10. Unscrew the 18 attachment screws (B), and remove the 3 washers (C), shown in the figure to the right. A B C xx0200000227 A view from below. • A: Oil drain hose 11. • B: Gearbox 1 attachment screws, 18 pcs • C: Washers, 3 pcs Remove the cable guide in the center of gearbox 1 by unscrewing its attachment screws. A xx0200000256 • 12. 3HAC 16247-1 A: Location for attachment screws, cable guide (cable guide removed in figure) Lift the gearbox away with the already mounted lifting tools. A 127 3 Repair activities, manipulator 3.6.2 Refitting of gearbox, axis 1 3.6.2 Refitting of gearbox, axis 1 Location of gearbox The axis 1 gearbox is located between the frame and base as shown in the figure below. A more detailed view of the component may be found in Foldout section Base incl. Frame on page 203. B A C xx0300000015 A Gearbox, axis 1 B Frame C Base - Attachment screws, base to gearbox (not shown in figure) Required equipment 128 Equipment, etc. Spare part no. Art. no. Note Gearbox, axis 1 3HAC 10828-8 Includes gearbox 3HAC 10828-3. Includes all o-rings and sealing rings! O-ring 3HAB 3772-54 Replace only when damaged! O-ring 3HAB 3772-55 Replace only when damaged! Sealing ring 3HAC 11581-4 Replace only when damaged! Grease 3HAC 3537-1 For lubricating the o-rings Support, base and gear 1 3HAC 15535-1 A 3HAC 16247-1 3 Repair activities, manipulator 3.6.2 Refitting of gearbox, axis 1 Equipment, etc. Spare part no. Art. no. Note Lifting device, base and gear 1 3HAC 15560-1 Lifting tool (chain) 3HAC 15556-1 Standard toolkit 3HAC 15571-1 Other tools may be required as detailed in sections to which references are made! Refitting, gearbox The contents are defined in section Standard toolkit on page 18! These procedures include references to the tools required. The procedure below details how to refit gearbox, axis 1. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The gear box weighs 155 kg! All lifting equipment used must be dimensioned accordingly! The base (without gearbox 1) weighs 263 kg! All lifting equipment used must be dimensioned accordingly! Step 1. 3HAC 16247-1 Action Note/Illustration If the base is not supported with Support, Mounting of the Support, base and base and gear 1, this should be done first. gear 1 is detailed in section Removal of gearbox, axis 1 on page 125. A 129 3 Repair activities, manipulator 3.6.2 Refitting of gearbox, axis 1 Step 2. Action Note/Illustration Make sure the two o-rings (C, D) on the cir- Art no. specified in Required equipcumference of the gearbox are seated ment on page 128! properly in their grooves respectively. Lightly lubricate the o-rings with grease . Make sure the small o-ring around the oil hole is fitted properly! E A D C xx0200000055 3. • A: Guide pin • C: O-ring 3HAB 3772-54 • D: O-ring 3HAB 3772-55 • E: Sealing ring 3HAC 11581-4 Refit the cable guide in the center of gearbox 1 with its attachment screws. A xx0200000256 • 130 A: Location for attachment screws, cable guide (cable guide removed in figure) 4. Fit the lifting device, base and the lifting tool Art no. specified in Required equip(chain) to the gearbox. ment on page 128! 5. Lift the gearbox to its mounting position in the center of the base. 6. Make sure the guide pin in the bottom face Shown in the figure xx0200000055 of the gearbox is properly aligned with the above! base. A 3HAC 16247-1 3 Repair activities, manipulator 3.6.2 Refitting of gearbox, axis 1 Step 7. Action Note/Illustration Secure the gearbox and the three washers M16 x 70, 12.9 quality UNBRAKO, with the 18 attachment screws, base to tightening torque: 300 Nm. gearbox (B). Reused screws may be used, providing they are lubricated as detailed in "Screw joints" before fitting. A B C xx0200000227 A view from below. • A: Oil drain hose 8. Lift the manipulator base and gearbox 1 to allow removing the support, base and gear. 9. Secure the base to the mounting site. 10. Refit the complete arm system. 11. • B: Attachment screws, base to gearbox, 18 pcs • C: Washers, 3 pcs Detailed in "Orienting and securing the manipulator" in the Installation Manual. Detailed in section Refitting of complete arm system on page 39. This is a complex task to be performed with utmost care in order to avoid injury or damage! Refit the cable support plate underneath the inside of the base and reconnect the cabling in the rear of the manipulator base. 12. Perform a leak-down test. Detailed in Performing a leak-down test on page 21. 13. Refill the gearbox with oil. Detailed in "Oil change, gearbox axis 1" in the Maintenance Manual. 14. Recalibrate the robot. Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 131 3 Repair activities, manipulator 3.6.3 Removal of gearbox axis 2 3.6.3 Removal of gearbox axis 2 Different designs Between the axis 2 motor and gearbox there is a motor attachment which exists in two different designs. • The early design of the motor attachment is attached directly to the gearbox, with the front gearbox attachment screws. • The later design of the motor attachment is attached directly to the frame. This design also includes an additional cover that overlaps the motor attachment and holds the oil plugs. The service work differ some between the designs. Be aware of the differences made in the instruction. Location of gearbox The gearbox, axis 2, is located in the lower arm rotational center, underneath the motor attachment. The figure below shows the later design of the motor attachment. A more detailed view of the component and its location may be found in the Foldout section Frame-Lower arm 1 on page 205. D A B J H I E F C G xx0200000171 132 A Gearbox axis 2 (behind motor attachment, not shown in figure ) B Attachment hole for locking screw, lower arm C Attachment holes inside of frame for fixture lower arm D Attachment holes for fixture lower arm E Balancing device F Motor axis 2 G Rear gearbox attachment screws A 3HAC 16247-1 3 Repair activities, manipulator 3.6.3 Removal of gearbox axis 2 H Attachment screws, motor attachment I Additional cover J Motor attachment Required equipment Equipment etc. Spare part no. Art. no. Fixture, lower arm 3HAC 13659-1 Locking screw, lower arm 3HAA 1001-266 M16 x 60. Accompanying the fixture. Lifting tool, gearbox axis 2 3HAC 13698-1 Guide pins, M12 x 150 3HAC 13056-2 For guiding the gearbox. Guide pins, M12 x 250 3HAC 13056-4 For guiding the gearbox. Press tool, balancing device 3HAC 15767-1 Hydraulic cylinder 3HAC 11731-1 To be used with the press tool and the hydraulic pump, when unloading the balancing device. Hydraulic pump 3HAC 13086-1 To be used with the press tool and the hydraulic cylinder, when unloading the balancing device. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Removal, gearbox Note Includes locking screw for securing the lower arm. These procedures include references to the tools required. The procedure below details how to remove the gearbox, axis 2. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The gear box weighs 52 kg! All lifting equipment used must be dimensioned accordingly! 3HAC 16247-1 A 133 3 Repair activities, manipulator 3.6.3 Removal of gearbox axis 2 Step Action Note/Illustration 1. Remove any equipment fitted to the turning disk. 2. Run the robot to the calibration position. The upper arm can be directed in three different ways, shown in the figure to the right. The lowered position, as in figure A, is recommended as it gives the least load on the tool. A B C xx0200000260 3. If the manipulator is fitted with moveable mechanical stops on axis 2 (not stock equipment), these must be removed at this point. The attachment holes of the mechanical stops are used to attach the fixture, lower arm. 4. The locking screw for the lower arm is Art. no. specified in Required equipattached to the fixture tool, remove it from ment on page 133! there (positioned as A in figure below). Shown in the figure Location of gearSecure the lower arm to the frame by insert- box on page 132! ing the locking screw into a specific attachment hole. 5. Fit the fixture, lower arm to prevent the lower arm from falling. • Make sure that both adjusters (B) on the fixture are screwed back. • • Art. no. specified in Required equipment on page 133! Attachment holes for the fixture are shown in the figure Location of gearbox on page 132! Align the fixture with the frame and Make sure the fixture is pressed lower arm. tightly against the lower arm before Tighten the four M16 bolts (C) on the securing with screws! inside of the frame, in attachment E A B D holes , with tightening torque: 220 Nm. • Screw in the two adjusters (B) until they rest against the flats on the lower arm. Tighten by hand. • Lock, using the two ring nuts (D). • Tighten the two M12 bolts (E) in the attachment holes, fixture lower arm with tightening torque: 91 Nm. C xx0200000261 134 A • A: Locking screw, lower arm • B: Adjusters • C: M16 bolts (4 pcs) • D: Ring nuts (2 pcs) • E: M12 bolts (2 pcs) 3HAC 16247-1 3 Repair activities, manipulator 3.6.3 Removal of gearbox axis 2 Step Action Note/Illustration 6. Unload the balancing device shaft by using press tool, balancing device. Art. no. specified in Required equipment on page 133! Detailed in section Unloading the balancing device on page 89! 7. Drain the gearbox, axis 2. Notice! Time-consuming activity! Detailed in "Oil change, gearbox axis 2" in Maintenance Manual. 8. Remove the motor, axis 2. Detailed in section Removal of motor axis 2 on page 97. 9. Remove the 33 rear gearbox attachment screws from inside the lower section of the lower arm. Shown in the figure Location of gearbox on page 132! 10. Remove the motor attachment. Read more about the variations in In the early design this is done by unscrew- design in Different designs on page ing the 24 front gearbox attachment screws. 132. In the later design this is done by unscrew- Shown in the figure Location of gearing the 15 attachment screws, motor attach- box on page 132! ment. 11. If the robot is equipped with the later design of the motor attachment; now remove the 24 front gearbox attachment screws (C), shown in the figure to the right. A B C xx0200000166 • A: Holes for guide pins, sealing ax 2/3 • B: Rear gearbox attachment screws (33 pcs) • C: Front gearbox attachment screws (24 pcs) 12. Fit two guide pins in 180°relation to each Art. no. specified in Required equipother in the empty holes of the front gearbox ment on page 133! attachment screws. 3HAC 16247-1 A 135 3 Repair activities, manipulator 3.6.3 Removal of gearbox axis 2 Step Action Note/Illustration 13. If required, apply two M12 screws to the holes (A), shown in the figure to the right, to press it free. A A xx0200000172 • A: M12 holes for pressing the gearbox out. 14. Fit the lifting tool, gearbox axis 2 to the gear- Art. no. specified in Required equipbox. ment on page 133! 15. Remove the gearbox axis 2 using an overhead crane or similar, with guidance from the mounted guide pins. 16. Remove the friction washer and clean it. 17. Remove the sealing from the lower arm. 136 A 3HAC 16247-1 3 Repair activities, manipulator 3.6.4 Refitting of gearbox axis 2 3.6.4 Refitting of gearbox axis 2 Different designs Between the axis 2 motor and gearbox there is a motor attachment which exists in two different designs. • The early design of the motor attachment is attached directly to the gearbox, with the front gearbox attachment screws. • The later design of the motor attachment is attached directly to the frame. This design also includes an additional cover that overlaps the motor attachment and holds the oil plugs. The service work differ some between the designs. Be aware of the differences made in the instruction. Location of gearbox The gearbox, axis 2, is located in the lower arm rotational center, underneath the motor attachment. The figure below shows the later design of the motor attachment. A more detailed view of the gearbox may be found in the Foldout section Frame-Lower arm 1 on page 205. D A B J H I E F C G xx0200000171 3HAC 16247-1 A Gearbox axis 2 (behind motor attachment, not shown in figure ) B Attachment hole for locking screw, lower arm C Attachment holes inside of frame for fixture, lower arm D Attachment holes for fixture, lower arm E Balancing device F Motor axis 2 G Rear gearbox attachment screws A 137 3 Repair activities, manipulator 3.6.4 Refitting of gearbox axis 2 H Attachment screws, motor attachment I Additional cover J Motor attachment Required equipment Equipment Spare part no. Art. no. Note Gear, axis 2 3HAC 10828-12 Includes gearbox 3HAC 1082811 and all o-rings! Does not include "Sealing, axis 2/3"! O-ring 3HAB 3772-68 2 pcs O-ring 3HAB 3772-69 O-rings in the additional cover. 3HAB 3772-70 Should be replaced if damaged! Sealing, axis 2/3 3HAC 12443-2 A new sealing must be used on each assembly! Grease 3HAB 3537-1 Lifting tool, gearbox axis 2 3HAC 13698-1 Guide pin, M12 x 150 3HAC 13056-2 Guide pin, M12 x 200 3HAC 13056-3 Guide pin, sealing axis 2/3, 80 mm 3HAC 14628-1 For guiding the sealing! Guide pin, sealing axis 2/3, 100 mm 3HAC 14628-2 For guiding the sealing! Gearbox crank 3HAC 16488-1 Used to turn the gear in correct position. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Refitting, gearbox For lubricating o-rings. These procedures include references to the tools required. The procedure below details how to refit gearbox axis 2. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! 138 A 3HAC 16247-1 3 Repair activities, manipulator 3.6.4 Refitting of gearbox axis 2 The gear box weighs 52 kg! All lifting equipment used must be dimensioned accordingly! Step 1. Action Note/Illustration Make sure the both o-rings (A) are fitted to the gearbox as shown in the figure to the right. Lightly lubricate them with grease. Art. no. specified in Required equipment on page 138! A xx0200000173 • 2. Fit the lifting tool, gearbox axis 2 to the gearbox. 3. Fit the guide pins, sealing axis 2/3 on the gearbox, axis 2. Use the attachment holes (A) shown in the figure to the right! A: O-rings (2 pcs), gearbox axis 2. Art. no. specified in Required equipment on page 138! A B C xx0200000166 3HAC 16247-1 A • A: Holes for guide pins, sealing axis 2/3 on the gearbox. • B: The gearboxes rear attachment screws (33 pcs) • C: The gearboxes front attachment screws (24 pcs) 139 3 Repair activities, manipulator 3.6.4 Refitting of gearbox axis 2 Step 140 Action Note/Illustration 4. Fit the new sealing, axis 2/3 on the gearArt. no. specified in Required equipbox, axis 2, and on to the guide pins. ment on page 138! Do not remove the guide pins for the sealing until the rear gearbox attachment screws are secured. 5. Fit two guide pins, M12 in 180°relation to Art. no. specified in Required equipeach other in the frame, in the screw holes ment on page 138! for the gearboxes front attachment screws. 6. Fit the cleaned friction washer onto the guide pins, M12. 7. Lift the gearbox to its mounting position and slide it onto the guiding pins attached in the frame, through the front attachment screw holes. 8. Align the gearbox attachment screw holes to the hole patterns in the lower arm, with help from the guide pins, sealing axis 2/3. If necessary, use a gearbox crank to turn the gear! Use the gearbox crank with caution! The gearbox may be damaged if the crank is inserted too far into the gear! 9. Fit the gearbox with guidance from the guide pins and slide it into position. If necessary, use the front gearbox attachment screws to press the gearbox into place. 10. Remove the lifting tool from the gearbox Choose correct instruction depending and continue refitting the motor attachment on which motor attachment the robot as described below. is equipped with. Read more about the variations in Different designs on page 137. 11. Early design of motor attachment: Lift the motor attachment and slide it on to the guide pins. If necessary, use a plastic mallet to knock the motor attachment into place. 12. Insert and secure 22 of the 24 front gearbox Shown in the figure xx0200000166 attachment screws. above! Tightening torque: 115 Nm. 13. Remove the guide pins, M12 and tighten the two remaining screws as detailed above. 14. Later design of the motor attachment: Art. no. specified in Required equipLubricate the o-ring at the rear of the motor ment on page 138! attachment with grease. Replace if damaged. 15. Later design of the motor attachment: Refit the motor attachment by pressing it against the frame. 16. Later design of the motor attachment: Refit Shown in the figure Location of gearthe attachment screws, motor attachment. box on page 137. 15 pcs: M8 x 25, tightening torque: 24 Nm. A Art. no. specified in Required equipment on page 138! 3HAC 16247-1 3 Repair activities, manipulator 3.6.4 Refitting of gearbox axis 2 Step Action Note/Illustration 17. Insert and secure 31 of the 33 rear gearbox Shown in the figure Location of gearattachment screws on the inside of the box on page 137! lower arm. M12 x 50, 12.9 quality UNBRAKO, tightening torque: 115 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 18. Remove the guide pins, sealing axis 2/3, and tighten the two remaining screws as detailed above. 19. Refit the motor. Detailed in section Refitting of motor axis 2 on page 100. 20. Perform a leak-down test. Detailed in section Performing a leakdown test on page 21. 21. Refill the gearbox with oil. Detailed in "Oil change, gearbox axis 2" in the Maintenance Manual. 22. Restore the balancing device. Detailed in section Restoring the balancing device on page 91! 23. Remove the fixture, lower arm. 24. Remove the locking screw, lower arm, and re-attach it to the fixture tool. 25. Refit any mechanical stops if such were removed during disassembly. 26. Refit any equipment to the turning disc if such was removed during disassambly. 27. Recalibrate the robot. Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 141 3 Repair activities, manipulator 3.6.5 Removal of gearbox, axis 3 3.6.5 Removal of gearbox, axis 3 Location of gearbox The axis 3 gearbox is located in the upper arm rotational center as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Upper arm on page 209. A C D B xx0200000194 A Gearbox, axis 3 (sealing, axis 2/3 between lower arm and gearbox 3) B Motor, axis 3 C Upper arm D Gearbox attachment screws (24 pcs) Required equipment Equipment, etc. 142 Spare part no. Art. no. Mech stop axis 3 3HAC 12708-1 Washers for Mech stop axis 3 3HAA 1001-186 A Note Used to secure the upper arm. Use attachment screws 3HAB 3409-86 (M16 x 60). 3HAC 16247-1 3 Repair activities, manipulator 3.6.5 Removal of gearbox, axis 3 Equipment, etc. Spare part no. Art. no. Guide pin, M12 x 200 3HAC 13056-3 For guiding the gearbox. Guides are to be used in pairs. Guide pin, M12 x 250 3HAC 13056-4 For guiding the gearbox. Guides are to be used in pairs. Lifting eye, M12 3HAC 14457-3 Standard toolkit 3HAC 15571-1 Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Removal, gearbox Note The contents are defined in section Standard toolkit on page 18! These procedures include references to the tools required. The procedure below details how to remove gearbox, axis 3. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The gear box weighs 52 kg! All lifting equipment used must be dimensioned accordingly! Step 1. Action Note/Illustration Secure the upper arm in a horizontal posi- Art. no. specified in Required equiption using a mechanical stop. ment on page 142. Fit the mechanical stop to the third and final attachment hole (A), below the fixed mechanical stop (B) in the upper arm, shown in the figure to the right. Tightening torqure: 115 Nm. B A xx0300000051 3HAC 16247-1 2. Remove the motor, axis 3. Detailed in section Removal of motor, axis 3 on page 103. Note! When removing the motor axis 3, the brake on axis 3 is released. Make sure the upper arm is secured and enabled to move! 3. Remove the upper arm. Detailed in section Removal of upper arm on page 54. A 143 3 Repair activities, manipulator 3.6.5 Removal of gearbox, axis 3 Step Action Note/Illustration 4. Remove the sealing, axis 2/3 between gearbox and lower arm. On reassembly a new sealing must be used! 5. Place the upper arm safely on a workbench, in a fixture or similar. 6. Remove the gearbox attachment screws. 7. Fit the two guide pins, M12 in 180°relation Art. no. specified in Required equipto each other in the gearbox attachment ment on page 142! screw holes. 8. If required, apply M12 screws to the holes (A) shown in the figure to the right to press the gearbox free. Shown in the figure Location of gearbox on page 142! A C A B xx0200000201 144 9. Fit the lifting eye, M12 to the gearbox, in one of the upper attachment screw holes that attaches the gearbox to the lower arm. 10. Remove the gearbox, with guidance from the guide pins, using an overhead crane or similar. A • A: M12 holes for pressing the gearbox out • B: Gearbox attachment screw holes • C: Upper attachment screw holes, gearbox - lower arm Art. no. specified in Required equipment on page 142! 3HAC 16247-1 3 Repair activities, manipulator 3.6.6 Refitting of gearbox, axis 3 3.6.6 Refitting of gearbox, axis 3 Location of gearbox The axis 3 gearbox is located in the upper arm rotational center as shown in the figure below. A more detailed view of the component and its location may be found in the Foldout section Upper arm on page 209. A C D B xx0200000194 A Gearbox, axis 3 (sealing, axis 2/3 between lower arm and gearbox 3) B Motor, axis 3 C Upper arm D Gearbox attachment screws Required equipment Equipment, etc. Spare part no. Art. no. Note Gearbox, axis 3 3HAC 10828-12 Includes gearbox 3HAC 10828-11 Includes all o-rings! Does not include "Sealing, axis 2/3"! O-ring 3HAC 16247-1 3HAB 3772-68 2 pcs. A 145 3 Repair activities, manipulator 3.6.6 Refitting of gearbox, axis 3 Equipment, etc. Spare part no. Art. no. Note Grease 3HAB 3537-1 Sealing, axis 2/3 3HAC 12443-2 A new sealing must be used on each assembly! Lifting eye, M12 3HAC 14457-3 Guide pin, M12 x 200 3HAC 13056-3 For guiding the gearbox. Guides are to be used in pairs. Guide pin, M12 x 250 3HAC 13056-4 For guiding the gearbox. Guides are to be used in pairs. Guide pin, sealing axis 2/3, 80 mm 3HAC 14628-1 For guiding "Sealing, axis 2/3". Guides are to be used in pairs. Guide pin, sealing axis 2/3, 100 mm 3HAC 14628-2 For guiding "Sealing, axis 2/3". Guides are to be used in pairs. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Refitting, gearbox For lubricating the o-rings. These procedures include references to the tools required. The procedure below details how to refit gearbox, axis 3. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! The gear box weighs 52 kg! All lifting equipment used must be dimensioned accordingly! Step 146 Action Note/Illustration 1. Turn the upper arm in such a position that the gear mating surface faces upwards. 2. Fit two guide pins in 180°relation to each Art. no. is specified in Required equipother in the gearbox attachment holes in the ment on page 145! upper arm. 3. Fit the lifting eye, M12 to the gearbox. A Art. no. is specified in Required equipment on page 145! 3HAC 16247-1 3 Repair activities, manipulator 3.6.6 Refitting of gearbox, axis 3 Step 4. Action Note/Illustration Make sure the o-rings are fitted to the gear- Art. no. is specified in Required equipbox. Apply grease to the o-rings to make ment on page 145! sure they stick in their grooves during A assembly. xx0100000136 • A: O-rings, gearbox ax 3 5. Lift the gearbox to its mounting position. 6. Turn the gearbox to align the attachment screw holes with those in the upper arm. 7. Fit the gearbox onto the guide pins and slide Make sure the gearbox and o-ring are it into position. seated properly and correctly oriented! 8. Remove the lifting tool. 9. Secure the gearbox with 22 of the 24 gearbox attachment screws. Remove the guide pins and tighten the remaining two screws. 24 pcs: M12 x 60. Tightening torque: 115 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 10. Refit the upper arm with a new sealing, axis Art. no. is specified in Required equip2/3 . ment on page 145! Detailed in section Refitting of upper arm on page 57! 11. Refit the motor. Detailed in section Refitting of motor, axis 3 on page 106. 12. Remove the mechanical stop used to secure the upper arm. 3HAC 16247-1 13. Recalibrate the robot! Detailed in "Calibration" in the Installation Manual. A 147 3 Repair activities, manipulator 3.6.6 Refitting of gearbox, axis 3 When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 148 A 3HAC 16247-1 3 Repair activities, manipulator 3.6.7 Removal of gearbox, axis 6 3.6.7 Removal of gearbox, axis 6 Location of gearbox The axis 6 gearbox is located in the center of the wrist unit as shown in the figure below. The different robot versions result in two different designs of the gearbox. A more detailed view of the component and its location may be found in the Foldout section Wrist complete on page 211. A A D B2 B1 C xx0200000219 A Gearbox, axis 6 B1 Attachment screws and washers, gearbox for robot version 175/2.55 (8 pcs) B2 Attachment screws and washers, gearbox for robot version 225/2.55, 175/2.8, 125/ 3.2 and 200/2.75 (18 pcs) C Oil plug, draining D Oil plug, filling - O-ring (not shown in figure) Required equipment Equipment, etc. Spare part no. Art. no. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. 3HAC 16247-1 Note These procedures include references to the tools required. A 149 3 Repair activities, manipulator 3.6.7 Removal of gearbox, axis 6 Removal, gearbox The procedure below details how to remove gearbox, axis 6. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Whenever parting/mating motor and gearbox, the gears may be damaged if excessive force is used! Step Action Note/Illustration 1. Drain the oil from gearbox, axis 6. Detailed in "Oil change, gearbox axis 6" in the Maintenance Manual. 2. Remove the turning disc. Detailed in section Removal of turning disk on page 42. 3. Remove the gearbox by unscrewing its 8 or 18 Shown in the figure Location of attachment screws and washers (amount gearbox on page 149! depends on robot version). 4. If required, apply M8 screws to the holes shown in the figure beside to press the gearbox out (not available in robot version 175/2.55). A A xx0200000220 • 5. 150 A: M8 holes for pressing the gearbox out Remove the gearbox axis 6 by lifting it out care- Be careful not to damage the motor fully. pinion! A 3HAC 16247-1 3 Repair activities, manipulator 3.6.8 Refitting of gearbox, axis 6 3.6.8 Refitting of gearbox, axis 6 Location of gearbox The axis 6 gearbox is located in the center of the wrist unit as shown in the figure below. The different robot versions result in two different designs of the gearbox. A A D B2 B1 C xx0200000219 A Gearbox, axis 6 B1 Attachment screws and washers, gearbox for robot version 175/2.55 (8 pcs) B2 Attachment screws and washers, gearbox for robot version 225/2.55, 175/2.8, 125/ 3.2 and 200/2.75 (18 pcs) C Oil plug, draining D Oil plug, filling - O-ring (not shown in figure) Required equipment 3HAC 16247-1 Equipment, etc. Spare part no. Art. no. Note Gear axis 6, 175/2.25 3HAC 10828-10 Includes o-ring 3HAB 377258. Gear axis 6, 225/2.55, 175/2.8, 125/3.2 and 200/2.75 3HAC 10828-13 Includes o-ring 3HAB 377257. Washers 3HAA 1001-172 O-ring 3HAB 3772-58/57 Must be replaced when reassembling gearbox! Grease 3HAB 3537-1 A Not included in gearbox! Replace only when damaged! For lubricating o-ring. 151 3 Repair activities, manipulator 3.6.8 Refitting of gearbox, axis 6 Equipment, etc. Spare part no. Art. no. Standard toolkit Note 3HAC 15571-1 Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Refitting, gearbox The contents are defined in section Standard toolkit on page 18! These procedures include references to the tools required. The procedure below details how to refit gearbox, axis 6. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Step 1. Action Note/Illustration Make sure the o-ring is fitted to the Art. no. specified in Required equipment on rear of the gearbox. Lightly lubricate page 151! the o-ring with grease. A xx0100000132 • 2. 