FAAC 746 ER Z16, Z20, CAT, RF Slide Gate Operator User Manual
The FAAC 746 Slide Gate Operator is an electro-mechanical operator that transmits motion to the sliding leaf via a rack or chain. The non-reversing system ensures the gate is mechanically locked when the motor is not operating. It comes equipped with a mechanical clutch and an electronic device for adjustable anti-crushing safety. The system includes a manual release for moving the gate in the event of a power cut or malfunction. The electronic control equipment is housed within the operator.
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746 Slide Gate Operator FAAC International Inc. Headquarter & East Coast Operations 5151 Sunbeam Road Suites 9-11 Jacksonville, FL 32257 Tel. 866 925 3222 www.faacusa.com FAAC International Inc. West Coast Operations 357 South Acacia Avenue Unit 357 Fullerton, CA 92831 Tel. 800 221 8278 AUTOMATED SYSTEM 746 & ELECTRONIC CONTROL UNIT 780D where: Ta = opening time Tc = closing time Tp = pause time Ti = time of interval between two complete cycles These instructions apply to the following models: 746 ER Z16 - 746 ER Z20 - 746 ER CAT - 746 ER RF The FAAC mod. 746 automated system for sliding gates is an electro-mechanical operator transmitting motion to the sliding leaf via a rack or chain pinion appropriately coupled to the gate. The non-reversing system ensures the gate is mechanically locked when the motor is not operating and, therefore, no lock needs to be installed. The gearmotor is equipped with a mechanical clutch which, combined with an electronic device, offers the necessary adjustable anti-crushing safety and guarantees stopping or reversing the gate movement. A handy manual release makes it possible to move the gate in the event of a power cut or malfunction. The electronic control equipment is equipped with a gearmotor and is housed inside the operator. The 746 automated system was designed and manufactured to control access of vehicles. Avoid any other use whatever. Use frequency graph % Benutzungs- % Frecuencia % gebruiks% Freq. % Duty % Fréq. Utilizzo Cycle d’utilisation frequenz de utilización frequentie 100 90 80 70 60 50 40 30 20 10 0 Tempo (h) Tab. 1 Securing corners Pinion Limit sensor switch Operator cover 780 D Control board Adjustment screw for anti-crushing clutch Oil filling plug Operator earthing Lever operated release system Protective side panels Cover for 780D control board 1. DESCRIPTION AND TECHNICAL SPECIFICATIONS MAXIMUM USE CURVE The curve makes it possible to establish maximum work time (T) according to use frequency (F). E.g.: The 746 gearmotor can operate non-stop at 70% use frequency. To ensure efficient operation, operate in the work range below the curve. Important: The curve is obtained at a temperature of 24°C. Exposure to the direct sun rays can reduce use frequency down to 20%. Calculation of use frequency The percentage of effective work time (opening + closing) compared to total time of cycle (opening + closing + pause times). Calculation formula: %F = Ta + Tc 2 3 4 Temps (h) 5 6 7 Zeit (h) 8 9 10 11 12 Tiempo (h) werktijd (h) TECHNICAL SPECIFICATIONS OF 746 GEARMOTOR MODEL 746 Power supply (Vac +6% -10% 50-60Hz) 230 Absorbed power (W) 300 Reduction ratio 1 : 30 Type of pinion Z20 - Z16 Rack Module 4 - step 12.566 Max. thrust (daN) 50 (Z20) - 62,5 (Z16) Max. Torque (Nm) 20 Winding thermal protection (°C) 120 Use frequency 70% (see graph) Oil quantity (l) 1,8 Type of oil FAAC XD 220 Operatine ambient temperature (°C) -20 ÷ +55 Gearmotor weight (Kg) 14 Protection class IP 44 Gate max. weight (Kg) 400 (Z20) - 600 (Z16) Gate speed (m/min) 12 (Z20) - 9,6 (Z16) Gate max. length (m) (time-out) 50 (Z20) - 40 (Z16) Clutch twin-disk in oil bath Protective treatment cataphoresis Equipment 780D Limit-switch MSL or inductive Gearmotor overall dimensions LxHxD (mm) see Fig. 2 Electric motor technical specifications RPM 1400 Power (W) 300 Absorbed current (A) 1.5 Starting capacitor (µF) 25 Power supply (Vac +6% -10%; 50-60Hz) 230 Fig. 1 1.1. 1 Time (h) X 100 Ta + Tc + Tp + Ti 19 To make the connections efficiently, allow the cables to project by about 40 cm from the hole (Figs.5-6 ref.) of the foundation plate. 