152 Insert the gearbox, axis 6 into the wrist unit. A A: O-ring, gearbox axis 6 Art. no. specified in Required equipment on page 151! Shown in the figure Location of gearbox on page 151! Make sure the gears of the gearbox mate with those of the motor! 3HAC 16247-1 3 Repair activities, manipulator 3.6.8 Refitting of gearbox, axis 6 Step Action Note/Illustration 3. Secure the gearbox with the attach- Shown in figure above! ment screws and washers. 8 pcs or 18 pcs (depending on robot version): M8 x 40, 12.9 quality UNBRAKO, tightening torque: 30 Nm. Reused screws may be used, providing they are lubricated as detailed in Screw joints on page 15 before fitting. 4. Refit the turning disc. Detailed in section Refitting of turning disk on page 44. 5. Perform a leak-down test. Detailed in section Performing a leak-down test on page 21. 6. Refill the gearbox with oil. Detailed in "Oil change, gearbox axis 6" in the Maintenance Manual. 7. Recalibrate the robot. Detailed in "Calibration" in the Installation Manual. When performing the first test run after a service activity (repair, installation or maintenance), it is vital that: - all the service tools and other foreign objects are removed from the manipulator! - all normal safety equipment is installed properly, e.g. TPU enabling device. - all personnel is standing at a safe distance from the manipulator, i.e. out of its reach behind any safety fences, etc. - special attention is paid to the function of the part previously serviced. 3HAC 16247-1 A 153 3 Repair activities, manipulator 3.6.8 Refitting of gearbox, axis 6 154 A 3HAC 16247-1 4 Repair activities, controller cabinet 4.0.1 Introduction Chapter 4: Repair activities, controller cabinet 4.0.1 Introduction Definitions This chapter details all repair activities recommended for the controller. It is made up of separate units, each detailing a specific repair activity, e.g. Removal or Refitting of a certain component in the controller. Each unit contains all information required to perform the activity, e.g. spare parts numbers, required special tools and materials. The chapter is divided into: 3HAC 16247-1 • Removal instructions for all components • Refitting instructions for all components • Remaining instructions A 155 4 Repair activities, controller cabinet 4.1.1 Replacement of battery unit, controller Section 4.1: Complete controller cabinet 4.1.1 Replacement of battery unit, controller Location of battery unit The battery unit is located at the bottom of the controller. X1 X1 X1 X1 X2 X2 X2 X2 X1 X2 X3 Rectifier A0 A xx0200000103 A Battery unit Required equipment Equipment, etc. Spare part no. Art no. Note Battery unit 3HAC 5393-2 To be replaced as a complete unit Standard toolkit 3HAC 15571-1 The contents are defined in section "Standard toolkit"! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal, battery unit These procedures include references to the tools required. The procedure below details how to remove the battery unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. 156 A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.1 Replacement of battery unit, controller Step Action Note/Illustration 1. Remove the battery unit by unscrewing its attachment screws (1). X1 X1 X1 X1 X2 X2 X2 X2 X1 X2 X3 Rectifier A0 xx0200000004 2. Pull the battery unit out. 3. Disconnect the three cables from the battery unit. xx0200000005 Refitting, battery unit The procedure below details how to refit the battery unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action 3HAC 16247-1 Note/Illustration 1. Place the battery unit close to its position. Art. no. is specified above! See illustration above! 2. Reconnect the cables and push the unit into position. See illustration above! 3. Secure it with the attachment screws. See illustration above! A 157 4 Repair activities, controller cabinet 4.1.2 Replacement of I/O and gateway units 4.1.2 Replacement of I/O and gateway units Location of I/O and gateway units The I/O and gateway units are located as shown in the figure below. I/O-4 I/O-3 I/O-1 I/O-2 xx0200000009 A I/O and gateway units located on the panel shutter on the left side of the cabinet. B Four available slots for I/O and gateway units Required equipment Equipment, etc. 158 Spare part no. Art. no. Note Digital 24 VDC I/O 3HAB 7229-1 DSQC 328 Analog I/O 3HNE 00554-1 DSQC 355 AD Combi I/O 3HAB 7230-1 DSQC 327 Digital 120 VAC I/O 3HAB 7231-1 DSQC 320 Digital I/O with relays 3HAB 9669-1 DSQC 332 Gateway for Allen-Bradley, RIO 3HNE00025-1 DSQC 350 Gateway for Interbus-S 3HNE00006-1 DSQC 351 Gateway for Profibus DP, slave unit 3HNE00009-1 DSQC 352 Standard toolkit 3HAC 15571-1 The contents are defined in section "Standard toolkit"! A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.2 Replacement of I/O and gateway units Removal The procedure below details how to remove an I/O or gateway board. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Disconnect any connectors from the unit. The actual number of connectors vary Note which connector goes where, to facil- depending on type of unit. itate reassembly. 2. Lift the unit until the upper claw, that holds the unit to the rail, is released. Use: • a screwdriver when replacing I/O units (position 2a in the figure). • 1 2a 3a 1 2b 3b by hand when replacing a gateway unit (position 2b in the figure). xx0200000010 3. With the upper claw released, tip the unit away from the mounting rail and remove it (positions 3a and 3b in the figure). Refitting The procedure below details how to refit an I/O or gateway board. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Hook the unit back onto the mounting rail and snap it gently in position. 2. Reconnect all connectors disconnected during removal. 3HAC 16247-1 A 159 4 Repair activities, controller cabinet 4.1.3 Replacement of bleeder resistor 4.1.3 Replacement of bleeder resistor Location of bleeder resistor The bleeder resistor is located behind the air outlet device, as shown in the figure below. A B xx0200000007 A Bleeder resistor unit B Air outlet device Required equipment Removal Equipment, etc. Spare part no. Art. no. Bleeder resistor 3HAC 4560-5 Note The procedure below details how to remove the bleeder resistor. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Remove the air outlet divice in the back of the controller by loosening the six M5 screws (pos B). 160 A B 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.3 Replacement of bleeder resistor Step Action Note/Illustration 2. Disconnect the cable secured on top of the bleeder resistor unit (see position 1 in the figure). 1 xx0200000015 3. Push down and pull out the bleeder resistor unit to release the bleeder resistor unit from the enclosure. (see position 2 and 3 in the figure). 1 2 Refitting The procedure below details how to refit the bleeder resistor. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Fit the bleeder resistor into position and secure it with the spring. Art. no. is specified above! Also see the figure above! 2. Secure the cable disconnected during disassembly. 3. Refit the air outlet device. 4. Tightening the M5 screws. 3HAC 16247-1 A 161 4 Repair activities, controller cabinet 4.1.4 Putting the computer unit in the service position 4.1.4 Putting the computer unit in the service position Location of computer unit The computer unit is located as shown in the figure below. X1 X1 X1 X1 X2 X2 X2 X2 X1 X2 X3 Rectifier A0 A xx0200000105 A Opening Computer unit The procedure below details how to open the computer unit. Please observe the following before commencing any repair work on the manipulator: Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. securing the lower arm with fixtures before removing motor, axis 2. Step Action Note/Illustration 1. Make sure the ESD-wrist band is worn and connected to ground. 2. Turn the exenter to the left to release the See following figure. computer unit. 162 A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.4 Putting the computer unit in the service position 1 3. Push the locking device on the front of the computer unit to the right (see position 1 in the figure). 1 4. Pull the computer unit out of the cabinet until locked in its end position. Then swing it to the left as shown in the figure. xx0200000018 5. If work is to be performed on the computer unit while in the service position, it must be locked in this position. This is done by placing the puck (located on the lower left side) on the metal bar. Alternatively, the computer unit may be lifted straight up and placed on a work bench. 3HAC 16247-1 A 163 4 Repair activities, controller cabinet 4.1.4 Putting the computer unit in the service position Closing The procedure below details how to close the computer unit. Please observe the following before commencing any repair work on the manipulator: Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. securing the lower arm with fixtures before removing motor, axis 2. Step Action Note/Illustration 1. Swing the computer unit back into position and secure it by swinging the exenter to th right. 164 A See the figure above! Also see the procedure above! 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.5 Replacement of mass storage memory 4.1.5 Replacement of mass storage memory Location of mass storage memory The mass storage memory is located in the computer system, which is shown in the figure below. X1 X1 X1 X1 X2 X2 X2 X2 X1 X2 X3 Rectifier A0 A xx0200000105 A Computer system Required equipment Equipment, etc. Spare part no. Art. no. Mass storage memory, 64 MB 3HAC 7519-2 Note Mass storage memory, 128 MB 3HAC 7519-3 Standard toolkit 3HAC 15571-1 The contents are defined in section "Standard toolkit"! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Removal These procedures include references to the tools required. The procedure below details how to remove the mass storage memory. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Put the computer unit in service position. 3HAC 16247-1 A Detailed in section "Putting the computer in the service position". 165 4 Repair activities, controller cabinet 4.1.5 Replacement of mass storage memory Step Action Note/Illustration 2. Open the cover on the right side of the computer system by unsnapping the two snaps (item 1 in the figure). 1 xx0200000019 3. Disconnect the connectors X1 and X2 from the front of the mass storage memory (items 2 and 3 in the figure). 1 2 3 4. Remove the mass storage memory by unscrewing its M4 attachment screws as shown in the figure (item 1 in the figure). Refitting See figure above! The procedure below details how to refit the mass storage memory. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Fit the mass storage memory in position and Art. no. is specified above! secure it with its M4 attachment screw (item 1 in the figure) 1 3 2 xx0200000019 2. Reconnect connectors X1 and X2 to the front See the figure above! of the computer unit (items 2 and 3 in the figure). 166 A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.5 Replacement of mass storage memory Step Action Note/Illustration 3. Close the cover on the right side of the computer unit and secure it with the snaps (item 1 in the figure). 1 4. Put the computer system back in regular operation position. 3HAC 16247-1 A Detailed in section "Putting the computer in the service position". 167 4 Repair activities, controller cabinet 4.1.6 Replacement of internal cooling fan 4.1.6 Replacement of internal cooling fan Location of internal cooling fan The internal cooling fan is located in the computer system, which is shown in the figure below. X1 X1 X1 X1 X2 X2 X2 X2 X1 X2 X3 A0 A xx0200000105 A Computer system Required equipment Equipment, etc. Spare part no. Art. no. Note Internal cooling fan 3HAC 6655-1 Two fans required Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Removal These procedures include references to the tools required. The procedure below details how to remove the internal cooling fan. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Put the computer unit in service position. 168 A Detailed in "Putting the computer in the service position". 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.6 Replacement of internal cooling fan Step Action Note/Illustration 2. Disconnect the connector E5 or E6 respectively, depending on which fan is to be replaced. A D C B E xx0200000020 3. Remove the internal cooling fan inwards by gently pressing the locking tabs upwards. Refitting • A: Upper fan • B: Lower fan • C: Locking tabs • D: Connector E5 • E: Connector E6 See the figure above! The procedure below details how to refit the internal cooling fan. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. 3HAC 16247-1 A 169 4 Repair activities, controller cabinet 4.1.6 Replacement of internal cooling fan Step Action Note/Illustration 1. Tip the internal cooling fan with its top towards the cabinet wall and fit it into the hole (see the figure). Art. no. specified above! A A xx0200000021 • A: Push direction 2. With the wall between the upper lock spring hooks, push See the figure above! the fan unit up and in until the locking tab snaps to the wall. 3. Reconnect the connector E5 or E6 respectively, depending on which fan was replaced. 4. Put the computer unit back in regular operation position. Detailed in "Putting the computer in the service position". 170 A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.7 Replacement of drive units and rectifier 4.1.7 Replacement of drive units and rectifier Location of drive units and rectifier The drive units and rectifier are located as shown in the figure below. B A C xx0200000007 A Rectifier (drive unit) B Drive units C Power supply unit Required equipment Equipment, etc. Spare part no. Art. no. Note Drive unit (rectifier) 3HAB 8101-17 DSQC 545A Drive unit, axes 1-6 3HAB 8101-18 DSQC 546A Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal These procedures include references to the tools required. The procedure below details how to remove the drive units. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! 3HAC 16247-1 A 171 4 Repair activities, controller cabinet 4.1.7 Replacement of drive units and rectifier Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Swing the panel shutter out of the way. (pos A in figure). A 2. Disconnect connectors X1 and X2, four connectors each (see position 1 in the figure). X1 X1 X1 X1 X2 X2 X2 X2 1 X1 2 X2 X3 X2 1 A0 Rectifier xx0200000013 3. Remove the power supply bar in front See figure above! of the drive units (see position 2 in the figure). 4. Lift the spring to release the drive unit and pull it slightly outwards (see position 3 in the figure). 3 4 xx0200000014 5. Tip it out and remove it (see position 4 See figure above! in the figure). Refitting The procedure below details how to refit the drive units. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. 172 A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.7 Replacement of drive units and rectifier Step Action Note/Illustration 1. Fit the unit into position and secure it with the spring. Also see figure above! 2. Refit the power bar in front of the unit. 3. Reconnect all connectors X1 and X2. 4. Swing the power supply unit back into position. 3HAC 16247-1 A Detailed in section "Replacement of power supply unit" 173 4 Repair activities, controller cabinet 4.1.8 Replacement of system fan unit 4.1.8 Replacement of system fan unit Location of system fan unit The system fan unit is located under the bleeder resistor unit, in the back of the controller as shown in the figure below. xx0200000007 A Air outlet device B Bleeder resistor unit C System fan unit Required equipment Equipment, etc. Spare part no. Art. no. System fan unit 3HAC 15449-1 Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal Note These procedures include references to the tools required. The procedure below details how to remove the system fan unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action 174 Note/Illustration 1. Remove the Air outlet device. Pos. A in previous illustration. 2. Remove the bleeder resistor unit. Detailed in "Replacement of bleeder resistor". A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.8 Replacement of system fan unit Step Action Note/Illustration 3. Disconnect the cable (see position 1 in the figure). 1 2 A0 Rectifier 2 1 xx0200000008 4. Pull the back of the system fan unit upwards to free it and then tip it out of the enclosure (see position 2 in the figure). Refitting The procedure below details how to refit the system fan unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Fit the system fan unit into position and secure it (see position 2 in the figure above). Art. no. is specified above! 2. Reconnect the cable disconnected during disassembly (see position 1 in the figure above). 3HAC 16247-1 3. Refit the bleeder resistor unit. Detailed in section "Replacement of bleeder resistor". 4. Refit the Air outlet device. Pos. A in previous illustration. A 175 4 Repair activities, controller cabinet 4.1.9 Replacement of power supply unit 4.1.9 Replacement of power supply unit Location of power supply unit The power supply unit is located as shown in the figure below. xx0200000011 A Power supply unit B Power supply unit locking spring Required equipment Equipment, etc. Spare part no. Art. no. Note Power supply unit 3HAB 4297-1 DSQC 506 Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal These procedures include references to the tools required. The procedure below details how to remove the power supply unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Push the locking spring to the right to free the panel Shown in previous figure! shutter, and Swing it out of the way. 176 2. Remove the M5 Torx screw. See pos. 2 in previous figure. 3. Disconnect the connectors. See pos. 1 in previous figure. A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.9 Replacement of power supply unit Step Action Note/Illustration 4. Lift the unit straight up to release it from the hooks in the back and remove it outwards. Refitting The procedure below details how to refit the power supply unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supply to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Fit the power supply unit into position onto its hooks and Art. no. is specified above! secure it with the attachment screw (see position 2 in the section Removal). 2. Reconnect all connectors disconnected during removal. See position 1 in figure. 3. Swing the panel shutter back in possition and secure it with the locking spring. 3HAC 16247-1 A 177 4 Repair activities, controller cabinet 4.1.10 Replacement of Peltier Cooler power supply 4.1.10 Replacement of Peltier Cooler power supply Location of power supply unit The Peltier cooler power supply unit is located as shown in the figure below. 1 2 3 1 Cover 2 M5 screw 3 Extended Power supply Required equipment Equipment, etc. Spare part no. Art. no. Extended Power supply 3HAB 13398-1 Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal Note These procedures include references to the tools required. The procedure below details how to remove the power supply unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Remove the M5 Torx screw. See pos. 2 in previous illustration. 2. Remove the cover See pos. 1 in previous illustration. 3. Disconnect the wires. 178 A 3HAC 16247-1 4 Repair activities, controller cabinet 4.1.10 Replacement of Peltier Cooler power supply Step Action Note/Illustration 4. Remove the Power supply from the mounting rail. Refitting See pos. 3 in previous illustration. The procedure below details how to refit the power supply unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Fit the power supply unit onto the mounting rail. 2. Reconnect the wires disconnected during removal. 3. Refit the cover and secure with M5 screws. 3HAC 16247-1 A See pos. 1 and pos. 3. in previous illustration. 179 4 Repair activities, controller cabinet 4.1.10 Replacement of Peltier Cooler power supply 180 A 3HAC 16247-1 5 Appendix 1: Part Lists 5.0.1 Introduction Chapter 5: Appendix 1: Part Lists 5.0.1 Introduction This chapter is an appendix to the manual and contains part lists with item numbers, refering to the Appendix 2: Foldouts. The part list for the manipulator sometimes differ for robot versions 225/2.25- 175/2.8 and 175.2.25. In case of difference, the version is stated in the title. 3HAC 16247-1 A 181 5 Appendix 1: Part Lists 5.0.1 Introduction Section 5.1: Part List, Manipulator IRB 6600/6650 182 Item Qty Art. number Description Dimension/Note 5 1 3HAC 12812-2 Mechanical stop ax 1, assembly See Mechanical stop ax 1, 3HAC 12812-2 on page 183. 101 1 3HAC 12685-1 Base incl frame ax 1 See “Base incl frame ax 1, 3HAC 12685-1” on page 183. 102 1 3HAC 10746-3 Axis 3-4, (175/2.55) See “Axis 3-4, (robot v. 175/ 2.55), 3HAC 10746-3” on page 184. 102 1 3HAC 10746-1 Axis 3-4, (225/2.55, 175/2.8, See “Axis 3-4, (robot v. 225/ 125/3.2, 200/2.75) 2.55, 175/2.8, 125/3.2, 200/ 2.75), 3HAC 10746-1” on page 184. 102 1 3HAC 10746-5 Axis 3-4, Foundry (175/ 2.55) 102 1 3HAC 10746-4 Axis 3-4, Foundry (225/2.55, See Axis 3-4, Foundry (robot 175/2.8, 125/3.2, 200/2.75) v. 225/2.25, 175/2.8, 125/3.2, 200/2.75), 3HAC 10746-4 on page 185. 103 1 3HAC 8114-1 Wrist (175/2.55) See “Wrist (robot v. 175/2.55) 3HAC 8114-1” on page 189. 103 1 3HAC 8114-3 Wrist (225/2.55, 175/2.8, 125/3.2, 200/2.75) See “Wrist (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-3” on page 189. 103 1 3HAC 8114-6 Wrist Foundry (175/2.55) See Wrist Foundry (robot v. 175/2.55) 3HAC 8114-6 on page 189. 103 1 3HAC 8114-5 Wrist Foundry (225/2.55, 175/2.8, 125/3.2, 200/2.75) See Wrist Foundry (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-5 on page 190. 104 1 3HAC 14678-1 Balancing Device F (175/ 2.55, 225/2.55, 175/2.8 ) 104 1 3HAC 16189-1 Balancing Device G (125/ 3.2, 200/2.75) 104 1 3HAC 17117-2 Balancing Device A (175/ 2.55, 225/2.55, 175/2.8 ) 104 1 3HAC 17117-3 Balancing Device B (125/ 3.2, 200/2.75) 105 1 3HAC 10141-1 Lower arm (175/2.55, 225/ 2.55, 175/2.8 ) 105 1 3HAC 13940-1 Lower arm (125/3.2, 200/ 2.75) 106 1 3HAC 14940-1 Cable harness, man. ax1-4 (175/2.55, 225/2.55, 175/2.8 ) 106 1 3HAC 16331-1 Cable harness, man ax 1-4 (125/3.2, 200/2.75) 108 1 3HAC 13263-1 Material set manipulator A See Axis 3-4, Foundry (robot v. 175/2.55), 3HAC 10746-5 on page 185. See “Material set manipulator, 3HAC 13263-1” on page 194. 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.1 Mechanical stop ax 1, 3HAC 12812-2 Item Qty Art. number Description Dimension/Note 109 1 3HAC 13264-1 Material set ax 1-2 See “Mtrl.set ax 1-2, 3HAC 13264-1” on page 195. 110 1 3HAC 13265-1 Mtrl.set balancing device See “Mtrl set balancing device, 3HAC 13265-1” on page 198. 111 1 3HAC 12311-4 Arm extension set 250mm (175/2.8) See “Arm extension set, 250 mm, 3HAC 12311-4” on page 199. 111 1 3HAC 12311-5 Arm extension set 450mm (125/3.2) See “Arm extension set, 450 mm, 3HAC 12311-5” on page 199. 112 2 3HAC 12129-1 Cover plate t=1,5 mm 112 1 3HAC 12129-1 Cover plate t=1,5 mm 113 8 9ADA 618-56 Torx pan head screw M6x16 113 4 9ADA 618-56 Torx pan head screw M6x16 114 1 3HAC 13416-1 Protection cover Shell size 16 5.1.1 Mechanical stop ax 1, 3HAC 12812-2 Item Qty Art. number Description 5.1 1 3HAC 12812-1 Mech stop 5.2 1 9ABA 142-92 Spring pin, slotted Dimension 10x30 5.1.2 Base incl frame ax 1, 3HAC 12685-1 Item Qty Art. number Description Dimension/Note 101.1 1 3HAC 13054-2 Base machining See Base, machining, 3HAC 13054-2 on page 183! 101.2 1 3HAC 12684-1 Frame incl ax 1 gearbox See Frame incl ax 1 gearbox, 3HAC 12684-1 on page 184! 101.3 3 3HAC 11732-2 Washer T=3 101.4 18 3HAB 7700-5 Hex socket head cap screw M16x70 101.5 1 3HAC 11529-1 Rubber lined clip D=28 101.6 1 3HAC 14453-1 Hose with flange 101.7 1 3HAC 14453-2 Plug 101.8 1 3HAC 4428-2 Hose Clip D=23-27 101.9 1 9ADA 618-56 Torx pan head screw M6x16 Item Qty Base, machining, 3HAC 13054-2 3HAC 16247-1 Art. number Description 101.1.1 1 3HAC 13054-1 Base, casting 101.1.2 5 3HAC 4836-7 A Protection plug Dimension 16x12,3x9x7 183 5 Appendix 1: Part Lists 5.1.3 Axis 3-4, (robot v. 175/2.55), 3HAC 10746-3 Item Frame incl ax 1 gearbox, 3HAC 12684-1 Qty Art. number Description 101.1.3 1 3HAC 1383-2 Protection Cover compl. 101.1.4 1 3HAC 14024-1 Protection screw Item Art. number Description 101.2.1 1 3HAC 15866-1 Frame machining 101.2.2 1 3HAC 10828-8 RV 320C-224,26 assembly 101.2.3 24 3HAB 7700-73 Hex socket head cap screw 101.2.4 24 3HAA 1001-134 Washer Qty Dimension Dimension M12x70 13x19x1,5 5.1.3 Axis 3-4, (robot v. 175/2.55), 3HAC 10746-3 Item Qty Art. number Description Note 102.1 1 3HAC 13350-1 Material set ax 4 See Material set ax 4, 3HAC 13350-1 on page 185! 102.2 1 3HAC 10139-1 Tube shaft 2,55 See Tube shaft 2,55, 3HAC 10139-1 on page 187! 102.3 1 3HAC 13351-2 Axis 3 See Axis 3, 3HAC 13351-2/1 on page 187! 102.4 1 3HAC 14753-1 Rot ac motor incl gearbox See Rot ac motor incl gearbox, 3HAC 14753-1 on page 188! 5.1.4 Axis 3-4, (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75), 3HAC 10746-1 184 Item Qty Art. number Description Note 102.1 1 3HAC 13350-1 Material set ax 4 See Material set ax 4, 3HAC 13350-1 on page 185! 102.2 1 3HAC 10139-1 Tube shaft 2,55 See Tube shaft 2,55, 3HAC 10139-1 on page 187! 102.3 1 3HAC 13351-1 Axis 3 See Axis 3, 3HAC 13351-2/1 on page 187! 102.4 1 3HAC 14752-1 Rot ac motor incl gearbox See Rot ac motor incl gearbox, 3HAC 14752-1 on page 189. A 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.5 Axis 3-4, Foundry (robot v. 175/2.55), 3HAC 10746-5 5.1.5 Axis 3-4, Foundry (robot v. 175/2.55), 3HAC 10746-5 Item Qty Art. number Description Note 102.1 1 3HAC 13350-1 Material set ax 4 See Material set ax 4, 3HAC 13350-1 on page 185! 102.2 1 3HAC 15859-1 Tube shaft 2,55 foundry 102.3 1 3HAC 13351-2 Axis 3 102.4 1 3HAC 14753-1 Rot ac motor incl gearbox See Rot ac motor incl gearbox, 3HAC 14753-1 on page 188. See Axis 3, 3HAC 13351-2/1 on page 187! 5.1.6 Axis 3-4, Foundry (robot v. 225/2.25, 175/2.8, 125/3.2, 200/2.75), 3HAC 10746-4 Item Qty Art. number Description Note 102.1 1 3HAC 13350-1 Material set ax 4 See Material set ax 4, 3HAC 13350-1 on page 185! 102.2 1 3HAC 15859-1 Tube shaft 2,55 foundry 102.3 1 3HAC 13351-1 Axis 3 See Axis 3, 3HAC 13351-2/1 on page 187! 102.4 1 3HAC 14752-1 Rot ac motor incl gearbox See Rot ac motor incl gearbox, 3HAC 14752-1 on page 189! Material set ax 4, 3HAC 13350-1 3HAC 16247-1 Item Qty Art. number Description Dimension/Note 102.1.1 1 3HAC 12261-1 Gear Z4 /4 102.1.3 8 9ADA 183-37 Hex socket head cap screw M8x25 102.1.4 8 9ADA 312-7 Plain washer 8,4x16x1,6 102.1.5 1 3HAC 12259-1 Wheel unit ax4 225kg 102.1.6 3 3HAA 1001-99 Wedge 102.1.7 3 3HAC 12560-1 Stud bolt M8x65 102.1.8 12 9ADA 334-7 Spring washer, conical 8,4x18x2 102.1.9 3 9ADA 267-7 Hexagon nut M8 See Wheel unit ax 4, 225 kg, 3HAC 12259-1 on page 186! 102.1.10 3 3HAB 3409-63 Hex socket head cap screw M10x110 102.1.11 3 9ADA 334-8 10,5x23x2,5 102.1.12 1 3HAC 13564-1 Damper axis 4 102.1.13 1 3HAA 1001-17 Stop, Axis 4, Casting A Spring washer, conical See Damper axis 4, 3HAC 13564-1 on page 187! 185 5 Appendix 1: Part Lists 5.1.6 Axis 3-4, Foundry (robot v. 225/2.25, 175/2.8, 125/3.2, 200/2.75), 3HAC 10746-4 Item Qty Art. number Description Dimension/Note 102.1.14 1 3HAC 11925-1 Mechanical stop head 102.1.15 2 3HAB 3409-81 Hex socket head cap screw M16x35 102.1.16 1 3HAA 1001-98 Gasket T=1 102.1.17 1 3HAC 12149-4 Cover ax4 with sealing See Cover axis 4 with sealing, 3HAC 12149-4 on page 187! 102.1.18 14 9ADA 618-56 M6x16 102.1.20 1 3HAC 12126-1 Set of shims 102.1.21 1 3HAC 12060-1 Thrust washer 102.1.22 1 9ABA 135-45 Retaining ring, shaft 170 102.1.23 2 2213 253-5 Ball bearing 170x215x22 102.1.24 1 2216 261-18 Sealing 170x200x15 102.1.25 1 2216 0086-4 Sealing (Nilos) 180x215x4 102.1.26 1 3HAB 4317-1 SEALING 102.1.27 1 3HAC 3774-7 Spacer ring 102.1.28 1 3HAB 3772-27 O-ring 170x5 102.1.29 1 9ABA 107-56 10x20 Torx pan head screw Parallel pin 102.1.30 8100 1171 2016-604 Lubricating oil ml Wheel unit ax 4, 225 kg, 3HAC 12259-1 102.1.31 30 g 3HAB 3537-1 Bearing grease 102.1.32 1 ml 3HAB 7116-1 Locking liquid 102.1.33 1 ml 3HAB 7116-2 Locking liquid 102.1.34 1 3HAC 16721-1 Magnetic plug Item Art. number Description 102.1.5.1 1 3HAC 11742-1 Intermediate hub, machine 102.1.5.2 1 3HAC 12259-2 Gear unit Z2, 3/4 See Gear unit Z2, 3/4, 3HAC 12259-2 on page 186! 102.1.5.3 1 2126 2851-104 Lock nut M20X1 102.1.5.4 1 2213 3802-11 Taper roller bearing 40x68x19 102.1.5.5 1 3HAA 1001-129 Taper Roller Bearing 102.1.5.6 1 ml 3HAB 7116-2 Locking liquid Qty R 1/2” Dimension/Note Gear unit Z2, 3/4, 3HAC 12259-2 186 Item Qty Art. number Description 102.1.5.2.0 1 3HAC 12259-3 Pinion Z3 /4 102.1.5.2.0 1 3HAC 12259-4 Gear Z2 /4 A Dimension 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.6 Axis 3-4, Foundry (robot v. 225/2.25, 175/2.8, 125/3.2, 200/2.75), 3HAC 10746-4 Damper axis 4, 3HAC 13564-1 Cover axis 4 with sealing, 3HAC 12149-4 Item Qty Art. number Description 102.1.12.2 2 Plate for damper Item Qty Art. number Description 102.1.17.1 1 3HAC 12149-3 Cover ax4 with gasket 102.1.17.2 1 3HAA 1001-628 Sealing 3HAC 13564-2 Dimension Dimension Tube shaft 2,55, 3HAC 10139-1 Item Protection Cover compl., 3HAC 1383-2 Qty Art. number Description 102.2.1 1 3HAC 10139-2 Tube shaft 2,55, casting 102.2.2 1 3HAC 1383-2 Protection Cover compl. Note See Protection Cover compl., 3HAC 1383-2 on page 187! Item Qty Art. number Description Dimension 102.2.2.1 1 9ADA 624-69 M8x20 102.2.2.2 1 3HAB 3772-66 O-ring 102.2.2.3 1 3HAC 1383-1 Protection Cover 102.2.2.4 1 3HAC 1383-3 Gasket Item Qty Art. number Description 102.3.1 1 3HAC 10133-1 Axis 4 housing 102.3.2 1 3HAC 10828-12 RV 410F-270,176 assembly See RV 410F-270, 176 assembly, 3HAC 1082812 on page 188! 102.3.3 24 3HAB 3409-71 M12x60 102.3.4 24 3HAA 1001-134 Washer 13x19x1,5 102.3.5 1 3HAC 14750-1 Rot ac motor incl pinion (225/2.55, 175/2.8, 125/ 3.2, 200/2.75) See “Rot ac motor incl pinion, 3HAC 14750-1” on page 188. 102.3.5 1 3HAC 14751-1 Rot ac motor incl pinion, (175/2.55) See “Rot ac motor incl pinion, 3HAC 14751-1” on page 188. Torx counters. head screw 8x2 Axis 3, 3HAC 13351-2/1 3HAC 16247-1 A Hex socket head cap screw Dimension/Note 187 5 Appendix 1: Part Lists 5.1.6 Axis 3-4, Foundry (robot v. 225/2.25, 175/2.8, 125/3.2, 200/2.75), 3HAC 10746-4 Item Qty Art. number Description Dimension/Note 102.3.6 4 3HAB 3409-50 Hex socket head cap screw M10x40 102.3.7 4 3HAB 4233-1 Washer 102.3.8 1 3HAC 16721-1 Magnetic plug 102.3.9 2500 ml 3HAC 16843-1 102.3.10 1 RV 410F-270, 176 assembly, 3HAC 10828-12 Rot ac motor incl pinion, 3HAC 14751-1 Rot ac motor incl pinion, 3HAC 14750-1 Rot ac motor incl gearbox, 3HAC 14753-1 188 R 1/2” Lubricating oil, RMO 150 9ABA 142-92 Spring pin, slotted 10x30 Description Dimension Item Qty Art. number 102.3.2.1 1 3HAC 10828-11 RV 410F, i=270,176 102.3.2.2 1 3HAB 3772-68 O-ring Item Qty Art. number Description 102.3.5.1 1 3HAC 14673-6 Rotational ac motor M6 102.3.5.2 1 3HAC 10122-15 Input gear RV 410F-270,17 102.3.5.3 0 2152 2012-430 O-ring 89,5x3 102.3.5.4 1 9ADA 183-444 Hex socket head cap screw M8x130 102.3.5.5 3 ml 3HAB 7116-1 Locking liquid Item Qty Art. number Description 102.3.5.1 1 3HAC 14673-9 Rotational ac motor M6 102.3.5.2 1 3HAC 10122-15 Input gear RV 410F-270,17 102.3.5.3 0 2152 2012-430 O-ring 89,5x3 102.3.5.4 1 9ADA 183-444 Hex socket head cap screw M8x130 102.3.5.5 3 ml 3HAB 7116-1 Locking liquid Item Qty Art. number Description 102.4.1 1 3HAC 14673-7 Rotational ac motor M7 102.4.2 1 3HAC 12260-1 Pinion Z1 /4 102.4.3 0 2152 2012-430 O-ring A 276 x 3,53 Dimension Dimension Dimension 89,5x3 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.7 Wrist (robot v. 175/2.55) 3HAC 8114-1 Rot ac motor incl gearbox, 3HAC 14752-1 Item Qty Art. number Description 102.4.1 1 3HAC 14673-10 Rotational ac motor M10 102.4.2 1 3HAC 12260-1 Pinion Z1 /4 102.4.3 0 2152 2012-430 O-ring Dimension 89,5x3 5.1.7 Wrist (robot v. 175/2.55) 3HAC 8114-1 Item Qty Art. number Description Dimension/Note 103.1 1 3HAC 8114-4 Material set See Material set, 3HAC 8114-4 on page 190! 103.2 1 3HAC 7941-29 Rot ac motor incl gearbox See Rot ac motor incl. gearbox, 3HAC 7941-29 on page 192! 103.3 8 3HAB 3409-89 Hex socket head cap screw M16x80 103.4 1 3HAC 9744-1 See Axis 6 complete, 3HAC 9744-1/16032-1 on page 192! 103.5 1 3HAC 12732-1 Label Axis 6 complete 5.1.8 Wrist (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-3 Item Qty Art. number Description Dimension/Note 103.1 1 3HAC 8114-4 See Material set, 3HAC 8114-4 on page 190! 103.2 1 3HAC 7941-30 Rot ac motor incl gearbox See ! 103.3 8 3HAB 3409-89 Hex socket head cap screw M16x80 103.4 1 3HAC 13890-1 Axis 6 complete See ! 103.5 1 3HAC 12732-3 Label Material set 5.1.9 Wrist Foundry (robot v. 175/2.55) 3HAC 8114-6 3HAC 16247-1 Item Qty Art. number Description Dimension/Note 103.1 1 3HAC 8114-4 Material set See Material set, 3HAC 8114-4 on page 190! 103.2 1 3HAC 7941-29 Rot ac motor incl gearbox See Rot ac motor incl. gearbox, 3HAC 7941-29 on page 192! A 189 5 Appendix 1: Part Lists 5.1.10 Wrist Foundry (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-5 Item Qty Art. number Description Dimension/Note 103.3 8 3HAB 3409-89 Hex socket head cap screw M16x80 103.4 1 3HAC 16032-1 Axis 6 complete Foundry See Axis 6 complete, 3HAC 9744-1/16032-1 on page 192! 103.5 1 3HAC 12732-2 Label 5.1.10 Wrist Foundry (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-5 Item Qty Art. number Description Dimension/Note 103.1 1 3HAC 8114-4 See Material set, 3HAC 8114-4 on page 190! 103.2 1 3HAC 7941-30 Rot ac motor incl gearbox See Rot ac motor incl. gearbox, 3HAC 7941-29 on page 192! 103.3 8 3HAB 3409-89 Hex socket head cap screw M16x80 103.4 1 3HAC 13890-2 Axis 6 complete Foundry See Axis 6 complete, 3HAC 13890-2/1 on page 193! 103.5 1 3HAC 12732-1 Label Material set Material set, 3HAC 8114-4 190 Item Qty Art. number Description 103.1.1 1 3HAC 7956-1 103.1.2 1 3HAC 7941-28 Set of shim, motor 103.1.3 1 3HAC 7941-19 Set of shim, bevel gear 103.1.4 8 9ADA 183-37 Hex socket head cap screw M8x25 103.1.5 8 9ADA 312-7 Plain washer 8,4x16x1,6 103.1.6 1 3HAA 2166-11 VK-Cover D=80 B=10 103.1.7 1 3HAC 4334-3 50x90x20 103.1.8 4 3HAC 12560-1 Stud bolt 103.1.9 1 3HAB 7116-2 Locking liquid 103.1.10 16 9ADA 334-7 Spring washer, conical 8,4x18x2 103.1.11 4 9ADA 267-7 Hexagon nut M8 103.1.12 4 3HAA 1001-99 Wedge 103.1.13 1 3HAB 7299-1 103.1.14 1 3HAA 2166-23 VK-Cover D=120, B=12 103.1.15 1 3HAC 7941-32 Support shaft inc bearing See Support shaft incl. bearing, 3HAC 7941-32 on page 191! 103.1.16 6 9ADA 183-39 Hex socket head cap screw M8x35 103.1.17 2 3HAB 4337-2 Damper axis 5 103.1.18 1 3HAC 9953-1 Syncplate with nonie A Dimension/Note Wrist housing, 225kg Cylindrical roll. bearing Sealing M8x65 Di=115 Dy=140 B=12 T=1,5 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.10 Wrist Foundry (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-5 Support shaft incl. bearing, 3HAC 7941-32 Interm.wheel unit/ 5 225kg, 3HAC 7941-6 Gear Unit Z4-Z5/5 225 kg, 3HAC 7941-12 Item Qty Art. number Description Dimension/Note 103.1.19 1 3HAC 16721-1 Magnetic plug R 1/2 103.1.21 27 9ADA 618-56 Torx pan head screw M6x16 103.1.22 2 9ADA 334-6 Plain washer 6,4x14x1,5 103.1.23 1 3HAB 7116-1 Locking liquid 103.1.24 1 3HAC 14139-1 Manip. Harness ax 5 103.1.25 6700 ml 1171 2016-604 Lubricating oil 103.1.26 1 3HAC 7941-6 Interm.wheel unit/5 225kg See Interm.wheel unit/5 225kg, 3HAC 7941-6 on page 191! 103.1.27 1 3HAA 1001266 Screw M16x60 103.1.28 1 3HAC 7941-21 Gear wheel unit z6/5 225 103.1.29 1 3HAC 8081-8 Cover with gasket, 225kg 103.1.30 1 3HAC 8081-3 Cable cover 103.1.31 1 3HAC 14140-1 Manip. Harn. ax 5/6 103.1.32 2 2166 2055-3 Item Qty Art. number Description 103.1.15.1 1 3HAC 14731-1 Shaft 103.1.15.2 1 3HAB 3643-11 Groove ball bearing 130x165x18 103.1.15.3 3 9ADA 618-56 Torx pan head screw M6x16 103.1.15.4 1 ml 3HAB 7116-1 Locking liquid Qty Art. number Description Item 4,8x208 Dimension Dimension/Note 103.1.26.1 1 3HAC 7946-1 103.1.26.2 2 3HAA 1001-130 Taper Roller Bearing 103.1.26.3 1 3HAC 7941-12 Gear Unit z4-z5/5 225kg See Gear Unit Z4-Z5/5 225 kg, 3HAC 7941-12 on page 191! 103.1.26.4 1 3HAC 13142-1 Washer 17x30x6 103.1.26.5 1 3HAC 7941-11 Locking Nut 103.1.26.6 1 ml 3HAB 7116-2 Locking liquid Item Qty 103.1.26.3.1 1 3HAC 16247-1 Cable straps, outdoors See Gear wheel unit z6/5 225, 3HAC 7941-21 on page 192! Hub ax5, machining Art. number Description 3HAC 7941-7 A Dimension Pinion z5/5 225kg 191 5 Appendix 1: Part Lists 5.1.10 Wrist Foundry (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-5 Item Qty 103.1.26.3.2 1 Gear wheel unit z6/5 225, 3HAC 7941-21 Rot ac motor incl. gearbox, 3HAC 7941-29 Rot ac motor incl. gearbox, 3HAC 7941-30 Axis 6 complete, 3HAC 9744-1/ 16032-1 192 Item Art. number Description 3HAC 7941-5 Qty Dimension Gear z4/5 225kg Art. number Description 103.1.28.1 1 3HAC 7941-8 Gear z6/5 225kg 103.1.28.2 1 3HAB 4271-1 Groove ball bearing 103.1.28.3 1 3HAB 6686-1 Support ring 103.1.28.4 1 ml 3HAB 7116-2 Locking liquid 110x150x20 Item Qty Art. number 103.2.1 1 3HAC 14673-7 Rotational ac motor M7 103.2.2 1 3HAC 7941-1 103.2.3 0 2152 2012-430 O-ring 89,5x3 Item Qty Art. number Description Dimension/Note 103.2.1 1 3HAC 1467310 Rotational ac motor M10 103.2.2 1 3HAC 7941-1 Bevel gear set unit z1-3/5 103.2.3 0 2152 2012-430 O-ring Item Qty Art. number Description 103.4.1 1 3HAC 9744-5 Turning disc, diam. 200 103.4.2 1 3HAC 10828-10 RV 40E-81 assembly 103.4.3 1 3HAC 9744-3 Tilt housing, machining RV40 103.4.3 1 3HAC 16009-2 Tilt housing, machining RV40, foundry 103.4.4 1 3HAC 14755-1 Rot ac motor incl pinion A Description Dimension Dimension/Note Bevel gear set unit z1-3/5 89,5x3 Dimension/Note See RV 40E-81 assembly, 3HAC 10828-10 on page 193! See Rot ac motor incl. pinion, 3HAC 14754-1 on page 194 below! 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.10 Wrist Foundry (robot v. 225/2.55, 175/2.8, 125/3.2, 200/2.75) 3HAC 8114-5 RV 40E-81 assembly, 3HAC 1082810 Rot ac motor incl. pinion, 3HAC 14755-1 Item Qty Art. number Description Dimension/Note 103.4.5 4 9ADA 312-7 Plain washer 8,4x16x1,6 103.4.6 4 9ADA 183-37 Hex socket head cap screw M8x25 103.4.7 8 3HAA 1001-172 Washer 8,4x13x1,5 103.4.8 2 2522 122-1 Magnetic plug R1/4” 103.4.9 300 ml 3HAC 16843-1 Lubricating oil, RMO 150 103.4.10 1 ml 3HAB 7116-1 Locking liquid 103.4.11 1 3HAB 3772-65 O-ring 131x2 103.4.12 6 2152 0431-20 O-ring 15,5x1,5 103.4.13 1 3HAC 6862-2 Syncplate 175 kg 103.4.14 6 2121 2518-577 Hex socket head cap screw M14x25 103.4.15 8 3HAB 7700-55 Hex socket head cap screw M8x40 103.4.18 2 9ADA 618-32 Torx pan head screw 103.4.20 1 3HAC 14263-1 Protection Cover 103.4.21 1 9ADA 624-69 Torx counters. head screw M8x20 Item Art. number Description Dimension 103.4.2.1 1 3HAC 10828-5 RV 40E, i=81 103.4.2.2 1 3HAB 3772-58 O-ring 151,99x3,53 Item Qty Art. number Description Dimension 103.4.4.1 1 3HAC 14673-8 Rotational ac motor M8 103.4.4.2 1 3HAC 10122-24 Pinion RV 40E-81 103.4.4.3 0 2152 2012-430 O-ring 89,5x3 103.4.4.4 1 9ADA 183-20 Hex socket head cap screw M5x45 103.4.4.5 2 ml 3HAB 7116-1 Locking liquid 103.4.4.6 1 3HAC 12877-1 Gasket Item Qty Art. number Description 103.4.1 1 3HAC 13752-1 Turning disc, diam. 200 103.4.2 1 3HAC 10828-13 RV 40E-81 assembly 103.4.3 1 3HAC 16009-1 Tilt housing RV70, foundry 103.4.3 1 3HAC 11522-2 Tilt housing RV70 103.4.4 1 3HAC 14754-1 Rot ac motor incl pinion Qty M4x8 Axis 6 complete, 3HAC 13890-2/1 3HAC 16247-1 A Dimension/Note See RV 40E-81 assembly, 3HAC 10828-13 on page 194! See Rot ac motor incl. pinion, 3HAC 14754-1 on page 194! 193 5 Appendix 1: Part Lists 5.1.11 Material set manipulator, 3HAC 13263-1 RV 40E-81 assembly, 3HAC 1082813 Rot ac motor incl. pinion, 3HAC 14754-1 Item Qty Art. number Description Dimension/Note 103.4.5 4 9ADA 312-7 Plain washer 8,4x16x1,6 103.4.6 4 9ADA 183-37 Hex socket head cap screw M8x25 103.4.7 8 3HAA 1001-172 Washer 8,4x13x1,5 103.4.8 2 2522 122-1 Magnetic plug R1/4” 103.4.9 300 ml 3HAC 16843-1 Lubricating oil, RMO 150 103.4.10 1 ml 3HAB 7116-1 Locking liquid 103.4.11 1 3HAB 3772-64 O-ring 150,0x2,0 103.4.12 6 3HAB 3772-61 O-ring 13,1x1,6 103.4.13 1 3HAC 16862-1 Syncplate 175 kg 103.4.14 12 3HAB 7700-65 Hex socket head cap screw M12x30 103.4.15 18 3HAB 7700-55 Hex socket head cap screw M8x40 103.4.18 2 9ADA 618-32 Torx pan head screw 103.4.20 1 3HAC 14263-1 Protection Cover 103.4.21 1 9ADA 624-69 Torx counters. head screw M8x20 Item Art. number Description Dimension Qty M4x8 103.4.2.1 1 3HAC 10828-14 RV 70F, i=125,8 103.4.2.2 1 3HAB 3772-57 O-ring 164,69x3,53 Item Qty Art. number Description Dimension 103.4.4.1 1 3HAC 14673-8 Rotational ac motor M8 103.4.4.2 1 3HAC 11173-3 Pinion RV 70F.125,8 103.4.4.3 0 2152 2012-430 O-ring 89,5x3 103.4.4.4 1 9ADA 183-415 Hex socket head cap screw M5x55 103.4.4.5 2 ml 3HAB 7116-1 Locking liquid 103.4.4.6 1 3HAC 12877-1 Gasket 5.1.11 Material set manipulator, 3HAC 13263-1 Item 194 Qty Art. number Description 108.201 2 3HAC 17212-1 Sealing axis 2/3 108.202 66 3HAB 7700-69 Hex socket head cap screw 108.203 3 3HAC 12703-1 Washer axis3 A Dimension/Note M12x50 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.12 Mtrl.set ax 1-2, 3HAC 13264-1 Item Qty Art. number Description Dimension/Note 108.204 33 3HAA 1001-134 Washer 13x19x1,5 108.206 12 3HAB 7700-69 M12x50 108.207 12 3HAA 1001-134 Washer 108.210 1 3HAC 14300-1 Cable protector 108.212 1 3HAC 11771-1 Cable guide, end part 108.213 1 3HAC 13960-1 Connection plate, ax3 108.214 2 3HAC 12320-1 Damper axis 3 108.215 2 3HAC 12991-1 Damper axis 2 108.216 2 9ADA 624-65 Torx counters. head screw M6x60 108.217 2 9ADA 334-7 Spring washer, conical 8,4x18x2 108.218 2 9ADA 618-57 Torx pan head screw M6x20 108.220 2 3HAC 9953-1 Syncplate with vernier T=1,5 108.222 1 3HAC 12719-1 Syncplate with vernier ax3 T=1,5 108.223 2 9ADA 183-48 Hex socket head cap screw M10x16 108.224 1 3HAC 12844-1 Cable cover 108.225 14 9ADA 618-56 Torx pan head screw 108.228 1 3HAC 3261-1 Cover 108.229 1 3HAC 15431-1 Cable protection 108.230 1 3HAC 14880-1 Cable fixing bracket t=3 108.232 4 3HAC 16721-1 Magnetic plug R 1/2” 108.234 3 9ADA 618-56 Torx pan head screw M6x16 Art. number Description Dimension/Note 109.301 1 3HAC 17271-1 RV 410F-270,176 assembly See RV 410F-270,176 assembly, 3HAC 172711 on page 197! 109.302 1 3HAC 16295-1 Cover, machining 109.302 1 3HAC 16829-1 Cover, machining 109.303 1 3HAC 14699-1 Friction washer 294x333x1,0 109.304 24 3HAB 3409-71 Hex socket head cap screw M12x60 109.305 24 3HAA 1001-134 Washer 13x19x1,5 109.306 1 3HAC 14749-1 Rot ac motor incl pinion See Rot ac motor incl pinion, 3HAC 14749-1 on page 197! 109.307 1 3HAC 14751-1 Rot ac motor incl pinion (175/ 2.55) See Rot ac motor incl pinion, 3HAC 14751-1 on page 197! 109.307 1 3HAC 14750-1 Rot ac motor incl pinion (225/2.25, 175/2.8, 125/3.2, 200/2.75) See Rot ac motor incl pinion, 3HAC 14750-1 on page 197! 109.308 8 3HAB 3409-50 Hex socket head cap screw M10x40 109.309 8 3HAB 4233-1 Washer 109.310 1 3HAC 12252-1 Bottom plate Hex socket head cap screw 13x19x1,5 t = 4 mm M6x16 5.1.12 Mtrl.set ax 1-2, 3HAC 13264-1 Item 3HAC 16247-1 Qty A T=3 195 5 Appendix 1: Part Lists 5.1.12 Mtrl.set ax 1-2, 3HAC 13264-1 Item 196 Qty Art. number Description Dimension/Note 109.311 1 3HAC 14131-1 Connection plate, base t=3 mm 109.312 1 3HAC 11774-3 Adapter, complete See Adapter, compl., 3HAC 11774-3 on page 197! 109.313 1 3HAC 11769-1 Cable guide, ax.1 109.314 1 3HAC 16295-3 Cover 109.315 29 9ADA 183-39 Hex socket head cap screw M8x35 109.316 29 9ADA 312-7 Plain washer 8,4x16x1,6 109.317 1 3HAB 3772-68 O-ring 276x3,53 109.318 1 3HAB 3772-69 O-ring 378x4 109.319 1 3HAB 3772-70 O-ring 340x3,5 109.320 1 3HAC 12671-5 Profile with sync scale 109.321 1 3HAC 12671-6 Block for calibration 109.322 1 3HAC 14024-1 Protection screw See Protection screw, 3HAC 14024-1 on page 198! 109.324 24 9ADA 618-56 Torx pan head screw M6x16 109.325 3 9ADA 618-57 Torx pan head screw M6x20 109.326 1 3HAC 16014-1 Serial measurement unit 109.327 1 3HAC 14692-3 Cover SMB and BRU See Cover SMB and BRU, 3HAC 14692-3 on page 198! 109.328 1 3HAC 16831-1 Battery pack 34x102x63 109.329 1 3HAC 13151-1 Cable battery/SMB L=350±20 109.330 2 3HAC 11526-1 Stud screw M6x150 109.332 1 3HAC 14791-3 Cover battery box See Cover battery box, 3HAC 14791-3 on page 198! 109.334 4 9ADA 618-53 Torx pan head screw M6x8 109.335 1 3HAA 2166-23 VK-Cover D=120, B=12 109.336 1 3HAC 13915-1 Attachment plate 109.337 2 3HAC 12625-1 Strap, Velcro 25x450 109.338 1 3HAC 14792-1 Bracket T=3 109.339 1 3HAC 15619-1 Cable, FB7-SMB 1.7 109.341 7300 3HAC 16843-1 ml Lubricating oil, RMO 150 109.342 4600 3HAC 16843-1 ml Lubricating oil, RMO 150 109.344 1 3HAB 7116-1 Locking liquid 109.345 1 9ADA 298-4 Prev. torque nut, non-met. 109.346 1 3HAC 16035-1 BU w. buttons DSQC 563 109.347 1 3HAC 6499-1 Push button guard 109.348 4 9ADA 629-56 Torx pan head roll. screw M6x16 109.349 2 9ADA 618-58 Torx pan head screw M6x25 109.350 1 3HAC 4813-1 Cover, push button guard 109.351 10 9ADA 618-44 Torx pan head screw A M6 M5x12 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.12 Mtrl.set ax 1-2, 3HAC 13264-1 RV 410F-270,176 assembly, 3HAC 17271-1 Rot ac motor incl pinion, 3HAC 14749-1 Rot ac motor incl pinion, 3HAC 14751-1 Rot ac motor incl pinion, 3HAC 14750-1 Item Qty Art. number Description 109.301.1 1 3HAC 10828-11 RV 410F, i=270,176 109.301.2 2 3HAB 3772-68 Item Qty Art. number O-ring 276x3,53 Description Dimension 109.306.1 1 3HAC 14673-6 Rotational ac motor M6 109.306.2 1 3HAC 11350-1 Pinion RV 500C & RV 320C 109.306.3 0 2152 2012-430 O-ring Item Qty Art. number Dimension Description 89,5x3 Dimension 109.307.1 1 3HAC 14673-6 Rotational ac motor M6 109.307.2 1 3HAC 10122-15 Input gear RV 410F-270,17 109.307.3 0 2152 2012-430 O-ring 89,5x3 109.307.4 1 9ADA 183-444 Hex socket head cap screw M8x130 109.307.5 3 ml 3HAB 7116-1 Locking liquid Item Description Qty Art. number Dimension 109.307.1 1 3HAC 14673-9 Rotational ac motor M9 109.307.2 1 3HAC 10122-15 Input gear RV 410F-270,17 109.307.3 0 2152 2012-430 O-ring 89,5x3 109.307.4 1 9ADA 183-444 Hex socket head cap screw M8x130 109.307.5 3 ml 3HAB 7116-1 Locking liquid Item Qty Art. number Description 109.312.1 1 3HAC 11774-1 Adapter, machined 109.312.2 2 2152 2012-428 O-ring 109.312.3 1 ml 1234 0011-125 Acrylate adhesive Adapter, compl., 3HAC 11774-3 3HAC 16247-1 A Dimension 79,5x3 197 5 Appendix 1: Part Lists 5.1.13 Mtrl set balancing device, 3HAC 13265-1 Protection screw, 3HAC 14024-1 Item Cover SMB and BRU, 3HAC 14692-3 Cover battery box, 3HAC 147913 Qty Art. number Description 109.322.1 1 3HAC 13582-1 Protection Screw 109.322.2 1 3HAB 3772-32 O-ring 17x3 Item Art. number Description Dimension 109.327.1 1 3HAC 14692-1 Cover, casting 109.327.2 1 3HAC 14692-2 Gasket 109.327.3 1 3HAC 14692-4 Rubber cloth Item Art. number Description Dimension 109.332.1 1 3HAC 14791-1 Cover T=4 109.332.2 1 3HAC 14791-2 Gasket T=3 109.332.3 1 3HAC 16977-1 Warning label battery Qty Qty Dimension 5.1.13 Mtrl set balancing device, 3HAC 13265-1 198 Item Qty Art. number Description Dimension 110.401 1 3HAC 12441-2 Spherical roller bearing 65x120x38 110.402 1 3HAC 12481-1 Thrust washer 110.403 1 3HAC 12627-1 Bushing 110.404 1 9ABA 135-31 Retaining ring, shaft 110.405 1 3HAC 12480-1 Shaft 110.406 1 3HAC 4836-7 Protection plug 16x12,3x9x7 110.407 4 3HAB 7700-5 Hex socket head cap screw M16x70 110.408 2 9ABA 107-56 Parallel pin 10x20 110.409 1 3HAC 12548-1 Protection washer T=1 110.410 1 3HAC 12534-1 Shaft, Balancing device 110.411 4 3HAA 1001-186 Washer 110.412 50 ml 3HAA 1001-294 Grease 110.413 2 3HAC 4836-1 Protection plug 20x14,6x7,5x5,5 110.414 1 9ADA 183-490 Hex socket head cap screw M16x180 110.415 1 9ADA 312-10 Plain washer 17x30x3 A 65 17x25x3 3HAC 16247-1 5 Appendix 1: Part Lists 5.1.14 Arm extension set, 250 mm, 3HAC 12311-4 5.1.14 Arm extension set, 250 mm, 3HAC 12311-4 Item Qty Art. number Description Dimension 111.501 1 3HAC 9760-3 Arm extender 250mm 111.501 1 3HAC 15859-2 Arm extender 250mm, Foundry 111.503 12 3HAB 7700-69 Hex socket head cap screw 111.504 12 3HAA 1001-134 Washer 13x19x1,5 111.505 1 9ABA 107-56 Parallel pin 10x20 111.506 1 3HAC 9760-9 Cable cover 250mm 111.507 4 9ADA 618-56 Torx pan head screw M12x50 M6x16 5.1.15 Arm extension set, 450 mm, 3HAC 12311-5 Item 3HAC 16247-1 Qty Art. number Description Dimension 111.501 1 3HAC 9760-7 Arm extender, 450mm 111.501 1 3HAC 15859-3 Arm extender, 450mm, Foundry 111.503 12 3HAB 7700-69 Hex socket head cap screw 111.504 12 3HAA 1001-134 Washer 13x19x1,5 111.505 1 9ABA 107-56 Parallel pin 10x20 111.506 1 3HAC 9760-10 Cable cover 450mm 111.507 6 9ADA 618-56 Torx pan head screw A M12x50 M6x16 199 5 Appendix 1: Part Lists 5.1.15 Arm extension set, 450 mm, 3HAC 12311-5 200 A 3HAC 16247-1 6 Appendix 2: Foldouts 6.0.1 Introduction Chapter 6: Appendix 2: Foldouts 6.0.1 Introduction Definitions This chapter is an appendix to the manual and contains detailed views of the components on the manipulator. The numbered details are specified with item numbers in the Appendix 1: Part List. The foldouts are divided into: 3HAC 16247-1 • Base, incl. frame • Frame-Lower arm 1 • Frame-Lower arm 2 • Upper arm • Wrist complete A 201 6 Appendix 2: Foldouts 6.0.1 Introduction 202 A 3HAC 16247-1 6 Appendix 2: Foldouts 6.0.2 Base incl. Frame 6.0.2 Base incl. Frame 101.2.1 101.2.2 101.1 101.5 101.9 101.6 101.8 101.7 101.2.4 101.2.3 101.3 101.4 xx0200000329 3HAC 16247-1 A 203 6 Appendix 2: Foldouts 6.0.2 Base incl. Frame 204 A 3HAC 16247-1 6 Appendix 2: Foldouts 6.0.3 Frame-Lower arm 1 6.0.3 Frame-Lower arm 1 6.1 .30 109 6.3 .30 109 6.2 .30 109 .303 109 1.1 .30 109 5 .30 109 4 .30 109 8 .31 109 302 109. 15 3 109. 6 9 31 109. .31 109 4 .31 109 317 . 109 32 .2 108 7.1 .30 3 109 .307. 109 .308 109 .309 109 xx0200000334 3HAC 16247-1 A 205 6 Appendix 2: Foldouts 6.0.3 Frame-Lower arm 1 206 A 3HAC 16247-1 6 Appendix 2: Foldouts 6.0.4 Frame-Lower arm 2 6.0.4 Frame-Lower arm 2 40 0. 4 40 0. 11 1 40 0. 2 11 11 108.201, 108.204 110.410 110.414 110.415 11 0. 40 3 11 0. 40 5 108.202 xx0200000335 3HAC 16247-1 A 207 6 Appendix 2: Foldouts 6.0.4 Frame-Lower arm 2 208 A 3HAC 16247-1 6 Appendix 2: Foldouts 6.0.5 Upper arm 6.0.5 Upper arm 1 .1 02 5 .5. xx0200000337 3HAC 16247-1 A 209 6 Appendix 2: Foldouts 6.0.5 Upper arm 210 A 3HAC 16247-1 6 Appendix 2: Foldouts 6.0.6 Wrist complete 6.0.6 Wrist complete xx0200000336 3HAC 16247-1 A 211 6 Appendix 2: Foldouts 6.0.6 Wrist complete 212 A 3HAC 16247-1 Maintenance Manual Industrial Robot IRB 6600 - 225/2.55 IRB 6600 - 175/2.8 IRB 6600 - 175/2.55 IRB 6650 - 200/2.75 IRB 6650 - 125/3.2 M2000A Maintenance Manual, IRB 6600/6650, M2000A 3HAC 16246-1 Revision A The information in this manual is subject to change without notice and should not be construed as a commitment by ABB. ABB assumes no responsibility for any errors that may appear in this manual. In no event shall ABB be liable for incidental or consequential damages arising from use of this manual and products described herein. This manual and parts thereof must not be reproduced or copied without ABB’s written permission, and contents thereof must not be imparted to a third party nor be used for any unauthorized purpose. Contravention will be prosecuted. Additional copies of this manual may be obtained from ABB at its then current charge. ©Copyright 2003 ABB All rights reserved. ABB Automation Technology Products AB Robotics SE-721 68 Västerås Sweden Table of Contents 0.0.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 0.0.2 Product Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 Chapter 1: Safety, service 5 1.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5 Section 1.1: General information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1.1.1 Safety, service - General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 1.1.2 Limitation of Liability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 1.1.3 Related information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 Section 1.2: Safety risks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.1 Safety risks related to gripper. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.2 Safety risks related to tools/workpieces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.3 Safety risks related to pneumatic/hydraulic systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.4 Safety risks during operational disturbances . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 1.2.5 Safety risks during installation and service . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 1.2.6 Risks associated with live electric parts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8 Section 1.3: Safety actions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.1 Safety fence dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.2 Fire extinguishing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.3 Emergency release of the manipulator’s arm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.4 Brake testing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10 1.3.5 Risk of disabling function "Reduced speed 250 mm/s". . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.3.6 Safe use of the Teach Pendant Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 1.3.7 Work inside the manipulator’s working range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 Chapter 2: Reference information 13 2.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13 Section 2.1: Reference information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 2.1.1 Applicable Safety Standards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 2.1.2 Screw joints . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15 2.1.3 Weight specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17 2.1.4 Standard toolkit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18 2.1.5 Special tools, IRB 6600/6650/7600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19 2.1.6 Performing a leak-down test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21 2.1.7 Lifting equipment and lifting instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22 Chapter 3: Service Information System (SIS) 23 3.0.1 Using the SIS system . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 3.0.2 Service Information System (SIS) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24 3.0.3 Defining the SIS input parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .30 3.0.4 Setting the SIS parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .33 3.0.5 Reading the SIS output logs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .35 3.0.6 Exporting the SIS data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .36 Chapter 4: Maintenance schedules and intervals 37 4.0.1 Specification of maintenance intervals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .37 4.0.2 Maintenance schedule, IRB 6600/6650 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .38 4.0.3 Expected component life, IRB 6600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .41 4.0.4 Maintenance schedule, controller S4CPlus M2000A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .42 3HAC 16246-1 i Table of Contents Chapter 5: Maintenance activities, manipulator 43 5.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 Section 5.1: Inspection activities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44 5.1.1 Inspection, oil level gearbox axis 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44 5.1.2 Inspection, oil level gearbox axis 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46 5.1.3 Inspection, oil level gearbox axis 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48 5.1.4 Inspection, oil level gearbox axis 4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 5.1.5 Inspection, oil level, gearbox axis 5. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 5.1.6 Inspection, oil level gearbox axis 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 5.1.7 Inspection, balancing device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56 5.1.8 Inspection, cable harness . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 5.1.9 Inspection, information labels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 5.1.10 Inspection, mechanical stop, axis 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65 5.1.11 Inspection, mechanical stop, axes 1, 2 and 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66 5.1.12 Inspection, damper axes 2-5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 5.1.13 Inspection, position switch axes 1, 2 and 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70 5.1.14 Inspection, UL signal lamp . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 Section 5.2: Changing activities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75 5.2.1 Oil change, gearbox axis 1. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75 5.2.2 Oil change, gearbox axis 2. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 5.2.3 Oil change, gearbox, axis 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81 5.2.4 Oil change, gearbox, axis 4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 5.2.5 Oil change, gearbox, axis 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 5.2.6 Oil change, gearbox axis 6. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87 Section 5.3: Lubrication activities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89 5.3.1 Lubrication, balancing device bearing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89 Section 5.4: Cleaning activities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91 5.4.1 Cleaning, manipulator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91 Chapter 6: Maintenance activities, controller cabinet 93 6.0.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 Section 6.1: Inspection activities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 6.1.1 Inspection of controller cabinet, S4Cplus M2000A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 Section 6.2: Replacement activities. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 6.2.1 Replacement of battery unit, controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 Section 6.3: Cleaning activities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 6.3.1 Cleaning of controller cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 6.3.2 Cleaning computer fans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98 6.3.3 Cleaning Drive units and air outlet device. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 6.3.4 Cleaning Air outlet. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 6.3.5 Cleaning Drain filter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 ii 3HAC 16246-1 0.0.1 Overview 0.0.1 Overview About This Manual This information product is a manual containing instructions for maintenance of the complete robot system, mechanically as well as electrically. Usage This manual should be used during maintenance work. Who Should Read This Manual? This manual is intended for: Prerequisites Organization of Chapters • maintenance personnel in the user's organization. • maintenance personnel in other organizations. The reader should... • be a trained maintenance craftsman • have the required knowledge of mechanical maintenance work OR • have the required knowledge of electrical maintenance work. The information product is organized in the following chapters: Chapter Contents 1 Safety, service 2 Reference information 3 Service Information System (SIS) 4 Maintenance Schedules 5 Maintenance activities 6 Maintenance activities for options References Reference Document Id Circuit diagram, Manipulator 3HAC 13347-1 Circuit diagram, Controller 3HAC 5582-2 Revisions Revision Description 0 First edition A 3HAC 16246-1 • Various corrections in text and in figures due to reconstructions, new spare part numbers, new tools, etc. • Manual completed with references to pagenumbers and numbering of sections (manipulator sections). • Manual completed with version IRB 6650. A 1 0.0.1 Overview 2 A 3HAC 16246-1 0.0.2 Product Documentation 0.0.2 Product Documentation General The complete product documentation kit for the robot, including controller, manipulator and any hardware option, consists of the manuals listed below: Installation and Commissioning Manual The Installation and Commissioning Manual contains the following information: Repair Manual Maintenance Manual • Safety, Service • Reference Information • Unpacking • On-site Installation • Electrical connections • Start-up • Installation of controller software • System directory structure • Calibration • If there is any, model specific information The Repair Manual contains the following information: • Safety, Service • Reference Information • Remove/Refitting instructions for all manipulator details considered spare parts • Remove/Refitting instructions for all controller cabinet details considered spare parts • If there is any, model specific information The Maintenance Manual contains the following information: • Safety, Service • Reference Information • Maintenance schedules • Instructions for all maintenance activities specified in the maintenance schedule, for example cleaning, lubrication, inspection etc. • If there is any, model specific information The information is generally divided into separate chapters for the manipulator and the controller, respectively. Software manuals The software documentation consists of a wide range of manuals, ranging from manuals for basic understanding of the operating system to manuals for entering parameters during operation. A complete listing of all available software manuals is available from ABB Robotics. 3HAC 16246-1 A 3 0.0.2 Product Documentation Hardware option manual Each hardware option is supplied with its own documentation. Each document set contains the types of information specified above: • Installation information • Repair information • Maintenance information In addition, spare part information is supplied for the complete option. 4 A 3HAC 16246-1 1 Safety, service 1.0.1 Introduction Chapter 1: Safety, service 1.0.1 Introduction Definitions This chapter details safety information for service personnel i.e. personnel performing installation, repair and maintenance work. Sections The chapter "Safety, service" is divided into the following sections: 1. General information contains lists of: • Safety, service -general • Limitation of liability • Referenced documents 2. Safety risks lists dangers relevant when servicing the robot system. The dangers are split into different categories: • Safety risks related to gripper/end effector • Safety risks related to tools/workpieces • Safety risks related to pneumatic/hydraulic systems • Safety risks during operational disturbances • Safety risks during installation and service • Risks associated with live electric parts 3. Safety actions details actions which may be taken to remedy or avoid dangers. • Safety fence dimensions • Fire extinguishing • Emergency release of the manipulator´s arm • Brake testing • Risk of disabling function "Reduced speed 250 mm/s" • Safe use of the Teach Pendant Unit enabling device • Work inside the manipulator´s working range 3HAC 16246-1 A 5 1 Safety, service 1.1.1 Safety, service - General Section 1.1: General information 1.1.1 Safety, service - General Validity and responsibility The information does not cover how to design, install and operate a complete system, nor does it cover all peripheral equipment, which can influence the safety of the total system. To protect personnel, the complete system must be designed and installed in accordance with the safety requirements set forth in the standards and regulations of the country where the robot is installed. The users of ABB industrial robots are responsible for ensuring that the applicable safety laws and regulations in the country concerned are observed and that the safety devices necessary to protect people working with the robot system have been designed and installed correctly. Personnel working with robots must be familiar with the operation and handling of the industrial robot, described in the applicable documents, e.g. User’s Guide and Product Manual. Connection of external safety devices Apart from the built-in safety functions, the robot is also supplied with an interface for the connection of external safety devices. Via this interface, an external safety function can interact with other machines and peripheral equipment. This means that control signals can act on safety signals received from the peripheral equipment as well as from the robot. In the Product Manual - Installation and Commissioning, instructions are provided for connecting safety devices between the robot and the peripheral equipment. 1.1.2 Limitation of Liability General Any information given in this information product regarding safety, must not be construed as a warranty by ABB Robotics that the industrial robot will not cause injury or damage even if all safety instructions have been complied with. 1.1.3 Related information General The list below specifies documents which contain useful information: Documents Type of information Detailed in document Installation of safety devices Installation and Commissioning Manual Changing robot modes User’s Guide Restricting the working space Installation and Commissioning Manual 6 A Section Start-up On-site installation Manipulator 3HAC 16246-1 1 Safety, service 1.2.1 Safety risks related to gripper Section 1.2: Safety risks 1.2.1 Safety risks related to gripper Ensure that a gripper is prevented from dropping a workpiece, if such is used. 1.2.2 Safety risks related to tools/workpieces Safe handling It must be possible to turn off tools, such as milling cutters, etc., safely. Make sure that guards remain closed until the cutters stop rotating. It should be possible to release parts by manual operation (valves). Safe design Grippers/end effectors must be designed so that they retain workpieces in the event of a power failure or a disturbance of the controller. 1.2.3 Safety risks related to pneumatic/hydraulic systems General Residual energy Safe design Special safety regulations apply to pneumatic and hydraulic systems. • Residual energy may be present in these systems so, after shutdown, particular care must be taken. • The pressure in pneumatic and hydraulic systems must be released before starting to repair them. • Gravity may cause any parts or objects held by these systems to drop. • Dump valves should be used in case of emergency. • Shot bolts should be used to prevent tools, etc., from falling due to gravity. 1.2.4 Safety risks during operational disturbances General Qualified personnel Extraordinary risks 3HAC 16246-1 • The industrial robot is a flexible tool which can be used in many different industrial applications. • All work must be carried out professionally and in accordance with the applicable safety regulations. • Care must be taken at all times. • Remedial action must only be carried out by qualified personnel who are familiar with the entire installation as well as the special risks associated with its different parts. If the working process is interrupted, extra care must be taken due to risks other than those associated with regular operation. Such an interruption may have to be rectified manually. A 7 1 Safety, service 1.2.5 Safety risks during installation and service 1.2.5 Safety risks during installation and service General risks during installation and service Nation/region specific regulations Non-voltage related risks To be observed by the supplier of the complete system • The instructions in the Product Manual - Installation and Commissioning must always be followed. • Emergency stop buttons must be positioned in easily accessible places so that the robot can be stopped quickly. • Those in charge of operations must make sure that safety instructions are available for the installation in question. • Those who install the robot must have the appropriate training for the robot system in question and in any safety matters associated with it. To prevent injuries and damage during the installation of the robot system, the regulations applicable in the country concerned and the instructions of ABB Robotics must be complied with. • Safety zones, which have to be crossed before admittance, must be set up in front of the robot's working space. Light beams or sensitive mats are suitable devices. • Turntables or the like should be used to keep the operator out of the robot's working space. • The axes are affected by the force of gravity when the brakes are released. In addition to the risk of being hit by moving robot parts, you run the risk of being crushed by the tie rod. • Energy, stored in the robot for the purpose of counterbalancing certain axes, may be released if the robot, or parts thereof, is dismantled. • When dismantling/assembling mechanical units, watch out for falling objects. • Be aware of stored heat energy in the controller. • Never use the robot as a ladder, i.e. do not climb on the robot motors or other parts during service work. There is a serious risk of slipping because of the high temperature of the motors or oil spills that can occur on the robot. • The supplier of the complete system must ensure that all circuits used in the safety function are interlocked in accordance with the applicable standards for that function. • The supplier of the complete system must ensure that all circuits used in the emergency stop function are interlocked in a safe manner, in accordance with the applicable standards for the emergency stop function. 1.2.6 Risks associated with live electric parts Voltage related risks, general Voltage related risks, controller 8 • Although troubleshooting may, on occasion, have to be carried out while the power supply is turned on, the robot must be turned off (by setting the mains switch to OFF) when repairing faults, disconnecting electric leads and disconnecting or connecting units. • The mains supply to the robot must be connected in such a way that it can be turned off outside the robot’s working space. A danger of high voltage is associated with the following parts: • Be aware of stored electrical energy (DC link) in the controller. A 3HAC 16246-1 1 Safety, service 1.2.6 Risks associated with live electric parts • Units inside the controller, e.g. I/O modules, can be supplied with power from an external source. • The mains supply/mains switch • The power unit • The power supply unit for the computer system (230 VAC) • The rectifier unit (400-480 VAC and 700 VDC. Note: Capacitors!) • The drive unit (700 VDC) • The service outlets (115/230 VAC) • The power supply unit for tools, or special power supply units for the machining process • The external voltage connected to the control cabinet remains live even when the robot is disconnected from the mains. • Additional connections Voltage related risks, manipulator A danger of high voltage is associated with the manipulator in: Voltage related risks, tools, material handling devices, etc Tools, material handling devices, etc., may be live even if the robot system is in the OFF position. Power supply cables which are in motion during the working process may be damaged. 3HAC 16246-1 • The power supply for the motors (up to 800 VDC) • The user connections for tools or other parts of the installation (max. 230 VAC, see Installation and Commissioning Manual) A 9 1 Safety, service 1.3.1 Safety fence dimensions Section 1.3: Safety actions 1.3.1 Safety fence dimensions General Fit a safety fence or enclosure around the robot to ensure a safe robot installation. Dimensioning Dimension the fence or enclosure to enable it to withstand the force created if the load being handled by the robot is dropped or released at maximum speed. Determine the maximum speed from the maximum velocities of the robot axes and from the position at which the robot is working in the work cell (see Product Specification - Description, Robot Motion). Also consider the maximum possible impact caused by a breaking or malfunctioning rotating tool or other device fitted to the manipulator. 1.3.2 Fire extinguishing Use a CARBON DIOXIDE (CO 2 ) extinguisher in the event of a fire in the robot (manipulator or controller)! 1.3.3 Emergency release of the manipulator’s arm Description In an emergency situation, any of the manipulator’s axes may be released manually by pushing the brake release buttons on the manipulator or on an optional external brake release unit. How to release the brakes is detailed in section "Manually releasing the brakes". The manipulator arm may be moved manually on smaller robot models, but larger models may require using an overhead crane or similar. Increased injury Before releasing the brakes, make sure that the weight of the arms does not increase the pressure on the trapped person, which may further increase any injury! 1.3.4 Brake testing When to test During operation the holding brakes of each axis motor wear normally. A test may be performed to determine whether the brake can still perform its function. How to test The function of each axis’ motor holding brakes may be checked as detailed below: 1. Run each manipulator axis to a position where the combined weight of the manipulator arm and any load is maximized (max. static load). 2. Switch the motor to the MOTORS OFF position with the Operating mode selector on the controller. 3. Check that the axis maintains its position. If the manipulator does not change position as the motors are switched off, then the brake function is adequate. 10 A 3HAC 16246-1 1 Safety, service 1.3.5 Risk of disabling function "Reduced speed 250 mm/s" 1.3.5 Risk of disabling function "Reduced speed 250 mm/s" Do not change "Transm gear ratio" or other kinematic parameters from the Teach Pendant Unit or a PC. This will affect the safety function Reduced speed 250 mm/s. 1.3.6 Safe use of the Teach Pendant Unit The enabling device is a push button located on the side of the Teach Pendant Unit (TPU) which, when pressed halfway in, takes the system to MOTORS ON. When the enabling device is released or pushed all the way in, the robot is taken to the MOTORS OFF state. To ensure safe use of the Teach Pendant Unit, the following must be implemented: The enabling device must never be rendered inoperative in any way. During programming and testing, the enabling device must be released as soon as there is no need for the robot to move. The programmer must always bring the Teach Pendant Unit with him/her, when entering the robot’s working space. This is to prevent anyone else taking control over the robot without the programmer knowing. 1.3.7 Work inside the manipulator’s working range If work must be carried out within the robot’s work envelope, the following points must be observed: - The operating mode selector on the controller must be in the manual mode position to render the enabling device operative and to block operation from a computer link or remote control panel. - The robot’s speed is limited to max. 250 mm/s when the operating mode selector is in position < 250 mm/s. This should be the normal position when entering the working space. The position 100% ”full speed”may only be used by trained personnel who are aware of the risks that this entails. - Pay attention to the rotating axes of the manipulator! Keep a distance to the axes in order not to get entangled with hair or clothing. Also be aware of any danger that may be caused by rotating tools or other devices mounted on the manipulator or inside the cell. - Test the motor brake on each axis, according to section Brake testing on page 10. 3HAC 16246-1 A 11 1 Safety, service 1.3.7 Work inside the manipulator’s working range 12 A 3HAC 16246-1 2 Reference information 2.0.1 Introduction Chapter 2: Reference information 2.0.1 Introduction General 3HAC 16246-1 This chapter presents generic pieces of information, complementing the more specific information in the following chapters. A 13 2 Reference information 2.1.1 Applicable Safety Standards Section 2.1: Reference information 2.1.1 Applicable Safety Standards Standards, general Standards, robot cell 14 The robot is designed in accordance with the requirements of: • EN 775 - Robot safety. • EN 292-1 - Basic terminology. • EN 292-2 - Technical principles. • EN 418 - Emergency stop. • EN 563 - Temperatures of surfaces. • EN 954-1 - Safety related parts of control systems. • EN 60204-1 - Electrical equipment of machines. • EN 1050 - Principles for risk assessment. • ANSI/RIA 15.06-1999 - Industrial robots, safety requirements. • DIN 19258 - Interbus-S, International Standard The following standards are applicable when the robot is part of a robot cell: • EN 953 - Fixed and moveable guards • EN 811 - Safety distances to prevent danger zones being reached by the lower limbs. • EN 349 - Minimum gaps to avoid crushing of parts of the human body. • EN 294 - Safety distances to prevent danger zones being reached by the upper limbs. • EN 1088 - Interlocking devices • EN 999 - The positioning of protective equipment in respect of approach speeds of the human body. • ISO 11 161 - Industrial automation systems - Safety of intergrated manufacturing systems. A 3HAC 16246-1 2 Reference information 2.1.2 Screw joints 2.1.2 Screw joints General This section details how to tighten the various types of screw joints on the manipulator as well as the controller. The instructions and torque values are valid for screw joints comprising metallic materials and do not apply to soft or brittle materials. Any instructions given in the repair, maintenance or installation procedure description override any value or procedure given here, i.e. these instruction are only valid for standard type screw joints. UNBRAKO screws UNBRAKO is a special type of screw recommended by ABB in certain screw joints. It features special surface treatment (Gleitmo as described below), and is extremely resistant to fatigue. Whenever used, this is specified in the instructions and in such cases no other type of replacement screw is allowed. Using other types of screw will void any warranty and may potentially cause serious damage or injury! Gleitmo treated screws Gleitmo is a special surface treatment to reduce the friction when tightening the screw joint. Screws treated with Gleitmo may be reused 3-4 times before the coating disappears. After this the screw must be discarded and replaced with a new one. When handling screws treated with Gleitmo, protective gloves of nitrile rubber type should be used. Screws lubricated in other ways Screws lubricated with Molycote 1000 (or another lubricant) should only be used when specified in the repair, maintenance or installation procedure descriptions. In such cases, proceed as follows: 1. Lubricate the thread of the screw. 2. Lubricate between the plain washer and screw head. 3. Tighten to the torque specified in section "Tightening torque" below. Screw dimensions of M8 or larger must be tightened with a torque wrench. Screw dimensions of M6 or smaller may be tightened without a torque wrench if this is done by trained and qualified personnel. Tightening torque 3HAC 16246-1 Lubricant Art. no. Molycote 1000 (molybdenum disulphide grease) 1171 2016-618 Below are tables specifying the torque values for different screw joint types: A 15 2 Reference information 2.1.2 Screw joints Screws with slotted or cross recess head Dimension Tightening torque (Nm) Class 4.8 "dry" M2.5 0.25 M3 0.5 M4 1.2 M5 2.5 M6 5.0 Dimension Tightening torque (Nm) Class 8.8 "dry" Tightening torque (Nm) Class 10.9 "dry" Tightening torque (Nm) Class 12.9 "dry" M5 6 - - M6 10 - - M8 24 34 40 M10 47 67 80 M12 82 115 140 M16 200 290 340 Dimension Tightening torque (Nm) Class 10.9 Tightening torque (Nm) Class 12.9 M8 28 34 M10 55 66 M12 96 115 M16 235 280 Screws with hexagon socket head, “dry” Screws with hexagon socket head, lubricated 16 A 3HAC 16246-1 2 Reference information 2.1.3 Weight specifications 2.1.3 Weight specifications Definition In all repair and maintenance instructions, weights of the components handled are sometimes specified. All components exceeding 22 kg (50 lbs) are high-lighted in this way. ABB recommends the use of lifting equipment when handling components with a weight exceeding 22 kg to avoid inflicting injury. A wide range of lifting tools and devices is available for each manipulator model. Example Below is an example of how a weight specification is presented: The motor weighs 65 kg! All lifting equipment used must be dimensioned accordingly! 3HAC 16246-1 A 17 2 Reference information 2.1.4 Standard toolkit 2.1.4 Standard toolkit General All service (repairs, maintenance and installation) instructions contain lists of tools required to perform the specified activity. All special tools required are listed directly in the instructions while all the tools that are considered standard are gathered in the Standard toolkit and defined in the table below. In this way, the tools required are the sum of the Standard Toolkit and any tools listed in the instruction. Contents, standard toolkit, 3HAC 15571-1 18 Qty Art. no. Tool Rem. 1 - Ring-open-end spanner 8-19mm 1 - Socket head cap 5-17mm 1 - Torx socket no:20-60 1 - Box spanner set 1 - Torque wrench 10-100Nm 1 - Torque wrench 75-400Nm 1 - Ratchet head for torque wrench 1/2 2 - Hexagon-headed screw M10x100 1 - Socket head cap no:14, socket 40mm bit L 100mm 1 - Socket head cap no:14, socket 40mm bit L 20mm To be shorted to 12mm 1 - Socket head cap no:6, socket 40mm bit L 145mm A 3HAC 16246-1 2 Reference information 2.1.5 Special tools, IRB 6600/6650/7600 2.1.5 Special tools, IRB 6600/6650/7600 General All service (repairs, maintenance and installation) instructions contain lists of tools required to perform the specified activity. The required tools are a sum of standard tools, defined in section Standard toolkit on page 18, and of special tools, listed directly in the instructions and also gathered in the table below. Special tools, IRB 6600/6650/7600 The table below is an overview of all the special tools required when performing service activities on the IRB 6600/6650/7600. The tools are gathered in two kits: Basic Toolkit (3HAC 15571-3) and Extended Toolkit (3HAC 15571-2). The special tools are also listed directly in the current instructions. 3HAC 16246-1 Description IRB 66X0/ IRB 7600/ Art. no. Qty Qty Angel bracket a a 68080011-LP Bolts (M16 x 60) for Mech stop ax 3 2 - 3HAB 3409-86 Bolts (M16 x 80) for Mech stop ax 3 - 2 3HAB 3409-89 Cal. tool a a 68080011-GM Calibration bracket a - 3HAC 13908-9 Calibration tool ax1 a a 3HAC 13908-4 CalPen (Calibration Pendulum) 1 1 3HAC 15716-1 Extension 300mm for bits 1/2" 1 1 3HAC 12342-1 Fixture lower arm 1 - 3HAC 13659-1 Fixture lower arm - 1 3HAC 13660-1 Gearbox crank 1 - 3HAC 16488-1 Guide pins M12 x 150 2 - 3HAC 13056-2 Guide pins M12 x 200 2 - 3HAC 13056-3 Guide pins M12 x 250 1 - 3HAC 13056-4 Guide pins M8 x 100 2 - 3HAC 15520-1 Guide pins M8 x 150 2 - 3HAC 15520-2 Guide pins sealing - b 3HAC 14445-1 Guide pins sealing b - 3HAC 14446-1 Guide pins M10 x 100 2 2 3HAC 15521-1 Guide pins M10 x 150 2 2 3HAC 15521-2 Guide pins M16 x 150 - 2 3HAC 13120-2 Guide pins M16 x 200 - 2 3HAC 13120-3 Guide pins M16 x 250 - 1 3HAC 13120-4 Guide pins M16 x 300 2 2 3HAC 13120-5 Guide pins sealing ax 2, 3, 100mm 1 - 3HAC 14628-2 Guide pins sealing ax 2, 3, 80mm 1 - 3HAC 14628-1 Guide pins sealing ax 2, 3, 100mm - 1 3HAC 14627-3 Guide pins sealing ax 2, 3, 80mm - 1 3HAC 14627-2 Hydraulic cylinder 1 1 3HAC 11731-1 A 19 2 Reference information 2.1.5 Special tools, IRB 6600/6650/7600 Description IRB 66X0/ IRB 7600/ Art. no. Qty Qty Hydraulic pump 80Mpa 1 1 3HAC 13086-1 Hydraulic pump 80Mpa (Glycerin) b b 3HAC 13086-2 Levelmeter 2000 kit a a 6369901-348 Lifting device, base 1 1 3HAC 15560-1 Lifting device, manipulator 1 1 3HAC 15607-1 Lifting device, upper arm 1 - 3HAC 15994-1 Lifting device, upper arm - 1 3HAC 15536-1 Lifting eye VLBG M12 1 1 3HAC 16131-1 Lifting eye M12 2 2 3HAC 14457-3 Lifting eye M16 2 2 3HAC 14457-4 Lifting tool (chain) 1 1 3HAC 15556-1 Lifting tool, gearbox ax 2 1 - 3HAC 13698-1 Lifting tool, gearbox ax 2 - 1 3HAC 12731-1 Lifting tool, lower arm b b 3HAC 14691-1 Lifting tool, motor ax 1, 4, 5 1 1 3HAC 14459-1 Lifting tool, motor ax 2, 3, 4 1 1 3HAC 15534-1 Lifting tool, wrist unit 1 - 3HAC 13605-1 Lifting tool, wrist unit - 1 3HAC 12734-1 Measuring pin a - 3HAC 13908-5 Mech stop ax 3 2 - 3HAC 12708-1 Mech stop ax 3 - 2 3HAC 12708-2 Press tool, ax 2 bearing 1 - 3HAC 13527-1 Press tool, ax 2 bearing - 1 3HAC 13453-1 Press tool, ax 2 shaft 1 1 3HAC 13452-1 Press tool, balancing device shaft 1 1 3HAC 17129-1 Press tool, balancing device 1 1 3HAC 15767-1 Puller tool, balancing device shaft 1 1 3HAC 12475-1 Removal tool, wheel unit - 1 3HAC 15814-1 Removal tool, motor M10x 2 2 3HAC 14972-1 Removal tool, motor M12x 2 2 3HAC 14631-1 Removal tool, motor M12x 2 2 3HAC 14973-1 Rotation tool 1 1 3HAC 17105-1 Sensor plate a 1 3HAC 0392-1 Support, base 1 1 3HAC 15535-1 Sync. adapter a a 3HAC 13908-1 Tool set balancing device 1 - 3HAC 15943-2 Tool set balancing device - 1 3HAC 15943-1 Turn disk fixture a a 3HAC 68080011-GU Washers for Mech stop axis 3 2 2 3HAA 1001-186 Note a) Calibration tools for IRB 6600/6650/7600 when CalPen is not used (standard). Note b) Special tools that may be rent from ATRP/S. 20 A 3HAC 16246-1 2 Reference information 2.1.6 Performing a leak-down test 2.1.6 Performing a leak-down test General After refitting any motor and any gearbox, the integrity of all seals enclosing the gearbox oil must be tested. This is done in a leak-down test. Required equipment Equipment, etc. Spare part no. Art. no. Leakdown tester Note 3HAC 0207-1 Leak detection spray Procedure Step 3HAC 16246-1 Action Note/Illustration 1. Finish the refitting procedure of the motor or gear in question. 