2. DIMENSIONS Fig. 4 Fig. 2 3. ELECTRIC EQUIPMENT (standard system) Fig. 5 Operator 746 with 780D equipment Photocells Key-operated push-button Flashing lamp Radio receiver Fig. 3 4. INSTALLATION OF THE AUTOMATED SYSTEM 4.1. Fig. 6 PRELIMINARY CHECKS To ensure safety and an efficiently operating automated system, make sure the following conditions are observed: • • • • • The gate structure must be suitable for automation. The following are necessary in particular: wheel diameter must be in proportion to the weight of the gate to be automated, an upper guide must be provided, plus mechanical stop limits to prevent the gate derailing. The soil must permit sufficient stability for the foundation plinth. There must be no pipes or electric cables in the plinth excavation area. If the gearmotor is exposed to passing vehicles, install, if possible, adequate means of protection against accidental impact. Check if an efficient earthing is available for connection to the gearmotor. Fig. 7 4.3. 4.2. MASONRY FOR FOUNDATION PLATE MECHANICAL INSTALLATION 1) Assemble the securing corners and anti-vibration spacers on the operator as shown in Fig. 8. 2) Open the cover, unscrewing the securing screws. 3) Place the operator on the plate, using the supplied washers and nuts as shown in Fig. 9. During this operation, route the cables through the duct inside the lower half-casing of the operator (Fig.10 - Ref. A). To access the electronic equipment, route the cables through the appropriate hole, using the supplied rubber cable-clamp. Make absolutely sure to unsheathe all the cables so that the clamp holds single cables only (Fig.10 - Ref. B). 1) Assemble the foundation plate as shown in figure 4. 2) The foundation plate must be located as shown in figure 5 (right closing) or figure 6 (left closing) to ensure the rack and pinion mesh correctly. 3) Prepare a foundation plinth as shown in fig.7 and wall the foundation plate, supplying one or more sheaths for routing electric cables. Using a spirit level, check if the plate is perfectly level. Wait for the cement to set. 4) Lay the electric cables for connection to the accessories and power supply as shown in figure 3. 20 5) Secure the gearmotor to the foundation plate, tightening the nuts as in Fig.12. 6) Prepare the operator for manual operating mode as described in chapter 8. Fig. 12 Fig. 8 4.4. INSTALLING THE RACK 4.4.1. Fig. 9 4.4.2. A B STEEL RACK TO WELD (Fig.13) 1) Place the three threaded pawls on the rack element, positioning them at the top of the slot. In this way, the slot play will enable any adjustments to be made. 2) Manually take the leaf into its closing position. 3) Lay the first piece of rack level on the Fig. 13 pinion and weld the threaded pawl on the gate as shown in figure15. 4) Move the gate manually, checking if the rack is resting on the pinion, and weld the second and third pawl. 5) Bring another rack element near to the previous one, using a piece of rack (as shown in figure 16) to synchronise the teeth of the two elements. 6) Move the gate manually and weld the three threaded pawls, thus proceeding until the gate is fully covered. STEEL RACK TO SCREW (Fig. 14) 1) Manually take the leaf into its closing position. 2) Lay the first piece of rack level on the pinion and place the spacer between the rack and the gate, positioning it at the top of the slot. 3) Mark the drilling point on the gate. Drill a Ø 6,5 mm hole and apply thread with a Ø 8 mm male tap. Screw the bolt. 4) Move the gate manually, checking if the rack is resting on the pinion, Fig. 14 and repeat the operations at point 3. 5) Bring another rack element near to the previous one, using a piece of rack (as shown in figure 16) to synchronise the teeth of the two elements. 6) Move the gate manually and carry out the securing operations as for the first element, thus proceeding until the gate is fully covered. Fig. 10 4.4.3. NYLON RACK TO SCREW (Fig.14bis) 1) Manually take the leaf into its closing position. Fig. 14bis 2) Lay the first piece of the rack level on the pinion and mark the drilling point on the gate; drill Ø 4 mm and screw the self-tapping screw 6 x 20 mm to the relevant reinforcing plate. 