2. Remove the topmost oil plug on the gear in question, Art. no. specified above! and replace it with the leakdown tester . Adapters may be required, which are included in the leakdown tester kit. 3. Apply compressed air, and raise the pressure with the knob until the correct value is shown on the manometer. 4. Disconnect the compressed air supply. 5. Wait for approx. 8-10 minutes. No pressure loss must be detected. 6. Was any pressure drop evident? Localize the leak as detailed below. Remove the leakdown tester, and refit the oil plug. The test is complete. 7. Spray suspected leak areas with leak detection spray . Bubbles indicate a leak. 8. When the leak has been localized: take the necessary measures to correct the leak. A Recommended value: 0.2 0.25 bar (20 - 25 kPa) If the compressed air is significantly colder or warmer than the gearbox to be tested, a slight pressure increase or decrease respectively may occur. This is quite normal. Art. no. specified above! 21 2 Reference information 2.1.7 Lifting equipment and lifting instructions 2.1.7 Lifting equipment and lifting instructions General Many repair and maintenance activities require different pieces of lifting equipment, which are specified in each activity instruction. However, how to use each piece of lifting equipment is not detailed in the activity instruction, but in the instruction delivered with each piece of lifting equipment. This implies that the instructions delivered with the lifting equipment should be stored for later reference. 22 A 3HAC 16246-1 3 Service Information System (SIS) 3.0.1 Using the SIS system Chapter 3: Service Information System (SIS) 3.0.1 Using the SIS system General This is a brief description of how to use the Service Information System, SIS. Details may be found in: • Service Information System, SIS • Defining the SIS input parameters • Setting the SIS parameters • Importing/exporting SIS data • Reading the SIS output logs Basic procedure Step 3HAC 16246-1 Action Reference 1. Determine which of the system function you require. These are described in Service Information System (SIS) on page 24. 2. Define what values are adequate and suitable for your application in your production environment. Recommendations on how to define these are given in Defining the SIS input parameters on page 30. Maintenance intervals recommended by ABB are specified in section "Maintenance Schedule" in the Maintenance Manual. 3. Enter these parameters in the system. How to do this is detailed in Setting the SIS parameters on page 33. 4. Run the robot in normal operation. 5. Reset the counter if a repair has to be The TPU displays for resetting any SIS made, or if a counter for any other reason value are shown in Service Information has to be restarted. System (SIS) on page 24. 6. When a time limit, set in the parameters, How to access this is detailed in Reading is exceeded, a message may be read on the SIS output logs on page 35. the Tech Pendant Unit (TPU). 7. If the log containing the message is to be These are described in Exporting the SIS available from an external PC, or if the data on page 36. SIS parameters are to be entered from an external PC, a set of software tools are available to build such an application. A 23 3 Service Information System (SIS) 3.0.2 Service Information System (SIS) 3.0.2 Service Information System (SIS) General Service Information System (SIS) is a software function within the robot controller, which simplifies maintenance of the robot system. It supervises the operating time and mode of the robot, and alerts the operator when a maintenance activity is scheduled. Supervised functions The following counters may be set: • Calendar time counter, a general alarm based on calendar time • Operation time counter, a general alarm based on operational time • Gearbox 1 operation time counter, based on percentage of the axis 1 gearbox service interval • Gearbox 2 operation time counter, based on percentage of the axis 2 gearbox service interval • Gearbox 3 operation time counter, based on percentage of the axis 3 gearbox service interval • Gearbox 6 operation time counter, based on percentage of the axis 6 gearbox service interval The figure below show the different selections possible: xx0200000034 x OK 24 "OK" indicates that no service interval limit has been exceeded by that counter. If any such limit was exceeded, the counter name would be followed by "NOK". A 3HAC 16246-1 3 Service Information System (SIS) 3.0.2 Service Information System (SIS) Calendar time This is a clock within the control system that enables you to set a specific service interval, based on calendar time: xx0200000035 After this time, a message is accessible on the Tech Pendant Unit (TPU). How to access this is detailed in section Reading the SIS output logs on page 35. Operation time Prev service Date when the counter was reset last time, i.e. after the last service. This date was entered manually as detailed in section Setting the SIS parameters on page 33. Elapsed time Elapsed time since the counter was reset the last time. Next service Date when next scheduled service is planned. This date is entered manually as detailed in section Setting the SIS parameters on page 33. Remaining time Remaining time to next scheduled service date. This is a function within the control system that counts the amount of time the "MOTORS ON" signal is active, i.e. the amount of time the robot is in the operational mode. xx0200000036 After this time, a message is accessible on the Teach Pendant Unit (TPU). How to access this is detailed in section Reading the SIS output logs on page 35. 3HAC 16246-1 Service interval The specified service interval until another service will be required. This parameter was entered manually as detailed in section Setting the SIS parameters on page 33. Elapsed time Operation time since the service interval was set the last time. Remaining time Remaining operation time until the time set in service interval has expired. A 25 3 Service Information System (SIS) 3.0.2 Service Information System (SIS) Gearbox Based on measurements, torque and RPM, for example, the system calculates an expected service interval for each gearbox. When service is due, a message will be shown on the TPU. How to access this is detailed in section Reading the SIS output logs on page 35. en0200000037 Axis x OK Service status for axis x, i.e. the automatically calculated time parameter has not been exceeded. Axis x NOK The service interval for the axis in question has been reached. Axis x N/A No service time parameter calculation available. Applies to axes 4 and 5 (IRB 6600 and IRB 7600). en0200000038 This example shows the window for axis 1, but is also valid for the other axes. 26 Consumed time The consumed time as a percentage of the total amount of time. Elapsed time Operation time for axis x since calculation began. Remaining time Remaining operation time for axis x until the service time parameter value has been reached. A 3HAC 16246-1 3 Service Information System (SIS) 3.0.2 Service Information System (SIS) Reset values All counters may be reset at any time. en0200000040 When resetting, both variables sisRestartDate and sisCalendarT are reset! The variables are described in section Exporting the SIS data on page 36! Yes Resets the counter to zero. No Does not reset the counter, but returns to the previous menu. en0200000041 When resetting, variable sisRunT is reset! The variables are described in section Exporting the SIS data on page 36! 3HAC 16246-1 Yes Resets the counter to zero. No Does not reset the counter, but returns to the previous menu. A 27 3 Service Information System (SIS) 3.0.2 Service Information System (SIS) en0200000039 When resetting, both variables sisL10h_x and sisL10h_Time_x are reset! The variables are described in section Exporting the SIS data on page 36! Service interval exceeded Yes Resets the counter to zero. No Does not reset the counter, but returns to the previous menu. When the service time has been exceeded for the selection made, a message (Service interval exceeded!) is displayed below the data of the counter in question: en0200000044 This window may be shown for any time mode; calendar time, operation time or gearbox time. In addition to this view, an error message is also displayed on the TPU when the service interval is exceeded! 28 A 3HAC 16246-1 3 Service Information System (SIS) 3.0.2 Service Information System (SIS) No data available When no data is available for the selection made, a message (No data available!) is displayed below the function in question: en0200000043 This window may be shown for any time mode; calendar time, operation time or gearbox time. Exit en0200000042 3HAC 16246-1 Yes Exits the Service Information System. No Returns to the Service Information System. A 29 3 Service Information System (SIS) 3.0.3 Defining the SIS input parameters 3.0.3 Defining the SIS input parameters General This section details the parameters that may be set with estimated values. The values can be defined by the operating organization as knowledge of the robot’s working conditions are accumulated. Since the counters are to be used for purposes defined by the user, ABB cannot give any recommendations regarding their definitions. The figure below shows the options of parameters to be set. en0200000049 Operation time limit (service level) The number of operation hours selected as service interval. E.g. by setting the value "20,000", the SIS will save this as the nominal time for activating the alarm, not counting the percentage described below. en0200000054 30 A 3HAC 16246-1 3 Service Information System (SIS) 3.0.3 Defining the SIS input parameters Operation time warning A percentage of the "Operation time limit" specified above. E.g. by setting the value "90", the SIS will alert the operator 18,000 hours after an operation time "Reset" was made the last time. en0200000053 Calendar time limit (service level) The number of calendar years selected as service interval. E.g. by setting the value "2", the SIS will save this as the nominal time for activating the alarm, not counting the percentage described below. en0200000050 Calendar time warning A percentage of the "Calendar time limit" specified above. E.g. by setting the value "90", the SIS will alert the operator after 90% of two years, i.e. 657 days after a calendar time "Reset" was made the last time. en0200000051 3HAC 16246-1 A 31 3 Service Information System (SIS) 3.0.3 Defining the SIS input parameters Gearbox warning A percentage of the gearbox service interval as calculated by the system. E.g. by setting the value "90", the SIS will alert the operator after 90% of the expected service interval of each gearbox. The robot system automatically detects and stores all required variables to calculate the expected service interval of each gearbox. This is done by extrapolating data from earlier operation into a function of time, using a formula including: • input and output torque • gearbox spindle speed • other variables en0200000052 32 A 3HAC 16246-1 3 Service Information System (SIS) 3.0.4 Setting the SIS parameters 3.0.4 Setting the SIS parameters General If the SIS system is to function properly, a number of parameters must be set. How to do this is detailed below. Procedure This is an instruction of how to enter SIS parameters to the robot system. Step Action Rem. 1. Open "System parameters" using the TPU. Detailed in the User’s Guide. 2. Go to "System parameters/Manipulator/ types 2". xx0200000045 en0200000046 3. Select "0 SIS parameters" and press "Enter". en0200000047 xx0100000200 3HAC 16246-1 A 33 3 Service Information System (SIS) 3.0.4 Setting the SIS parameters Step 4. Action Rem. Select the required system The parameter list is displayed. en0200000048 en0200000049 5. 34 Select the required parameters by step- Available parameters are described in ping up and down through the parame- Defining the SIS input parameters on page ter list. 30! A 3HAC 16246-1 3 Service Information System (SIS) 3.0.5 Reading the SIS output logs 3.0.5 Reading the SIS output logs General Whenever a set condition has expired (e.g. max allowed operation time before service), a message to this effect will be shown in the Operational log. Access to logs How to open any log and show its contents is detailed in the "User’s Guide", chapter "Service". Available messages The following messages may be shown: Available in: 3HAC 16246-1 SIS message in Operational log Meaning Calendar time Service Message Service is due! X calendar days since last service. The manually set calendar time limit has expired. How to set the limit is detailed in section Setting the SIS parameters on page 33. Proceed with the required service as detailed in the Repair Manual or Maintenance Manual depending on which type of service. Calendar time Service Message X calendar days to next service. X number of calendar days remain until the manually set calendar time limit expires. How to set the value determining when the message is to be shown, is detailed in section Setting the SIS parameters on page 33. Operation time Service Message Service is due! X production hours since last service. The manually set operation time limit has expired. How to set the limit is detailed in section Setting the SIS parameters on page 33. Proceed with the required service as detailed in the Repair Manual or Maintenance Manual depending on which type of service. Operation time Service Message X production hours to next service. X number of operation hours remain until the manually set operation time limit expires. How to set the value determining when the message is to be shown, is detailed in section Setting the SIS parameters on page 33. Gearbox time Service Message Gearbox x requires service! The automatically calculated gearbox time limit has expired. Proceed with the required service as detailed in the Repair Manual or Maintenance Manual depending on which type of service. Gearbox time Service Message X percent of gearbox hours remain until the autoX% of the service inter- matically calculated gearbox time limit expires. val has expired for How to set the value determining when the mesgearbox x! sage is to be shown, is detailed in section Setting the SIS parameters on page 33. A 35 3 Service Information System (SIS) 3.0.6 Exporting the SIS data 3.0.6 Exporting the SIS data General This section describes the available variables for entering SIS parameters as well as showing any messages of exceeded time limits as detected by the SIS counters on an external PC using "Webware SDK". How to access these variables and how to perform the actual programming sequences are detailed in the robot system User’s Guide. Definitions 36 The table below defines the names and functions of all software variables available for communication between the SIS and an external computer. Signal Unit Counter type sisRestartDate sec Calendar time The date on which the supervision was started/ reset last time. Expressed in seconds starting 1/1 1970 (in accordance with ANSI c-standard). sisCalendarT sec Calendar time The number of seconds since start/last reset. sisTotRunT sec Operation time Total number of operation seconds since the system was started. Corresponds to the operating time counter on the control cabinet. sisRunT sec Operation time The number of operation seconds since start/last reset of the operation time counter. Corresponds to the operating time counter on the control cabinet. sisL10h_1 hrs Gearbox time Estimated life of gearbox axis 1 sisL10h_Time_1 sec Gearbox time Operation time of gearbox axis 1 sisL10h_2 hrs Gearbox time Estimated life of gearbox axis 2 sisL10h_Time_2 sec Gearbox time Operation time of gearbox axis 2 sisL10h_3 hrs Gearbox time Estimated life of gearbox axis 3 sisL10h_Time_3 sec Gearbox time Operation time of gearbox axis 3 sisL10h_6 hrs Gearbox time Estimated life of gearbox axis 6 sisL10h_Time_6 sec Gearbox time Operation time of gearbox axis 6 A Function 3HAC 16246-1 4 Maintenance schedules and intervals 4.0.1 Specification of maintenance intervals Chapter 4: Maintenance schedules and intervals 4.0.1 Specification of maintenance intervals Description 3HAC 16246-1 The intervals may be specified in different ways depending on the type of maintenance activity to be carried out and the working conditions of the robot: • Calendar time: specified in months regardless of whether the robot system is run or not. • Operating time: specified in operating hours. More frequent running of the robot means more frequent maintenance activities. • SIS: specified by the robot's Service Information System (SIS). How to access this information is detailed in section "Access to SIS information". A typical value is given for a typical work cycle, but the value will differ depending on how hard each part is run. A 37 4 Maintenance schedules and intervals 4.0.2 Maintenance schedule, IRB 6600/6650 4.0.2 Maintenance schedule, IRB 6600/6650 General The robot, consisting of manipulator and controller cabinet, must be maintained regularly to ensure its function. The maintenance activities and their respective intervals are specified in the table below. Non-predictable situations also give rise to inspections of the robot. If damage is discovered, attend to it immediately! The inspection intervals do not specify the life of each component. Values for these are specified in Expected component life, IRB 6600 on page 41. Activities and intervals, standard equipment 38 The section referred to in the table can be found in the different chapters for every maintenance activity. The table below specifies the required maintenance activities and intervals: Maintenance Equipment activity Interval Note Inspection Axis 1 gear, oil level 12 mths Ambient tempera- "Inspection, oil level, ture below 50 °C 1 gearbox axis 1" Inspection Axis 2 gear, oil level 12 mths Ambient tempera- "Inspection, oil level, ture below 50 °C 1 gearbox axis 2" Inspection Axis 3 gear, oil level 12 mths Ambient tempera- "Inspection, oil level, ture below 50 °C 1 gearbox axis 3" Inspection Axis 4 gear, oil level 12 mths "Inspection, oil level gearbox axis 4" Inspection Axis 5 gear, oil level 12 mths "Inspection, oil level gearbox axis 5" Inspection Axis 6 gear, oil level 12 mths Ambient tempera- "Inspection, oil level ture below 50 °C 1 gearbox axis 6" Inspection Balancing device 12 mths "Inspection, balancing device" Inspection Manipulator har- 12 mths ness "Inspection, cable harness" Inspection Information labels 12 mths "Inspection, information labels" Inspection Damper axes 2-5 12 mths "Inspection damper, axes 2-5" Inspection Mechanical stop, 12 mths axis 1 "Inspection mechanical stop, axis 1" Changing Axis 1 gear, oil 48 mths Ambient tempera- "Oil change, gearbox ture below 50 °C 1 axis 1" Changing Axis 2 gear, oil 48 mths Ambient tempera- "Oil change, gearbox ture below 50 °C 1 axis 2" Changing Axis 3 gear, oil 48 mths Ambient tempera- "Oil change, gearbox ture below 50 °C 1 axis 3" Changing Axis 4 gear, oil 48 mths Ambient tempera- "Oil change, gearbox ture below 50 °C 1 axis 4" Changing Axis 5 gear, oil 48 mths Ambient tempera- "Oil change, gearbox ture below 50 °C 1 axis 5" A Detailed in section 3HAC 16246-1 4 Maintenance schedules and intervals 4.0.2 Maintenance schedule, IRB 6600/6650 Maintenance Equipment activity Interval Note Changing Axis 6 gear, oil 48 mths Ambient tempera- "Oil change, gearbox ture below 50 °C 1 axis 6" Replacement Axis 1 gear, oil As specified by the SIS, or typically 96 mths "Remove/Refit, gearbox axis 1" in Repair Manual Replacement Axis 2 gear, oil As specified by the SIS, or typically 96 mths "Remove/Refit, gearbox axis 2" in Repair Manual Replacement Axis 3 gear, oil As specified by the SIS, or typically 96 mths "Remove/Refit, gearbox axis 3" in Repair Manual Replacement Axis 4 gear 96 mths 2 "Remove/Refit, upper arm without wrist unit" in Repair Manual Replacement Axis 5 gear 96 mths 2 "Remove/Refit, complete wrist unit" in Repair Manual Replacement Axis 6 gear As specified by the SIS, or typically 96 mths "Remove/Refit, gearbox axis 6" in Repair Manual Replacement Manipulator har- See note ness below 3 "Remove/Refit, cable harness" in Repair Manual Replacement SMB Battery pack 36 mths "Removal/Refitting of SMB related equipment" in Repair Manual Lubrication Balancing device 48 mths 4 bearing "Lubrication, balancing device bearing" Detailed in section 1) If the robot is run at temperatures higher than 50 °C, the manipulator may require maintenance more frequently. 2) The service time for gearboxes, axes 4 and 5, is not calculated by the SIS, see expected life in section Expected component life, IRB 6600 on page 41. 3) Replace when damage is detected or when approaching life limit as specified in Expected component life, IRB 6600 on page 41. 4) The interval is the same as the interval for changing axis 2 gear oil because of the similarity of the type and degree of operation. Activities and intervals, optional equipment 3HAC 16246-1 The table below specifies the required maintenance activities and intervals for common optional equipment. Maintenance of other external equipment for the robot is detailed in separate documentation. A 39 4 Maintenance schedules and intervals 4.0.2 Maintenance schedule, IRB 6600/6650 Maintenance Equipment activity 40 Interval Note Inspection UL-lamp Inspection Mechanical stop axes 1-3 12 mths Inspection Position switches, axes 1-3 12 mths Detailed in section "Inspection, ULlamp" A Mechanical stops in "Inspection, addition to the fixed mechanical stop, stops axes 1-3" "Inspection, position switches, axes 1-3" 3HAC 16246-1 4 Maintenance schedules and intervals 4.0.3 Expected component life, IRB 6600 4.0.3 Expected component life, IRB 6600 General The expected life of a component can vary greatly depending on how hard it is run Expected life Component Expected life Note Manipulator harness 2,000,000 cycles See note 1) Cabling for position switch and fan 2,000,000 cycles See note 1) Balancing device 2,000,000 cycles See note 2) Gearbox 40,000h See note 3) 1) The expected life can also be affected by assemblage of cabling other than standard options. The given life is based on a test cycle that for every axis starts from the calibration position to minimum angle to maximum angle and back to the calibration position. Deviations from this cycle will result in differences in expected life! 2) The given life for the balancing device is based on a test cycle that starts from the initial position and goes to maximum extension, and back. Deviations from this cycle will result in differences in expected life! 3) The robot is dimensioned for a life of 8 years (350,000 cycles per year) in a normal spot welding application. Depending on the actual application, the life of individual gearboxes may vary greatly from this specification. The SIS (Service Information System) integrated in the robot software, keeps track of the gearbox life in each individual case and will notify the user when a service is due. The SIS is described in "SIS, Service Information System". 3HAC 16246-1 A 41 4 Maintenance schedules and intervals 4.0.4 Maintenance schedule, controller S4CPlus M2000A 4.0.4 Maintenance schedule, controller S4CPlus M2000A General The robot controller must be maintained at regular intervals to ensure its function. The maintenance activities and their respective intervals are specified in the table below: Intervals Maintenance Equipment activity Interval Detailed in section Inspection Controller cabinet 6 mths "Inspection, controller cabinet" Cleaning Controller cabinet Replacement Battery unit 12 000 h/36 mths 1 "Replacement, battery unit" Replacement System fan unit 60 mths "Replacement, system fan unit". 1) 42 "Cleaning of controller cabinet" Hours denote operational time while months denote the actual calender time. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.0.1 Introduction Chapter 5: Maintenance activities, manipulator 5.0.1 Introduction General 3HAC 16246-1 This chapter contains information on how to maintain the equipment in question, i.e. how to perform the preventive maintenance activities specified in the maintenance schedule for the same equipment. A 43 5 Maintenance activities, manipulator 5.1.1 Inspection, oil level gearbox axis 1 Section 5.1: Inspection activities 5.1.1 Inspection, oil level gearbox axis 1 Location of gearbox The axis 1 gearbox is located between the frame and base as shown in the figure below. C D B A xx0200000228 A Gearbox axis 1 B Oil plug, inspection C Motor, axis 1 D Oil plug, filling Required equipment Equipment Spare part no. Art. no. Lubricating oil 3HAC 16843-1 Optimol Optigear RMO 150 Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. 44 Note These procedures include references to the tools required. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.1 Inspection, oil level gearbox axis 1 Inspection, oil level gearbox The procedure below details how to inspect the oil level in gearbox axis 1. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 3HAC 16246-1 Action Note/Illustration 1. Open the oil plug, inspection. Shown in the figure Location of gearbox on page 44! 2. Required oil level: max. 10 mm below the oil plug hole! 3. Add oil if required. Art. no. specified in Required equipment on page 44! Detailed in section Oil change, gearbox axis 1 on page 75. 4. Refit the oil plug, inspection. Tightening torque: 24 Nm. A 45 5 Maintenance activities, manipulator 5.1.2 Inspection, oil level gearbox axis 2 5.1.2 Inspection, oil level gearbox axis 2 Different designs Between the axis 2 motor and gearbox there is a motor attachment which exists in two different designs. • The early design of the motor attachment is attached directly to the gearbox, with the front gearbox attachment screws. • The later design of the motor attachment is attached directly to the frame. This design also includes an additional cover that overlaps the motor attachment and holds the oil plugs. The correct oil level varies, depending on the design of the motor attachment. Location of gearbox The gearbox, axis 2, is located in the lower arm rotational center, underneath the motor attachment. The figure below shows the later design of the motor attachment. A D B C xx0200000229 A Gearbox axis 2 (behind motor attachment and cover) B Oil plug, filling C Oil plug, draining D Vent hole, gearbox axis 2 Required equipment Equipment etc. Spare part no. Art. no. Lubricating oil 46 Note 3HAC 16843-1 Optimol Optigear RMO 150 A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.2 Inspection, oil level gearbox axis 2 Equipment etc. Spare part no. Art. no. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Inspection, oil level Note These procedures include references to the tools required. The procedure below details how to inspect the oil level in gearbox axis 2. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 3HAC 16246-1 Action Note/Illustration 1. Open the oil plug, filling. Shown in the figure Location of gearbox on page 46! 2. Measure the oil level at the oil plug, filling. Required oil level with the early design of the motor attachment: approx. 65 mm ±5 mm. Required oil level with the later design of the motor attachment: max. 10 mm below the oil plug hole. Shown in the figure Location of gearbox on page 46! Read more about the variations in design in Different designs on page 46. 3. Add oil if required. Art. no. specified in Required equipment on page 46! Detailed in section Oil change, gearbox axis 2 on page 78. 4. Refit the oil plug, filling. Tightening torque: 24 Nm. A 47 5 Maintenance activities, manipulator 5.1.3 Inspection, oil level gearbox axis 3 5.1.3 Inspection, oil level gearbox axis 3 Location of gearbox The axis 3 gearbox is located in the upper arm rotational center as shown in the figure below. A B C xx0200000230 A Gearbox axis 3 B Oil plug, filling C Oil plug, draining Required equipment Equipment, etc. Spare part no. Art. no. Lubricating oil 3HAC 16843-1 Optimol Optigear RMO 150 Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. 48 Note These procedures include references to the tools required. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.3 Inspection, oil level gearbox axis 3 Inspection, oil level gearbox 3 The procedure below details how to inspect the oil level in the gearbox axis 3. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 3HAC 16246-1 Action Note/Illustration 1. Run the manipulator to the calibration position. Detailed in "Calibration" in the Installation Manual. 2. Open the oil plug, filling. Shown in the figure Location of gearbox on page 48! 3. Required oil level: max 10 mm below the oil plug hole. 4. Add oil if required. Art. no. specified in Required equipment on page 48! Detailed in section Oil change, gearbox, axis 3 on page 81. 5. Refit the oil plug, filling. Tightening torque: 24 Nm. A 49 5 Maintenance activities, manipulator 5.1.4 Inspection, oil level gearbox axis 4 5.1.4 Inspection, oil level gearbox axis 4 Location of gearbox The axis 4 gearbox is located in the rearmost part of the upper arm as shown in the figure below. A B xx0200000231 A Oil plug, filling B Oil plug, draining Required equipment Equipment, etc. Spare part no. Art. no. Lubricating oil 1171 2016-604 BP Energol GR-XP 320 This is a common oil that can be replaced with an equivalent oil from another manufacturer! Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the stepby-step instructions below. Inspection, oil level gearbox 4 Note These procedures include references to the tools required. The procedure below details how to inspect the oil level in gearbox axis 4. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! 50 A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.4 Inspection, oil level gearbox axis 4 - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 3HAC 16246-1 Action Note/Illustration 1. Run the manipulator to the calibration position. Shown in "Calibration" in the Installation Manual! 2. Open the oil plug, filling. Shown in the figure Location of gearbox on page 50! 3. Required oil level: max 10 mm below the oil plug hole. 4. Add oil if required. Art. no. specified in Required equipment on page 50. Detailed in section Oil change, gearbox, axis 4 on page 83. 5. Refit the oil plug. Tightening torque: 24 Nm. A 51 5 Maintenance activities, manipulator 5.1.5 Inspection, oil level, gearbox axis 5 5.1.5 Inspection, oil level, gearbox axis 5 Location of gearbox The axis 5 gearbox is located in the wrist unit as shown in the figure below. A B xx0200000232 A Oil plug, filling B Oil plug, draining Required equipment Equipment etc. Spare part no. Art. no. Lubricating oil 1171 2016-604 BP Energol GR-XP 320 This is a common oil that can be replaced with an equivalent oil from another manufacturer! Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Inspection, oil level gearbox 5 Note These procedures include references to the tools required. The procedure below details how to inspect the oil level in gearbox axis 5. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. 52 A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.5 Inspection, oil level, gearbox axis 5 When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 3HAC 16246-1 Action Note/Illustration 1. Turn the wrist unit so that both oil plugs face upwards. 2. Open the oil plug, filling. 3. Measure the oil level. Required oil level: 30 mm to the oil plug hole. 4. Add oil if required. Art. no. specified in Required equipment on page 52. Detailed in section Oil change, gearbox, axis 5 on page 85. 5. Refit the oil plug. Tightening torque: 24 Nm. A Shown in the figure Location of gearbox on page 52! 53 5 Maintenance activities, manipulator 5.1.6 Inspection, oil level gearbox axis 6 5.1.6 Inspection, oil level gearbox axis 6 Location of gearbox The axis 6 gearbox is located in the center of the wrist unit as shown in the figure below. B A C xx0200000233 A Gearbox axis 6 B Oil plug, filling C Oil plug, draining Required equipment Equipment Spare part no. Art. no. Lubricating oil 3HAC 16843-1 Optimol Optigear RMO 150. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Inspection, oil level gearbox 6 Note These procedures include references to the tools required. The procedure below details how to inspect the oil level in gearbox axis 6. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When changing gearbox oil, first run the robot for a time to heat up the oil. Warm oil drains quicker than cold oil. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! 54 A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.6 Inspection, oil level gearbox axis 6 When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 3HAC 16246-1 Action Note/Illustration 1. Make sure the oil plug, filling is facing upwards and open it. Shown in the figure Location of gearbox on page 54! 2. Measure the oil level. Required oil level: 55 mm ±5 mm to oil plug hole, filling. 3. Add oil if required. Art. no. specified in Required equipment on page 54! Detailed in section Oil change, gearbox axis 6 on page 87. 4. Refit the oil plug, filling. Tightening torque: 24 Nm. A 55 5 Maintenance activities, manipulator 5.1.7 Inspection, balancing device 5.1.7 Inspection, balancing device Location of balancing device The balancing device is located at the top rear of the frame as shown in the figure below. If damage is detected during inspection, a maintenance or an upgrade must be performed, depending on version of balancing device! Balancing device 3HAC 14678-1 and 3HAC 16189-1 requires maintenance, while 3HAC 12604-1 requires an upgrade. D C A, B E F xx0200000110 A Balancing device B Piston rod (inside the cylinder) C Shaft, including securing screw D Ear with spherical roller bearing inside E Bearing attachment F Rear cover Required equipment -general 56 Equipment, etc. Spare part no. Art. no. Note Balancing device 3HAC 16198-1 IRB 6600. Includes balancing device 3HAC 14678-1! A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.7 Inspection, balancing device Equipment, etc. Spare part no. Art. no. Note Balancing device 3HAC 16907-1 IRB 6650. Includes balancing device 3HAC 16189-1! Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. These procedures include references to the tools required. Depending on whether maintenance or upgrade is to be performed, use also equipment as specified below! Required equipment -maintenance Required equipment -upgrade If detecting damage when inspecting balancing device, version 3HAC 14678-1, 3HAC 16189-1 maintenance must be performed! The table below specifies the equipment required when maintaining the balancing device! Equipment, etc. Spare part no. Art. no. Note Maintenance kit 3HAC 16195-1 Includes complete kit 3HAC 16192-1 and instructions for maintenance, 3HAC 15864-5. Maintenance kit 3HAC 16194-1 Includes kit with bearings and seals only, 3HAC 16190-1, plus instructions for maintenance, 3HAC 15864-4. Documentation for maintenance 3HAC 15864-5 3HAC 15864-4 See difference above! Toolkit for maintenance 3HAC 15943-2 Puller for separator 4552-2 (Bahco) Used for dismounting the spherical roller bearings. Separator 4551-C (Bahco) Used for dismounting the spherical roller bearings. If detecting damage when inspecting balancing device, version 3HAC 12604-1, an upgrade must be performed! The table below specifies equipment required when upgrading the balancing device! Equipment, etc. Spare part no. Art. no. 3HAC 16246-1 Note Upgrade kit 3HAC 16196-1 Includes kit with piston rod, support shaft etc., 3HAC 16193-1, plus instruction for conversion, 3HAC 15864-6. Documentation in upgrade kit 3HAC 15864-6 Instruction for conversion from balancing device, 3HAC 12604-1 to 3HAC 14678-1. A 57 5 Maintenance activities, manipulator 5.1.7 Inspection, balancing device Inspection, balancing device The procedure below details how to inspect the balancing device. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Do not under any circumstances, deal with the balancing device in any other way than that detailed in the product documentation! For example, attempting to open the balancing device is potentially lethal! Step 58 Action Note 1. Check for dissonance from bearings, gear or Shown in the figure Location of balshaft. ancing device on page 56. Make sure the securing screw in the shaft is positioned correctly and undamaged. (M16x180, tightening torque: 50 Nm.) At detected dissonance: Carry out an overhaul as detailed in Maintenance kit or Upgrade kit, depending on the version of balancing device. 2. Check for dissonance from the cylinder. Replacing balancing device is The springs inside the cylinder can cause a detailed in "Remove/Refit balancing tapping sound. Replace the balancing device device" in the Repair Manual. or consult ABB Robotics. 3. Check for dissonance from the piston rod. Squeaking can indicate worn plain bearings, internal contamination or insufficient lubrication. At detected dissonance: Carry out an overhaul as detailed in Maintenance kit or Upgrade kit, depending on the version of balancing device. 4. Check if the piston rod is scratched, worn or has an uneven surface. At detected damage: Carry out an overhaul as detailed in Maintenance kit or Upgrade kit, depending on the version of balancing device. 5. If any damage or dissonance is detected, fol- Art. no. specified in Required equiplow the notes above! ment -maintenance on page 57/ Required equipment -upgrade on Carry out the overhaul as detailed in the enclosed instruction in the Maintenance kit or page 57! upgrade as detailed in the instruction in the Upgrade kit. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.8 Inspection, cable harness 5.1.8 Inspection, cable harness Location of cabling axes 1-4 The manipulator cable harness, axes 1-4, is located as shown in the figure below. C A B D xx0200000097 A Lower arm B Cables attached with velcro straps and mounting plate C Connectors at cable harness division point, R2.M5/6 D Connectors at base Required equipment 3HAC 16246-1 Equipment, etc. Spare part no. Art. no. Note Harness manipulator 1-4 3HAC 14940-1 IRB 6600 Harness manipulator 1-4 3HAC 16331-1 IRB 6650 Cable harness ax. 5-6 3HAC 14140-1 Cable harness axis 5 3HAC 14139-1 Circuit diagram 3HAC 13347-1 Included in the Repair Manual, part 2. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! A 59 5 Maintenance activities, manipulator 5.1.8 Inspection, cable harness Equipment, etc. Spare part no. Art. no. Other tools and procedures may be required. See references to these procedures in the step-bystep instructions below. Inspection, cable harness 1-4 Note These procedures include references to the tools required. The procedure below details how to inspect the cable harness of axes 1-4. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The cable harnesses are sensitive to mechanical damage! They must be handled with care, especially the connectors, in order to avoid damaging them! Step 60 Action Note/Illustration 1. Make an overall visual inspection of the cable harness, in order to detect wear and damage. 2. Check the connectors at the division point and at the base. Shown in the figure Location of cabling axes 1-4 on page 59! 3. Check that velcro straps and the mounting plate are properly attached to the frame. Also check the cabling, leading into the lower arm. Make sure it is attached by the straps and not damaged. Location shown in the figure Location of cabling axes 1-4 on page 59! A certain wear of the hose at the entrance to the lower arm is natural. 4. Replace the cable harness if wear or damage is detected. Art. no. specified in Required equipment on page 59! Removal and refitting of cable harness is detailed in the Repair Manual! A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.8 Inspection, cable harness Location of cabling axes 5-6 The manipulator cable harness, axes 5-6, is located as shown in the figure below. B A C xx0200000234 Inspection, cable harness, axes 5-6 A Connectors at cable harness division point, R2.M5/6 B Cable attachment, rear of upper arm C Cable attachment, upper arm tube The procedure below details how to inspect the cable harness of axes 5-6. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. The cable harnesses are sensitive to mechanical damage! They must be handled with care, especially the connectors, in order to avoid damaging them! Step 1. 3HAC 16246-1 Action Note Make an overall visual inspection of the cable harness, in order to detect wear and damage. A 61 5 Maintenance activities, manipulator 5.1.8 Inspection, cable harness Step 62 Action Note 2. Check the attachments at the rear of the upper arm and Shown in the figure Locain the upper arm tube. tion of cabling axes 5-6 on page 61! Check the connectors at the cable harness division. Make sure the attachment plate is not bent or in other way damaged. 3. Replace the cable harness if wear or damage is detected. A Art. no. specified in Required equipment on page 59! Removal and refitting of cable harness is detailed in the Repair Manual! 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.9 Inspection, information labels 5.1.9 Inspection, information labels Location of labels The figures below show the location of the information labels to be inspected. A B Warning B A A D X X B Warning C B A B X-X xx0200000236 3HAC 16246-1 A Warning label "High temperature", 3HAC 4431-1 B Warning sign, a symbol of a lightning flash (located on motor cover), 3HAC 1589-1 C Instruction label "Safety instructions", 3HAC 4591-1 D Warning label "Brake release", 3HAC 15334-1 A 63 5 Maintenance activities, manipulator 5.1.9 Inspection, information labels E G Liftin g of robot H Warning Warning F xx0200000101 E Instruction label "Lifting the robot", 3HAC 16420-1 F Warning label "Robot can tip forward...", 3HAC 9191-1 G Foundry logotype, 3HAC 8256-1 H Warning label "Stored energy", 3HAC 9526-1 Required equipment Equipment, etc. Spare part no. Art. no. Labels and plate set Note 3HAC 8711-1 Inspection, labels Step 64 Action Note/Illustration 1. Check the labels, located as shown in the figures Location of labels on page 63. 2. Replace any missing or damaged labels. A Art. no. specified in Required equipment on page 64! 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.10 Inspection, mechanical stop, axis 1 5.1.10 Inspection, mechanical stop, axis 1 Location of mechanical stop The mechanical stop axis 1 is located at the base as shown in the figure below. A xx0200000151 A Mechanical stop (stop pin) Required equipment Equipment, etc. Inspection, mechanical stop Spare part no. Art. no. Note Mechanical stop ax 1 3HAC 12812-2 To be replaced when damaged. Includes spring pin. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! The procedure below details how to inspect the mechanical stop axis 1. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Step 3HAC 16246-1 Action Note/Illustration 1. Inspect the mechanical stop, axis 1. Shown in the figure Location of mechanical stop on page 65! 2. Make sure the mechanical stop can move in both directions. 3. If the stop pin is bent or damaged, it must be replaced! A Art. no. specified in Required equipment on page 65! 65 5 Maintenance activities, manipulator 5.1.11 Inspection, mechanical stop, axes 1, 2 and 3 5.1.11 Inspection, mechanical stop, axes 1, 2 and 3 Location of mechanical stops The figure below shows the location of the additional mechanical stops on axes 1, 2 and 3 (IRB 7600 shown). A B A B B A xx0200000150 A Additional stop B Fixed stop Required equipment Equipment etc. 66 Spare part no. Art. no. Note Mechanical stop ax 1 3HAC 11076-1 Limits the robot working range by 7,5°. Mechanical stop ax 1 3HAC 11076-2 Limits the robot working range by 15°. Mechanical stop ax 2 3HAC 13787-1 Mechanical stop ax 3 3HAC 13128-2 Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit! A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.11 Inspection, mechanical stop, axes 1, 2 and 3 Inspection, mechanical stops The procedure below details how to inspect the additional mechanical stops on axes 1, 2 and 3. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Step 3HAC 16246-1 Action Note/Illustration 1. Check the additional stops on axes 1, 2 and 3 for Shown in the figure Location of damage. mechanical stops on page 66! 2. Make sure the stops are properly attached. Correct tightening torque: 115 Nm. 3. If any damage is detected, the mechanical stops Art. no. specified in Required must be replaced! equipment on page 66! Correct attachment screws (lubricated with Molycote 1000): • Axis 1: M16 x 35 • Axis 2: M16 x 50 • Axis 3: M16 x 60 A 67 5 Maintenance activities, manipulator 5.1.12 Inspection, damper axes 2-5 5.1.12 Inspection, damper axes 2-5 Location of dampers The figure below shows the location of all the dampers to be inspected. D C B A xx0300000040 A Damper, axis 2 (2 pcs) B Damper, axis 3 (2 pcs) C Damper, axis 4 (1 pc) D Damper, axis 5 (2 pcs) Required equipment Equipment 68 Spare part no. Art. no. Note Damper axis 2 3HAC 12991-1 To be replaced if damaged! Damper axis 3 3HAC 12320-1 To be replaced if damaged! Damper axis 4 3HAC 13564-1 To be replaced if damaged! Damper axis 5 3HAB 4337-2 To be replaced if damaged! Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.12 Inspection, damper axes 2-5 Inspection, dampers The procedure below details how to inspect the dampers, axes 2-5 Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Step 3HAC 16246-1 Action Note/Illustration 1. Check all dampers for damage, and for cracks or Shown in the figure Location of existing impressions larger than 1 mm. dampers on page 68! To inspect the damper, axis 4, remove the two covers on top of the upper arm! 2. Check attachment screws for deformation. 3. If any damage is detected, the damper must be replaced with a new one! A Art. no. specified in Required equipment on page 68! 69 5 Maintenance activities, manipulator 5.1.13 Inspection, position switch axes 1, 2 and 3 5.1.13 Inspection, position switch axes 1, 2 and 3 Location of position switches The illustration below shows the position switch for axis 1. A F C D B E xx0100000158 A Position switch, axis 1 B Cam C Set screw, cam D Protection sheet E Rail F Rail attachment The illustration below shows the position switch for axis 2. E B A C F xx0100000159 70 A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.13 Inspection, position switch axes 1, 2 and 3 A Position switch, axis 2 B Cam C Set screw, cam E Rail F Rail attachment The illustration below shows the position switch for axis 3. F E C B A xx0100000160 A Position switch, axis 3 B Cam C Set screw, cam E Rail F Rail attachment Required equipment Equipment, etc. 3HAC 16246-1 Spare part no. Art. no. Note Position switch, axis 1 3HAC 15715-1 To be replaced in case of detected damage Position switch, axis 2 3HAC 16418-1 To be replaced in case of detected damage Position switch, axis 3 3HAC 16417-1 To be replaced in case of detected damage A 71 5 Maintenance activities, manipulator 5.1.13 Inspection, position switch axes 1, 2 and 3 Equipment, etc. Spare part no. Art. no. Standard toolkit 3HAC 15571-1 Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Inspection, position switches Note The contents are defined in section Standard toolkit on page 18! These procedures include references to the tools required. The procedure below details how to inspect the position switch, axes 1, 2 and 3. See figure above to locate the different components to be inspected. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Step Action 1. Check the position switch! • Check that the rollers are easy to push in and that they roll freely. 2. Check the rail! • Check that the rail is firmly attached with the attachment screws. 3. Check the cams! • Check that the rollers has not caused any impressions on the cams. 4. • Check that the cams are clean. Wipe them if necessary! • Check that the set screws holding the cams in position are firmly attached. Check the protection sheets on axis 1! • Check that the three sheets are in position and not damaged. Deformation can result in rubbing against the cams! • 5. 72 Note/Illustration Check that the area inside of the sheets is clean enough not to interfere the function of the position switch. If any damage is detected, the position switch must Art. no. specified in Required be replaced! equipment on page 71! A 3HAC 16246-1 5 Maintenance activities, manipulator 5.1.14 Inspection, UL signal lamp 5.1.14 Inspection, UL signal lamp Location of UL lamp The UL-lamp is located as shown in the figure below. Note that the position can differ depending on how the customer harness for axis 4-6 is mounted. See assembly drawing on the current harness for alternative positioning. There are two different article numbers for the UL-lamp. The difference is due to the accompanying motor cover, which is either flat or vaulted. E A D C B xx0200000240 A UL signal lamp B Clamp C Position for cable gland D Warning label on motor cover E Warning sign on motor cover Required equipment Equipment, etc. 3HAC 16246-1 Spare part no. Art. no. Note Signal lamp 3HAC 10830-1 To be replaced in case of detected damage. (Includes vaulted motor cover.) Signal lamp 3HAC 13097-1 To be replaced in case of detected damage. (Includes flat motor cover.) Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! A 73 5 Maintenance activities, manipulator 5.1.14 Inspection, UL signal lamp Equipment, etc. Spare part no. Art. no. Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Inspection, ULlamp Note These procedures include references to the tools required. The procedure below details how to inspect the function of the UL-lamp. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Step 74 Action Note/Illustration 1. Check that the UL-lamp is lit, when the motors are put in operation ("motors ON"). 2. If the lamp is not lit, trace the fault by: • Checking whether the ul-lamp is broken. If so, replace it. • Checking the cable connections. • Measuring the voltage in connectors motor axis 3 (=24V). • Checking the cabling. Replace cabling if a fault is detected. A Art. no. specified in Required equipment on page 73! 3HAC 16246-1 5 Maintenance activities, manipulator 5.2.1 Oil change, gearbox axis 1 Section 5.2: Changing activities 5.2.1 Oil change, gearbox axis 1 Location of gearbox The axis 1 gearbox is located between the frame and base as shown in the figure below. C D B A xx0200000228 A Gearbox axis 1 B Oil plug, inspection C Motor axis 1 D Oil plug, filling Required equipment Equipment, etc. Spare part no. Art. no. Lubricating oil Note 3HAC 16843-1 Optimol Optigear RMO 150. Total amount: 7,300 ml. Oil collecting vessel Capacity: 8,000 ml. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! The specified amount of oil is based on the total volume of the gearbox. When changing the oil, the amount of refilled oil may therefor differ from the specified amount, depending on how much oil has previously been drained from the gearbox. The correct oil level is specified in the section about inspection of oil level. 3HAC 16246-1 A 75 5 Maintenance activities, manipulator 5.2.1 Oil change, gearbox axis 1 Changing, oil The procedure below details how to change the oil in gearbox axis 1. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When changing gearbox oil, first run the robot for a time to heat up the oil. Warm oil drains quicker than cold oil. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step Action Note/Illustration 1. Remove the rear cover on the base by unscrewing its attachment screws. 2. Pull the oil draining hose out of the rear of the base. A xx0200000237 The hose is located beneath the base, as shown in the figure with a view from below. • A: Oil draining hose 76 3. Place an oil vessel close to the hose end. Vessel capacity specified in Required equipment on page 75! 4. Remove the oil plug, filling, in order to drain the oil quicker! 5. Open the hose end and drain the oil into the vessel. 6. Close the oil drain hose, and put it back inside the base. A Notice! The draining is time-consuming. Elapsed time depends on the temperature of the oil. 3HAC 16246-1 5 Maintenance activities, manipulator 5.2.1 Oil change, gearbox axis 1 Step 3HAC 16246-1 Action Note/Illustration 7. Close the rear cover by securing it with its attachment screws. 8. Open the oil plug, filling. 9. Refill the gearbox with lubricating oil. Art. no. and the total amount are speciThe amount of oil to be refilled depends on fied in Required equipment on page 75! the amount previously being drained. The correct oil level is detailed in section Inspection, oil level gearbox axis 1 on page 44. 10. Refit the oil plug, filling. A Shown in the figure Location of gearbox on page 75! Tightening torque: 24 Nm. 77 5 Maintenance activities, manipulator 5.2.2 Oil change, gearbox axis 2 5.2.2 Oil change, gearbox axis 2 Different designs Between the axis 2 motor and gearbox there is a motor attachment which exists in two different designs. • The early design of the motor attachment is attached directly to the gearbox, with the front gearbox attachment screws (only some versions of IRB 6600). • The later design of the motor attachment is attached directly to the frame. This design also includes an additional cover that overlaps the motor attachment and holds the oil plugs. The correct amount oil varies, depending on the design of the motor attachment. Location of gearbox The gearbox, axis 2, is located in the lower arm rotational center, underneath the motor attachment. The figure below shows the later design of the motor attachment. A D B C xx0200000229 78 A Gearbox axis 2 B Oil plug, filling C Oil plug, draining D Vent hole, gearbox axis 2 A 3HAC 16246-1 5 Maintenance activities, manipulator 5.2.2 Oil change, gearbox axis 2 Required equipment Equipment, etc. Spare part no. Art. no. Lubricating oil Note 3HAC 16843-1 Optimol Optigear RMO 150. Total amount with early design of motor attachment: 1,800 ml. Total amount with later design of motor attachment: 4,300 ml. Oil collecting vessel Capacity: 5,000 ml. Hose with nipple 1/2". Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! The specified amount of oil is based on the total volume of the gearbox. When changing the oil, the amount of refilled oil may therefor differ from the specified amount, depending on how much oil has previously been drained from the gearbox. The correct oil level is specified in the section about inspection of oil level. Changing, oil The procedure below details how to change the oil in gearbox axis 2. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When changing gearbox oil, first run the robot for a time to heat up the oil. Warm oil drains quicker than cold oil. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 1. 3HAC 16246-1 Action Note/Illustration Remove the plug of the vent hole (later design). Shown in the figure Location of gearbox on page 78! A 79 5 Maintenance activities, manipulator 5.2.2 Oil change, gearbox axis 2 Step 80 Action Note/Illustration 2. Remove the oil plug, draining, and drain the gearbox oil using a hose with nipple and an oil collecting vessel. Shown in the figure Location of gearbox on page 78! Vessel capacity specified above! Draining is time-consuming. Elapsed time varies depending on the temperature of the oil. 3. Refit the oil plug. Tightening torque: 24 Nm. 4. Remove the oil plug, filling. Shown in the figure Location of gearbox on page 78! 5. Refill the gearbox with lubricating oil. The amount of oil to be refilled depends on the amount previously being drained. The correct oil level is detailed in section Inspection, oil level gearbox axis 2 on page 46. Art. no. and total amount specified in Required equipment on page 79! 6. Refit the oil plug and the plug in the vent hole. Tightening torque: 24 Nm. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.2.3 Oil change, gearbox, axis 3 5.2.3 Oil change, gearbox, axis 3 Location of gearbox The axis 3 gearbox is located in the upper arm rotational center as shown in the figure below. A B C xx0200000230 A Gearbox axis 3 B Oil plug, filling C Oil plug, draining Required equipment Equipment, etc. Spare part no. Art. no. Lubricating oil Note 3HAC 16843-1 Optimol Optigear RMO 150. Total amount: 2,500 ml. Oil collecting vessel Capacity: 3,000 ml. Hose with nipple 1/2". Standard toolkit The contents are defined in section Standard toolkit on page 18! The specified amount of oil is based on the total volume of the gearbox. When changing the oil, the amount of refilled oil may therefor differ from the specified amount, depending on how much oil has previously been drained from the gearbox. The correct oil level is specified in the section about inspection of oil level. 3HAC 16246-1 A 81 5 Maintenance activities, manipulator 5.2.3 Oil change, gearbox, axis 3 Changing, oil The procedure below details how to change the oil in gearbox, axis 3. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When changing gearbox oil, first run the robot for a time to heat up the oil. Warm oil drains quicker than cold oil. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 82 Action Note/Illustration 1. Remove the oil plug, draining, and drain the gearbox oil using a hose with nipple and an oil collecting vessel. Remove the oil plug, filling in order to drain the oil quicker! Shown in the figure Location of gearbox on page 81! Vessel capacity specified in Required equipment on page 81! Draining is time-consuming. Elapsed time varies depending on the temperature of the oil. 2. Refit the oil plug. Tightening torque: 24 Nm. 3. Remove the oil plug, filling. Shown in the figure Location of gearbox on page 81! 4. Refill the gearbox with lubricating oil. Art. no. and total amount specified in The amount of oil to be refilled depends on Required equipment on page 81! the amount previously being drained. The correct oil level is detailed in section Inspection, oil level gearbox axis 3 on page 48. 5. Refit the oil plug. Tightening torque: 24 Nm. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.2.4 Oil change, gearbox, axis 4 5.2.4 Oil change, gearbox, axis 4 Location of gearbox The axis 4 gearbox is located in the rearmost part of the upper arm as shown in the figure below. A B xx0200000231 A Oil plug, filling B Oil plug, draining Required equipment Equipment, etc. Spare part no. Art. no. Lubricating oil 1171 2016-604 Oil collecting vessel Note BP Energol GR-XP 320. This is a common oil that can be replaced with an equivalent oil from another manufacturer! Total amount: 8,100 ml. Capacity: 9,000 ml. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! The specified amount of oil is based on the total volume of the gearbox. When changing the oil, the amount of refilled oil may therefor differ from the specified amount, depending on how much oil has previously been drained from the gearbox. The correct oil level is specified in the section about inspection of oil level. 3HAC 16246-1 A 83 5 Maintenance activities, manipulator 5.2.4 Oil change, gearbox, axis 4 Changing, oil The procedure below details how to change the oil in gearbox, axis 4. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When changing gearbox oil, first run the robot for a time to heat up the oil. Warm oil drains quicker than cold oil. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 84 Action Note/Illustration 1. Run the upper arm -45°from the calibration position. 2. Open the oil plug, draining. Shown in the figure Location of gearRemove the oil plug, filling in order to drain box on page 83! the oil quicker! 3. Drain the oil from the gearbox. Vessel capacity specified in Required equipment on page 83! 4. Run the upper arm back to its calibration position (horizontal position). Detailed in "Calibration" in the Installation Manual. 5. Refit the oil plug, draining. Tightening torque: 24 Nm. 6. Refill the gearbox with lubricating oil through the oil plug, filling. The amount of oil to be refilled depends on the amount previously being drained. The correct oil level is detailed in section Inspection, oil level gearbox axis 4 on page 50. Shown in the figure Location of gearbox on page 83! Art. no. and total amount specified in Required equipment on page 83. 7. Refit the oil plug, filling. Tightening torque: 24 Nm. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.2.5 Oil change, gearbox, axis 5 5.2.5 Oil change, gearbox, axis 5 Location of gearbox The axis 5 gearbox is located in the wrist unit as shown in the figure below. A B xx0200000232 A Oil plug, filling B Oil plug, draining Required equipment Equipment, etc. Spare part no. Art. no. Lubricating oil Note 1171 2016-604 BP Energol GR-XP 320. This is a common oil that can be replaced with an equivalent oil from another manufacturer! Total amount: 6,700 ml. Oil collecting vessel Capacity: 7,000 ml. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! The specified amount of oil is based on the total volume of the gearbox. When changing the oil, the amount of refilled oil may therefor differ from the specified amount, depending on how much oil has previously been drained from the gearbox. The correct oil level is specified in the section about inspection of oil level. Changing, oil The procedure below details how to change the oil in gearbox, axis 5. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. 3HAC 16246-1 A 85 5 Maintenance activities, manipulator 5.2.5 Oil change, gearbox, axis 5 When changing gearbox oil, first run the robot for a time to heat up the oil. Warm oil drains quicker than cold oil. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 86 Action Note/Illustration 1. Run axis 4 to a position where the oil plug, draining, is facing downwards. 2. Open the oil plug, draining. Shown in the figure Location of gearRemove the oil plug, filling in order to drain box on page 85! the oil quicker! 3. Drain the oil from the gearbox. Vessel capacity specified in Required equipment on page 85! 4. Refit the oil plug, draining. Tightening torque: 24 Nm. 5. Run axis 4 back to the calibration position. 6. Refill the gearbox with lubricating oil through the oil plug, filling. The amount of oil to be refilled depends on the amount previously being drained. The correct oil level is detailed in section Inspection, oil level, gearbox axis 5 on page 52. Shown in the figure Location of gearbox on page 85! Art. no. and total amount specified in Required equipment on page 85. 7. Refit the oil plug, filling. Tightening torque: 24 Nm. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.2.6 Oil change, gearbox axis 6 5.2.6 Oil change, gearbox axis 6 Location of gearbox The axis 6 gearbox is located in the center of the wrist unit as shown in the figure below. The different robot versions have different gearbox designs. The amount of oil in the gearbox therefore varies depending on robot version. B A C xx0200000233 A Gearbox axis 6 B Oil plug, filling C Oil plug, draining Required equipment Equipment, etc. Spare part no. Art. no. Lubricating oil Note 3HAC 16843-1 Optimal Optigear RMO 150. Total amount for robot v. 175/2.25: 300 ml. Total amount for robot v. 225/2.55, 175/2.8, 125/3.2 and 200/2.75: 450 ml. Oil collecting vessel Vessel capacity: 500 ml. Standard toolkit 3HAC 15571-1 The contents are defined in section Standard toolkit on page 18! The specified amount of oil is based on the total volume of the gearbox. When changing the oil, the amount of refilled oil may therefor differ from the specified amount, depending on how much oil has previously been drained from the gearbox. The correct oil level is specified in the section about inspection of oil level. 3HAC 16246-1 A 87 5 Maintenance activities, manipulator 5.2.6 Oil change, gearbox axis 6 Changing, oil The procedure below details how to change oil in gearbox, axis 6. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. When changing gearbox oil, first run the robot for a time to heat up the oil. Warm oil drains quicker than cold oil. When filling gearbox oil, do not mix different types of oil unless specified in the instruction. Always use the type of oil specified by the manufacturer! When filling gearbox oil, do not overfill, since this could lead to internal over-pressure inside the gearbox which in turn may: - damage seals and gaskets - completely press out seals and gaskets - prevent the manipulator from moving freely Changing and draining gearbox oil may require handling hot oil of up to 90 °C! Make sure that protective gear like goggles and gloves are always worn during this work. Also be aware of possible over-pressure in gearbox! When opening the oil plug, there may be pressure resident in the gearbox, causing oil spray from the opening! Step 88 Action Note/Illustration 1. Run the robot to a position where the oil plug, draining of axis 6 gearbox is facing downwards. Shown in the figure Location of gearbox on page 87! 2. Drain the oil from gearbox 6 by removing the oil Vessel capacity specified in plug. Collect the oil with a suitable vessel. Required equipment on page 87! 3. Refit the oil plug, draining. Tightening torque: 24 Nm. 4. Remove the oil plug, filling. Shown in the figure Location of gearbox on page 87! 5. Refill the gearbox with lubricating oil. Art. no. and the total amount are The amount of oil to be refilled depends on the specified in Required equipment amount previously being drained. The correct on page 87! oil level is detailed in section Inspection, oil level gearbox axis 6 on page 54. 6. Refit the oil plug. Tightening torque: 24 Nm. A 3HAC 16246-1 5 Maintenance activities, manipulator 5.3.1 Lubrication, balancing device bearing Section 5.3: Lubrication activities 5.3.1 Lubrication, balancing device bearing Location of bearing The figure below shows the location of the lubrication nipple etc. Note! The balancing device must be mounted on the manipulator when lubricating the bearing! A B C D xx0200000109 A Ear (spherical roller bearing located inside) B Lubrication nipple C Sealing spacer D Hole through which the shaft is pressed Required equipment Equipment, etc. Spare part no. Art. no. Note Grease Optimol PDO, max. 80 ml. For lubrication of the spherical roller bearing. 3HAA 1001-294 Grease pump 3HAC 16246-1 A 89 5 Maintenance activities, manipulator 5.3.1 Lubrication, balancing device bearing Lubrication, balancing device bearing The procedure below details how to lubricate the spherical roller bearing. Please observe the following before commencing any repair work on the manipulator: - Motors and gears are HOT after running the robot! Burns may result from touching the motors or gears! - Turn off all electric power, hydraulic and pneumatic pressure supplies to the robot! - Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. to secure the lower arm with fixtures if removing motor, axis 2. Do not under any circumstances, deal with the balancing device in any other way than that detailed in the product documentation! For example, attempting to open the balancing device is potentially lethal! Step 1. 90 Action Note/Illustration Lubricate the spherical roller bearing through the lubrication nipple in the ear, with grease. Fill until excessive grease exudes out between the shaft and the sealing spacer. Art. no. specified in Required equipment on page 89! Shown in the figure Location of bearing on page 89! The balancing device must be mounted on the manipulator! A 3HAC 16246-1 5 Maintenance activities, manipulator 5.4.1 Cleaning, manipulator Section 5.4: Cleaning activities 5.4.1 Cleaning, manipulator General The protection class is IP 67, i.e. the manipulator is watertight. Activities This instruction specifies how to clean the manipulator. Periodicity The periodicity of cleaning the manipulator varies a great deal depending on the actual environment and function of the robot. Clean a contamined manipulator as required. Special points Special points to be observed are shown in the figure below: C B A D E xx0200000239 3HAC 16246-1 A Spiral cables to motor 6 B Inside of upper arm tube C Rear of upper arm tube D Inside of lower arm E Inside of base/axis 1 A 91 5 Maintenance activities, manipulator 5.4.1 Cleaning, manipulator Required equipment Equipment, etc. Steam cleaner High pressure water cleaner Do’s and don’ts! Always! Never! Foundry versions 92 Note • Water pressure at nozzle: max. 2,500 kN/m 2 (25 bar) • Type of nozzle: fan jet, min. 45°spread • Flow: max. 100 litres/min. • Water temperature: max. 80°C • Max. water pressure on enclosures: 50 kN/m 2 (0.5 bar) • Fan jet nozzle should be used, min. 45°spread • Flow: max. 100 litres/min. The section below specifies some special considerations when cleaning the manipulator. • Always use cleaning equipment as specified above! Any other cleaning equipment may shorten the life of paintwork, rust inhibitors, signs, or labels! • Always check that all protective covers are fitted to the robot before cleaning! • Never point the water jet at bearing seals, contacts, and other seals! • Never spray from a distance closer than 0.4 m! • Never remove any covers or other protective devices before cleaning the robot! • Never use any cleaning agents, e.g. compressed air or solvents, other than those specified above! • Never spray with a high pressure cleaner onto the sealing cup at the bottom of the motor 6 spiral cable (item A in the figure Special points on page 91)! • Although the manipulator is watertight, avoid spraying connectors and similar items with a high pressure cleaner! In working environments, e.g. foundries, where the manipulator may be exposed to fluids that dry to make a crusty surface, e.g. release agents, clean the cable harnesses to prevent the crust damaging the cables: • Clean the spiral wound cables to motor 6 (item A in the figure Special points on page 91) with water and a cloth! • Clean the remaining sections of the cable harnesses as detailed above! A 3HAC 16246-1 6 Maintenance activities, controller cabinet 6.0.1 Introduction Chapter 6: Maintenance activities, controller cabinet 6.0.1 Introduction General 3HAC 16246-1 This chapter contains information on how to maintain the equipment in question, i.e. how to perform the preventive maintenance activities specified in the maintenance schedule for the same equipment. A 93 6 Maintenance activities, controller cabinet 6.1.1 Inspection of controller cabinet, S4Cplus M2000A Section 6.1: Inspection activities 6.1.1 Inspection of controller cabinet, S4Cplus M2000A Inspection The procedure below details how to inspect the controller cabinet. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action 94 Note/Illustration 1. Inspect the cabinet interior to make sure there is no Replace any faulty seals as contamination. required. If any contamination is found, the cabinet interior must be cleaned and all gaskets and seals to the cabinet inspected. 2. Inspect all sealing joints and cable glands to make sure they are airtight in order to prevent dust and dirt from being sucked into the cabinet. 3. Inspect connectors and cabling to make sure they are securely fastened and cabling not damaged. 4. Inspect any fans to make sure they function correctly. A Replace any malfunctioning fans as detailed in the Repairs manual. 3HAC 16246-1 6 Maintenance activities, controller cabinet 6.2.1 Replacement of battery unit, controller Section 6.2: Replacement activities 6.2.1 Replacement of battery unit, controller Location of battery unit The battery unit is located at the bottom of the controller. X1 X1 X1 X1 X2 X2 X2 X2 X1 X2 X3 Rectifier A0 A xx0200000103 A Battery unit Required equipment Equipment, etc. Spare part no. Art no. Note Battery unit 3HAC 5393-2 To be replaced as a complete unit Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal, battery unit These procedures include references to the tools required. The procedure below details how to remove the battery unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. 3HAC 16246-1 A 95 6 Maintenance activities, controller cabinet 6.2.1 Replacement of battery unit, controller Step Action Note/Illustration 1. Remove the battery unit by unscrewing its attachment screws (1). X1 X1 X1 X1 X2 X2 X2 X2 X1 X2 X3 Rectifier A0 xx0200000004 2. Pull the battery unit out. 3. Disconnect the three cables from the battery unit. xx0200000005 Refitting, battery unit The procedure below details how to refit the battery unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Place the battery unit close to its position. Art. no. is specified above! See illustration above! 2. Reconnect the cables and push the unit into position. See illustration above! 3. Secure it with the attachment screws. 96 A See illustration above! 3HAC 16246-1 6 Maintenance activities, controller cabinet 6.3.1 Cleaning of controller cabinet Section 6.3: Cleaning activities 6.3.1 Cleaning of controller cabinet Required equipment Equipment, etc. Internal cleaning Art. no. Note Vacuum cleaner ESD Safe Cleaning agent, exterior cleaning Use rag with alcohol, for example, if necessary The procedure below details how to clean the interior of the controller cabinet. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step 1. Do’s and don’ts! Always! Never! 3HAC 16246-1 Action Note/Illustration Clean the cabinet interior with a vacuum cleaner if necessary. The section below specifies special considerations when cleaning the controller cabinet. • Always use cleaning equipment as specified above! Any other cleaning equipment may shorten the life of paintwork, rust inhibitors, signs, or labels! • Always check that all protective covers are fitted to the controller before cleaning! • Never remove any covers or other protective devices before cleaning the controller! • Never use any cleaning agents, e.g. compressed air or solvents, other than those specified above! • Never spray with a high pressure water cleaner! A 97 6 Maintenance activities, controller cabinet 6.3.2 Cleaning computer fans 6.3.2 Cleaning computer fans Location of computer fans The fans are located as shown in the figure below: 3 1 2 xx0200000002 1 Cover 2 Fan 3 Screw Required equipment Equipment, etc. Spare part no. Art. no. Note Vacuum cleaner Cleaning ESD Safe The following procedures details how to clean the computer fans. Please observe the following before commencing any repair work: Turn off all electric power supplies to the robot! Take any necessary measures to ensure that the manipulator does not collapse as parts are removed, e.g. securing the lower arm with fixtures before removing the gearbox, axis 2. Step 1. 98 Action Note/Illustration Loosen the screws on both sides of the cover, see illustration pos 1. A 1 3HAC 16246-1 6 Maintenance activities, controller cabinet 6.3.2 Cleaning computer fans Step 3HAC 16246-1 Action Note/Illustration 2. Remove the covers. 3. Clean the fans with an ESD safe vacuum cleaner. 4. Remount the covers. A 99 6 Maintenance activities, controller cabinet 6.3.3 Cleaning Drive units and air outlet device 6.3.3 Cleaning Drive units and air outlet device Location of drive units The illustration below shows the location of the drive units and air outlet device. 1 1 Drive units 2 Air outlet device 2 Required equipment Equipment, etc. Spare part no. Art. no. Vacuum cleaner Cleaning Note ESD Safe The following procedures detail how to clean the drive units, bleeder resistor and air outlet device. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step 1. 2. 100 Action Illustration/Note Loosen the M5 screws (pos B) to the air outlet device. B Remove the air outlet A 3HAC 16246-1 6 Maintenance activities, controller cabinet 6.3.3 Cleaning Drive units and air outlet device Step Refitting Action Illustration/Note 3. Remove the bleeder resistor. Detailed in Repairs Manual section “Replacement of bleeder resistor”. 4. Clean the Inside of the air outlet. Use an ESD safe vacuum cleaner. 5. Clean the back side of the drive units. See Note above. 6. Clean the bleeder resistor. See Note above. 7. Clean the drive unit fans. See Note above. The procedure below details how to refit the bleeder resistor. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Fit the bleeder resistor into position and secure it with the Art. no. is specified above! spring. Also see the figure above! 2. Secure the cable disconnected during disassembly. 3. Refit the air outlet device. 4. Tighten the M5 screws. 3HAC 16246-1 A 101 6 Maintenance activities, controller cabinet 6.3.4 Cleaning Air outlet 6.3.4 Cleaning Air outlet Location of air outlet The illustration below shows the location of the air outlet shaft 1 1 Air outlet Required equipment Equipment, etc. Spare part no. Art. no. Vacuum cleaner Cleaning Note ESD Safe The following procedures detail how to clean the air outlet shaft. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. 102 1. Remove the drive units. Detailed in Repairs Manual, section “Replacement of drive units and rectifier”. 2. Remove the Bleeder resistor and system fan unit. Detailed in Repairs Manual, section “Replacement of system fan unit”. 3. Use an ESD safe vacuum cleaner to clean the shaft 4. Clean also the space around the transformer from the front of the cabinet, see illustration. A 3HAC 16246-1 6 Maintenance activities, controller cabinet 6.3.4 Cleaning Air outlet Refitting The procedure below details how to refit the Drive units, bleeder resistor and system fan unit. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Refit the drive units. Detailed in Repairs Manual, section “Replacement of drive units and rectifier”. 2. Refit the Bleeder resistor and system fan unit. Detailed in Repairs Manual, section “Replacement of system fan unit”. 3. Refit the air outlet device. 4. Tighten the M5 screws. 3HAC 16246-1 A 103 6 Maintenance activities, controller cabinet 6.3.5 Cleaning Drain filter 6.3.5 Cleaning Drain filter Location of drain filter The illustration below shows the location of the drain filter. 1 2 3 1 Filter holder 2 M5 screw 3 Drain filter Required equipment Equipment, etc. Spare part no. Art no. Filter 3HAC 5393-2 Standard toolkit 3HAC 15571-1 The contents are defined in section "Standard toolkit"! Other tools and procedures may be required. See references to these procedures in the step-by-step instructions below. Removal Note These procedures include references to the tools required. The procedure below details how to remove the drain filter. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. 104 A 3HAC 16246-1 6 Maintenance activities, controller cabinet 6.3.5 Cleaning Drain filter Step Action Note/Illustration 1. Place the computer unit in the service position. Detailed in Repairs Manual, section, “Putting the computer unit in service position”. 2. Loosen the M5 screw, pos. 2 in illustration. 1 2 3 3. Remove the filter holder, pos. 1 in previous illustration. 4. Clean or replace the filter. Refitting The procedure below details how to refit the Drain filter. Please observe the following before commencing any repair work on the controller: Turn off all electric power supplies to the cabinet! Many components inside the cabinet are sensitive to ESD (ElectroStatic Discharge) and will be destroyed if subjected to it! Before handling, make sure you are connected to earth through a special ESD wrist bracelet or similar. Step Action Note/Illustration 1. Fit the cleaned or new filter, pos 3 1 2 3 2. Fit the filter holder, (pos.1) and secure it with the See the figure above! M5 screw, (pos. 2). 3. Put the computer system back in the regular operation position. 3HAC 16246-1 A Detailed in section "Putting the computer in the service position". 