3) Move the gate manually, checking if the rack is resting on the pinion, and repeat the operations at point 2. 4) Bring another rack element near to the previous one, using a piece of rack (as shown in figure 16) to synchronise the teeth of the two elements. 5) Move the gate manually and carry out the securing operations as for the first element, thus proceeding until the gate is fully covered. Fig. 11 21 Fig. 19 4.5.2. MOD. 746 ER RF (Figs. 20 - 21) Fig. 15 1) Insert the spring pin on the shaft, using a hammer. 2) Fit the idle transmissions bracket on the gearmotor flange, using the four screws (M5 x 12) and the appropriate washers , in the kit as shown in Fig. 20. 3) Fit the chain pinion on the shaft, making the pinion seats coincide with the spring pin and tighten the screw and the appropriate washers and . 4) Pass the chain as shown in Fig. 21 ref. A and install the housing with screw and washer as in Fig. 20. 5) In case of operators with MLS limit switches, arrange the supports for the positioning of the magnets supplied while observing the dimensions given in fig. 21 ref. B. Fig. 16 • • • • • Notes on rack installation Make sure that, during the gate travel, all the rack elements do not exit the pinion. Do not, on any account, weld the rack elements either to the spacers or to each other. When the rack has been installed, to ensure it meshes correctly with the pinion, we advise you to lower the gearmotor position by about 1.5 mm (Fig.17). Manually check if the gate habitually reaches the mechanical stop limits and make sure there is no friction during gate travel. Do not use grease or other lubricants Fig. 17 between rack and pinion. 4.5. Fig. 20 INSTALLATION OF CHAIN PINIONS In the versions for applications with chain and idle transmissions, a Z16 or Z20 chain pinion must be installed. Proceed as follows: A 4.5.1. MOD. 746 ER CAT (Figs. 18 - 19) 1) Insert the spring pin on the shaft, using a hammer. 2) Fit the chain pinion on the shaft, making the pinion seats coincide with the spring pin and tighten the screw with the appropriate washers. 0÷10 mm 5÷12 mm B Fig. 21 Fig. 18 22 5.3. 5. CONTROL BOARD 780D 5.1. DL Led J1 J2 J5 J6 J7 J8 F1 F2 F – + WARNINGS Important: Before attempting any work on the control board (connections, maintenance), always turn off power. - Install, upstream of the system, a differential thermal breaker with adequatetrippingthreshold. - Connect the earth cable to the terminal on J7 connector of the board, and to the bush on the operator (figs. 22 and 40). - Always separate power cables from control and safety cables (pushbutton, receiver, photocells, etc.). To avoid any electric noise, use separate sheaths or a shielded cable (with earthed shield). 5.2. TECHNICAL SPECIFICATIONS Power supply V~ (+6% -10%) 230 Absorbed power (W) 10 Motor max. load (W) 1000 Accessories max. load (A) 0,5 Operating ambient temperature -20 °C +55 °C Protection fuses 2 (see fig. 22 and par. 5.3) Function logics: Automatic / “Stepped” automatic / Semi-automatic / Safety devices / Semi-automatic B / Dead-man C / “Stepped” semi-automatic / Mixed B/C logic Work time Programmable (from 0 to 4,1 min.) Pause time Programmable (from 0 to 4,1 min.) Thrust force Adjustable over 50 levels Terminal board inputs: Open - Partial Open - Opening safety devices - Closing safety devices - Stop - Edge - Power supply+Earth On-connector inputs Opening and closing limit-switch Motor capacitor Terminal board outputs: Flashing lamp - Motor - 24 Vdc accessories power supply - 24 Vdc indicator-light / Timed output / Electric lock command - 'traffic lights' - Fail safe Rapid connector 5-pin card connection for Minidec, Decoder or RP receivers Programming 3 keys (+, -, F) and display, "basic" or "advanced" mode Basic mode programmable functions: Function logic - Pause time - Thrust Force - Opening-closing direction Advanced mode programmable functions: Torque at initial thrust - Braking - Fail safe - Pre-flashing - Indicator-light/Timed output/Electric lock or 'traffic lights' command Opening and closing safety devices logic - Encoder/ Anti-crushing sensitivity Decelerations - Partial opening time - Work time - Assistance request - Cycle counter LAYOUT AND COMPONENTS SIGNALLING AND PROGRAMMING DISPLAY INPUTS STATUS CONTROL LED LOW VOLTAGE TERMINAL BOARD CONNECTOR FOR DECODER/MINIDEC/RP RECEIVER CONNECTOR FOR MOTOR STARTING CAPACITOR MOTOR AND FLASHING LAMP CONNECTION TERMINAL BOARD 230 Vac POWER SUPPLY TERMINAL BOARD DOUBLE CONNECTOR J8 - LIMIT-SWITCH QUICK FIT MOTOR AND TRANSFORMER PRIMARY WINDING FUSE (F 5A) LOW VOLTAGE AND ACCESSORIES FUSE (T 800mA) "F" PROGRAMMING PUSH-BUTTON "–" PROGRAMMING PUSH-BUTTON "+" PROGRAMMING PUSH-BUTTON J1 CONNECTOR 1 2 3 4 5 6 7 8 9 10 11 12 OPEN A (total opening) OPEN B (partial opening) FSW-OP (opening safety devices) FSW-CL (closing safety devices) STOP SAFE (“edge” safety devices) - (negative for power supply to accessories) - (negative for power supply to accessories) +24V (supply to accessories) +24V (supply to accessories) FSW-TX (negative for emitting photocells - FAILSAFE) W.L. (negative for indicator light) + J7 – F J8 J1 J5 J6 DL F1 Led J2 Led F2 Fig. 22 23 5.4. Opening safety devices: they are tripped when an obstacle is detected only during gate opening movement. They cause immediate closure and resumption of opening motion on release (see programming in par. 5.5.2.) ELECTRIC CONNECTIONS 230Vac 50-60Hz Closing safety devices: they are tripped when an obstacle is detected only during gate closing movement. They cause re-opening, either immediate or on release (see programming in par. 5.5.2.) BLUE Opening/closing safety devices: they are tripped during the gate opening and closing movements. They cause stopping and restart motion on release. 230 Vac (max. 60W) Capacitor J5 "Edge" safety devices: they are tripped during the gate opening and closing movements. They cause immediate reversal of motion and stopping after two seconds. Encoder: it is tripped if there is an obstacle during gate opening and closing movements. It causes immediate reversal of motion and stopping after two seconds. N.B. If two or more safety devices have the same function (opening, closing, opening and closing, edge), the contacts must be connected to each other in series (fig. 25). N.C. contacts must be used. N.B: If safety devices are not used, jumper connect the terminals as shown in fig. 26. The most common photocell and safety device lay-outs are shown below (from fig. 27 to fig. 34). LIMIT-SWITCH J1 + + SAFE CL OP OPEN A OPEN B 24 Vcc max. 3W TOTAL OPEN Connection of two N.C. contacts in series (e.g. Photocells, Stop, Edge, etc.) For connection of the photocells and safety devices, see paragraph 5.4.1. PARTIAL OPEN Fig. 25 STOP + + SAFE CL OP OPEN B OPEN A Connection of no safety device Fig. 23 Fig. 26 + + CL OP SAFE Connection of photocells and safety devices OPEN B 5.4.1. OPEN A Connection of a closing safety device and an opening safety device Before connecting the safety devices and photocells we advise you to select the type of operation according to the movement area they have to protect (see fig.24 for example): Fig. 27 Opening or opening/closing photocells + + SAFE CL OP OPEN B Connection of an "edge" safety device OPEN A Closing photocells "Edge" safety devices Closing photocells Fig. 28 Fig. 24 24 + + SAFE CL OP OPEN A + + SAFE CL OP OPEN B OPEN A OPEN B Connection of two pairs of closing photocells and two edge safety devices Connection of a pair of opening photocells Fig. 29 + + SAFE CL OP OPEN B OPEN A Connection of a pair of closing photocells Fig. 32 + + OP CL SAFE Fig. 30 OPEN B OPEN A Connection of a pair of closing photocells, a pair of opening photocells and a pair of opening/closing photocells + + SAFE CL OP OPEN B OPEN A Connection of a pair of opening photocells, a pair of closing photocell and an edge safety device TX OP/CL TX OP RX OP/CL RX OP RX OP Fig. 31 TX OP Fig. 33 25 To install several partial opening pulse generators, connect the N.O. contacts in parallel (fig.35). TX OP/CL FSW OP - Opening safety devices contact (terminal 3): The purpose