105 6 Maintenance activities, controller cabinet 6.3.5 Cleaning Drain filter 106 A 3HAC 16246-1 Repair Manual, part 2 (Circuit Diagrams) Industrial Robot IRB 6600 - 225/2.55 IRB 6600 - 175/2.8 IRB 6600 - 175/2.55 IRB 6650 - 200/2.75 IRB 6650 - 125/3.2 M2000A Repair Manual, part 2 (Circuit Diagrams) IRB 6600/6650 M2000A 3HAC 16247-1 Revision A The information in this manual is subject to change without notice and should not be construed as a commitment by ABB. ABB assumes no responsibility for any errors that may appear in this manual. In no event shall ABB be liable for incidental or consequential damages arising from use of this manual and products described herein. This manual and parts thereof must not be reproduced or copied without ABB’s written permission, and contents thereof must not be imparted to a third party nor be used for any unauthorized purpose. Contravention will be prosecuted. Additional copies of this manual may be obtained from ABB at its then current charge. ©Copyright 2003 ABB All rights reserved. ABB Automation Technology Products AB Robotics SE-721 68 Västerås Sweden 0.0.1 Overview 0.0.1 Overview About This Manual This information product is a manual containing circuit diagrams for both the manipulator and the controller cabinet. Usage This manual should be used during installation/repair/maintenance work. Who Should Read This Manual? This manual is intended for: Organization of Chapters • personnel in the user's organization. • personnel in other organizations. The information product is organized in the following chapters: Chapter Contents 1 Circuit Diagram, manipulator, 3HAC 13347-1 (IRB 66X0/7600) 2 Circuit Diagram, controller, 3HAC 14189-2 (S4Cplus M2000A) Revision Description 0 First edition Revisions A 3HAC 16247-1 • New revisions of the circuit diagrams. A 1 0.0.1 Overview 2 A 3HAC 16247-1 Circuit Diagram 3HAC 13347-1 / Rev. 01 CONTENTS Sheet Contents ........................................................................................................................101 Connection Point Location ...........................................................................................102 Legend ..........................................................................................................................103 Brake Release Unit .......................................................................................................104 Service brake release unit (IRB 7600).......................................................................104.1 Serial Measurement Board ...........................................................................................105 Axis 1............................................................................................................................106 Axis 2............................................................................................................................107 Axis 3............................................................................................................................108 Axis 4............................................................................................................................109 Axis 5 (IRB 7600) ........................................................................................................110 Axis 5 (IRB 6600) .....................................................................................................110.1 Axis 6............................................................................................................................111 Customer Power/Signal/Bus Connections....................................................................112 Customer Power/Signal/Bus and External axis .........................................................112.1 Customer Power/Signal/Bus Connections, ax 3-6.....................................................112.5 Switches axis 1 .......................................................................................................... ..113 Switches/ Fan axis 2 .....................................................................................................114 Switches/ Fan axis 3 .....................................................................................................115 Weld connections..........................................................................................................116 Product Manual IRB 7600/6600 A 1 Contents 101 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Connection Point Location 102 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Legend 103 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Brake Release Unit No. of sheets 20 sheet 104 01 Revision Circuit Diagram 3HAC 13347-1 Service brake release unit (IRB 7600) 104.1 sheet 20 No. of sheets 00 Revision Circuit Diagram 3HAC 13347-1 Serial Measurement Board 105 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Axis 1 106 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Axis 2 107 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Axis 3 108 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Axis 4 109 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Axis 5 (IRB 7600) No. of sheets 20 sheet 110 01 Revision Circuit Diagram 3HAC 13347-1 Axis 5 (IRB 6600) 110.1 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Axis 6 111 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Customer Power/Signal/Bus Connections 112 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Customer Power/Signal/Bus and External axis 112.1 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Customer Power/Signal/Bus Connections, ax 3-6 112.5 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Switches axis 1 113 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Switches/ Fan axis 2 114 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Switches/ Fan axis 3 115 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 Weld connections 116 sheet 20 No. of sheets 01 Revision Circuit Diagram 3HAC 13347-1 ABB Automation Technology Products AB Robotics S-721 68 VÄSTERÅS SWEDEN Telephone: +46 (0) 21 344000 Telefax: +46 (0) 21 132592 Circuit Diagram Contents 3HAC 5582-2/Rev. 03 Page 1 General Information ........................................................................................................ 1 Block Diagram.............................................................................................................. 1-1 View of Control Cabinet............................................................................................... 1-2 View of Control Cabinet............................................................................................... 1-3 Designation................................................................................................................... 1-4 Designation................................................................................................................... 1-5 2 Mains Connection and Power Supply ............................................................................ 1 Mains Connection......................................................................................................... 2-1 Transformer Unit 400-600V......................................................................................... 2-2 Transformer unit 200-440V.......................................................................................... 2-3 Power Supply................................................................................................................ 2-4 External transformer unit 200 - 600V IRB 66X0/7600................................................ 2-5 Transformer unit 400 - 475V IRB 66X0/7600 ............................................................. 2-6 3 Computer Unit and Connector Unit............................................................................... 1 Block Diagram / Computer Unit .................................................................................. 3-1 Cabling in Computer Unit ............................................................................................ 3-2 Main Computer and Hard Disk / Flash Disk Drive ...................................................... 3-3 Computer Cooling ........................................................................................................ 3-4 Base Connector Board and I/O Computer.................................................................... 3-5 Connector Board and I/O Computer............................................................................. 3-6 Connector Board and Axis Computer .......................................................................... 3-7 Base Connector Unit..................................................................................................... 3-8 Connector Plate on Controller Panel ............................................................................ 3-9 4 Emergency Stops and Run Chain................................................................................... 1 Emergency Stop............................................................................................................ 4-1 Run Chain, Operating Mode Selector, 3 modes ........................................................... 4-2 Run Chain, Operating Mode Selector, 2 modes ........................................................... 4-3 Power Unit Servo Disconnector ................................................................................... 4-4 5 Drive System and Robot Cable ....................................................................................... 1 Block Diagram.............................................................................................................. 5-1 Rectifier, Fans and Bleeder .......................................................................................... 5-2 Drive System Signal Connection 2 Drive Units........................................................... 5-3 Drive System Signal Connection 3 Drive Units........................................................... 5-4 Servo Drive Units / IRB 140 ........................................................................................ 5-5 Servo Drive Units / IRB 340 ........................................................................................ 5-6 Servo Drive Units / IRB 640, 840 ................................................................................ 5-7 Servo Drive Units / IRB 1400, 2400 IRC..................................................................... 5-8 Servo Drive Units / IRB 4400, 6400S, PE ................................................................... 5-9 Servo Drive System / IRB 6400R, IRC........................................................................ 5-10 Control Cable IRB 140 ................................................................................................. 5-11 Control Cable IRB 340, 1400 - 2400, IRC (ECB)........................................................ 5-12 Control Cable IRB 640, 840, 4400, and 6400S, PE ..................................................... 5-13 Control Cable IRB 6400R, IRC (GT, GU)................................................................... 5-14 Circuit Diagram S4Cplus 1 Circuit Diagram Contents 3HAC 5582-2/Rev. 03 Page Rectifier, fans and bleeder, IRB 66X0, 7600 ............................................................... 5-15 Servo drive system, IRB 66X0, 7600........................................................................... 5-16 Control cable, IRB 66X0, 7600.................................................................................... 5-17 6 External Axes ................................................................................................................... 1 External Axes ............................................................................................................... 6-1 Axes Computer 2 and Connector Board....................................................................... 6-2 Expansion Board Axis Connector Board ..................................................................... 6-3 Drive System Signal Connection External Axes.......................................................... 6-4 External Axes no. 7th - 9th Control Signal Connection............................................... 6-5 Axis Computer 2 and Axis Connector Unit if External Axis Cabinet ......................... 6-6 Connection to External Axis Cabinet ........................................................................... 6-7 Servogun-SMB power/signals cable ............................................................................ 6-8 DDU Power/Signals Cable, IRB 6400R....................................................................... 6-9 DDU Power/Signals Cable, IRB 6600, 7600 ............................................................... 6-10 DDU Cable, IRB 6600, 7600 ....................................................................................... 6-11 Ext. Axis no.7 SG, IRB 6600, 7600 ............................................................................. 6-12 External axis no.7 RG, IRB 6600, 7600....................................................................... 6-13 External axis no.8 SG, IRB 6600, 7600 ....................................................................... 6-14 7 I/O Units and Field Bus Modules ................................................................................... 1 I/O Unit Position .......................................................................................................... 7-1 Digital Part of Combi I/O and Digital I/O Unit Input Part........................................... 7-2 Digital I/O Unit Output Part ......................................................................................... 7-3 Combi I/O Unit Digital and Analogue Output Part...................................................... 7-4 Digital Input Part of 120V AC I/O Unit....................................................................... 7-5 Digital Output Part of 120V AC I/O Unit .................................................................... 7-6 Relay I/O Unit Input 1-16 ............................................................................................ 7-7 Digital with Relays I/O Output 1-8 .............................................................................. 7-8 Digital with Relays I/O Output 9-16 ............................................................................ 7-9 Analogue I/O Unit ........................................................................................................ 7-10 Remote I/O Unit For Allen Bradley PLC..................................................................... 7-11 Interbus-S Slave ........................................................................................................... 7-12 Profibus DP Slave ........................................................................................................ 7-13 Encoder Unit................................................................................................................. 7-14 Profibus DP Master/Slave ............................................................................................ 7-15 Interbus master/slave optical fibre and copper wire..................................................... 7-16 8 Other Options................................................................................................................... 1 Floppy Disk .................................................................................................................. 8-1 Service Equipment Supply ........................................................................................... 8-2 External Connection System Signals ........................................................................... 8-3 Position Switches on Manipulator................................................................................ 8-4 Customer Signal, IRB 140, 340, 1400.......................................................................... 8-5 Customer Power/Signal IRB 2400, 4400, 6400S/PE ................................................... 8-6 Customer Cable Power/Signal/CAN IRB 6400R......................................................... 8-7 External Control Panel ................................................................................................. 8-8 2 Circuit Diagram S4Cplus Circuit Diagram Contents 3HAC 5582-2/Rev. 03 Page Extension Cable Teach Pendant ................................................................................... 8-9 Time Relay ................................................................................................................... 8-10 External I/O CAN-BUS Connection ............................................................................ 8-11 Customer power/signal/Profibus, IRB 6400R .............................................................. 8-12 LAN Ethernet connection............................................................................................. 8-13 Customer power/CAN-BUS IRB 640/6400S ............................................................... 8-14 Customer cable power/signal CAN-BUS IRB 6600/7600 ........................................... 8-15 Customer cable power/signal Profibus IRB 66X0/7600 .............................................. 8-16 Extended customer power/signal/Profibus, IRB 6400R............................................... 8-17 Position Switches 1/2/3 on Manipulator, IRB 66X0, 7600 .......................................... 8-18 Customer Cable Power/Signals/IBS, IRB 6600, 7600 ................................................. 8-19 9 External Axis Cabinet...................................................................................................... 1 Block Diagram.............................................................................................................. 9-1 View of External Axis Cabinet..................................................................................... 9-2 Designation................................................................................................................... 9-3 Mains Connection......................................................................................................... 9-4 Transformer Unit .......................................................................................................... 9-5 Power Supply, I/O Supply ............................................................................................ 9-6 Power Unit.................................................................................................................... 9-7 Rectifier, Fans and Bleeder .......................................................................................... 9-8 Drive Unit Signal Connection, 1 External Drive Unit.................................................. 9-9 Drive Unit Signal Connection 2 External Drive Units ................................................. 9-10 Drive Unit Signal Connection 3 External Drive Units ................................................. 9-11 Drive Unit and Control Cable Drive Unit GT .............................................................. 9-12 Drive Unit and Control Cable Drive Unit GT+CCB.................................................... 9-13 Drive Unit and Control Cable....................................................................................... 9-14 Service Equipment Supply ........................................................................................... 9-15 Circuit Diagram S4Cplus 3 Circuit Diagram Contents 4 3HAC 5582-2/Rev. 03 Page Circuit Diagram S4Cplus 1 General Information No. of sheets 107 sheet 1-0 04 Revision Circuit Diagram 3HAC 5582-2 Block Diagram 1-1 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 View of Control Cabinet 1-2 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 View of Control Cabinet 1-3 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Designation 1-4 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Designation 1-5 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 2 Mains Connection and Power Supply No. of sheets 107 sheet 2-0 04 Revision Circuit Diagram 3HAC 5582-2 Mains Connection 2-1 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Transformer Unit 400-600V 2-2 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Transformer unit 200-440V 2-3 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Power Supply 2-4 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 External transformer unit 200 - 600V IRB 66X0/7600 No. of sheets 107 sheet 2-5 04 Revision Circuit Diagram 3HAC 5582-2 Transformer unit 400 - 475V IRB 66X0/7600 No. of sheets 107 sheet 2-6 04 Revision Circuit Diagram 3HAC 5582-2 3 Computer Unit and Connector Unit No. of sheets 107 sheet 3-0 04 Revision Circuit Diagram 3HAC 5582-2 Block Diagram / Computer Unit 3-1 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Cabling in Computer Unit 3-2 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Main Computer and Hard Disk / Flash Disk Drive 3-3 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Computer Cooling 3-4 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Base Connector Board and I/O Computer 3-5 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Connector Board and I/O Computer 3-6 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Connector Board and Axis Computer 3-7 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Base Connector Unit 3-8 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Connector Plate on Controller Panel 3-9 sheet 91 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 4 Emergency Stops and Run Chain No. of sheets 107 sheet 4-0 04 Revision Circuit Diagram 3HAC 5582-2 Emergency Stop 4-1 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Run Chain, Operating Mode Selector, 3 modes 4-2 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Run Chain, Operating Mode Selector, 2 modes 4-3 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Power Unit Servo Disconnector 4-4 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 5 Drive System and Robot Cable No. of sheets 107 sheet 5-0 04 Revision Circuit Diagram 3HAC 5582-2 Block Diagram 5-1 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Rectifier, Fans and Bleeder 5-2 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive System Signal Connection 2 Drive Units 5-3 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive System Signal Connection 3 Drive Units 5-4 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Servo Drive Units / IRB 140 5-5 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Servo Drive Units / IRB 340 5-6 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Servo Drive Units / IRB 640, 840 5-7 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Servo Drive Units / IRB 1400, 2400 IRC 5-8 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Servo Drive Units / IRB 4400, 6400S, PE 5-9 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Servo Drive System / IRB 6400R, IRC 5-10 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Control Cable IRB 140 5-11 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Control Cable IRB 340, 1400 - 2400, IRC (ECB) 5-12 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Control Cable IRB 640, 840, 4400, and 6400S, PE 5-13 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Control Cable IRB 6400R, IRC (GT, GU) 5-14 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Rectifier, fans and bleeder, IRB 66X0, 7600 5-15 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Servo drive system, IRB 66X0, 7600 5-16 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Control cable, IRB 66X0, 7600 5-17 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 6 External Axes No. of sheets 107 sheet 6-0 04 Revision Circuit Diagram 3HAC 5582-2 External Axes 6-1 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Axes Computer 2 and Connector Board 6-2 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Expansion Board Axis Connector Board 6-3 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive System Signal Connection External Axes 6-4 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 External Axes no. 7th - 9th Control Signal Connection 6-5 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Axis Computer 2 and Axis Connector Unit if External Axis Cabinet 6-6 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Connection to External Axis Cabinet 6-7 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Servogun-SMB power/signals cable 6-8 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 DDU Power/Signals Cable, IRB 6400R 6-9 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 DDU Power/Signals Cable, IRB 6600, 7600 6-10 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 DDU Cable, IRB 6600, 7600 6-11 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Ext. Axis no.7 SG, IRB 6600, 7600 6-12 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 External axis no.7 RG, IRB 6600, 7600 6-13 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 External axis no.8 SG, IRB 6600, 7600 6-14 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 7 I/O Units and Field Bus Modules No. of sheets 107 sheet 7-0 04 Revision Circuit Diagram 3HAC 5582-2 I/O Unit Position 7-1 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Digital Part of Combi I/O and Digital I/O Unit Input Part 7-2 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Digital I/O Unit Output Part 7-3 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Combi I/O Unit Digital and Analogue Output Part 7-4 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Digital Input Part of 120V AC I/O Unit 7-5 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Digital Output Part of 120V AC I/O Unit 7-6 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Relay I/O Unit Input 1-16 7-7 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Digital with Relays I/O Output 1-8 7-8 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Digital with Relays I/O Output 9-16 7-9 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Analogue I/O Unit 7-10 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Remote I/O Unit For Allen Bradley PLC 7-11 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Interbus-S Slave 7-12 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Profibus DP Slave 7-13 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Encoder Unit 7-14 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Profibus DP Master/Slave 7-15 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Interbus master/slave optical fibre and copper wire 7-16 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 8 Other Options No. of sheets 107 sheet 8-0 04 Revision Circuit Diagram 3HAC 5582-2 Floppy Disk 8-1 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Service Equipment Supply 8-2 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 External Connection System Signals 8-3 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Position Switches on Manipulator 8-4 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Customer Signal, IRB 140, 340, 1400 8-5 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Customer Power/Signal IRB 2400, 4400, 6400S/PE 8-6 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Customer Cable Power/Signal/CAN IRB 6400R 8-7 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 External Control Panel 8-8 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Extension Cable Teach Pendant 8-9 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Time Relay 8-10 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 External I/O CAN-BUS Connection 8-11 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Customer power/signal/Profibus, IRB 6400R 8-12 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 LAN Ethernet connection 8-13 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Customer power/CAN-BUS IRB 640/6400S 8-14 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Customer cable power/signal CAN-BUS IRB 6600/7600 8-15 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Customer cable power/signal Profibus IRB 66X0/7600 8-16 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Extended customer power/signal/Profibus, IRB 6400R 8-17 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Position Switches 1/2/3 on Manipulator, IRB 66X0, 7600 8-18 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Customer Cable Power/Signals/IBS, IRB 6600, 7600 8-19 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 9 External Axis Cabinet No. of sheets 107 sheet 9-0 04 Revision Circuit Diagram 3HAC 5582-2 Block Diagram 9-1 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 View of External Axis Cabinet 9-2 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Designation 9-3 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Mains Connection 9-4 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Transformer Unit 9-5 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Power Supply, I/O Supply 9-6 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Power Unit 9-7 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Rectifier, Fans and Bleeder 9-8 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive Unit Signal Connection, 1 External Drive Unit 9-9 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive Unit Signal Connection 2 External Drive Units 9-10 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive Unit Signal Connection 3 External Drive Units 9-11 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive Unit and Control Cable Drive Unit GT 9-12 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive Unit and Control Cable Drive Unit GT+CCB 9-13 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Drive Unit and Control Cable 9-14 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 Service Equipment Supply 9-15 sheet 107 No. of sheets 04 Revision Circuit Diagram 3HAC 5582-2 ABB Automation Technology Products AB Robotics S-721 68 VÄSTERÅS SWEDEN Telephone: +46 (0) 21 344000 Telefax: +46 (0) 21 132592
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Key Features
- 175 kg payload
- 2.55 m reach
- Active Safety features
- BaseWare OS
- Spot welding capability
- Material handling
- Machine tending
- Floor mounting
- IP67 protection
- Cleanroom class 100
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Frequently Answers and Questions
What is the maximum payload capacity of the ABB IRB 6600 - 175/2.55?
The robot has a maximum payload capacity of 175 kg.
What is the reach of the ABB IRB 6600 - 175/2.55?
The robot has a maximum reach of 2.55 meters.
What safety features are incorporated in the ABB IRB 6600 - 175/2.55?
This robot includes Active Safety features like Active Brake System and Electronically Stabilised Path.