of the opening safety devices is to protect the leaf movement area during opening. During opening, in the A-AP-S-E-EP logics the safety devices reverse the movement of the gate, or stop and restart the movement when it is released (see advanced programming in Chpt. 5.5.2). During the opening cycle in logics B, C and B/C, they interrupt movement. They never operate during the closing cycle. If the Opening safety devices are engaged when the gate is closed, they prevent the opening movement. To install several safety devices, connect the N.C. contacts in series (fig.25). NB.: If no opening safety devices are connected, jumper connect inputs FSW OP and -TX FSW (fig. 26). FSW CL - Closing safety devices contact (terminal 4): The purpose of the closing safety devices is to protect the gate movement area during closing. During closing, in the A-AP-S-E-EP logics, the safety devices reverse the movement of the gate, or stop and reverse the movement when it is released (see advanced programming in Chpt. 5.5.2). During the closing cycle in logics B, C and B/C, they interrupt movement. They never operate during the opening cycle. If the Closing safety devices are engaged when the gate is open, they prevent the closing movement. To install several safety devices, connect the N.C. contacts in series (fig.25). NB.: If no closing safety devices are connected, jumper connect terminals FSW CL and -TX FSW (fig. 26). STOP - STOP contact (terminal 5): any device (e.g. a push-button) which, by opening a contact, stops gate movement. To install several STOP devices, connect the N.C. contacts in series (fig. 25). NB.: If STOP devices are not connected, jumper connect the STOP and - terminals. SAFE - EDGE safety device contact (terminal 6): The purpose of the "edge" safety device is to protect the leaf movement area during opening/closing. In all logics, during opening and closing, the safety device reverses gate movement for 2 seconds. If the safety devices operate again during the 2seconds reversing time, it stops movement (STOP) without any reversing. If the Edge safety device is engaged while the gate is closed or open, it prevents movement. To install several safety devices, connect the N.C. contacts in series (fig.25). NB.: If edge safety devices are not connected, jumper connect the SAFE and - inputs (fig. 26). + + SAFE CL OP OPEN B OPEN A Connection of a pair of closing photocells and a pair of opening/closing photocells RX OP/CL Fig. 34 Connection of two N.O. contacts in parallel (e.g. Open A, Open B) Fig. 35 5.4.2. J7 Terminal board - Power supply (fig. 23) POWER SUPPLY (terminals PE-N-L): PE: Earth connection N : Power supply ( Neutral ) L : Power supply ( Line ) NB.: For correct operation, the board must be connected to the earth conductor in the system. Install an adequate differential thermal breaker upstream of the system. 5.4.3. J6 Terminal board - Motors and flashing lamp (fig. 23) MOTOR - (terminals MOT-C, MOT-1, MOT-2): Motor connection (see Par. 6.5). LAMP - (terminals LAMP L, LAMP N): Flashing lamp output 230Vac max 60W. 5.4.4. – Negative for power supply to accessories (terminals 7 and 8) + 24 Vdc - Positive for power supply to accessories (terminals 9 and 10) Important: Accessories max. load is 500 mA. To calculate absorption values, refer to the instructions for individual accessories. J1 Terminal board - Accessories (fig. 23) Consult the relevant tables for a detailed description of operation in the different logics OPEN A - “Total Opening” command (terminal 1): any pulse generator (push-button, detector, etc.) which, by closing a contact, commands total opening and/or closing of the gate leaf. To install several total opening pulse generators, connect the N.O. contacts in parallel (fig. 35). OPEN B - “Partial opening” or “Closing” command (terminal 2): any pulse generator (push-button, detector, etc.) which, by closing a contact, commands partial opening and/or closing of the gate leaf. In the B, C and B/C logics, it always commands gate closure. 26 TX -FSW - Negative for power supply to photocell transmitters (terminal 11) If you use this terminal for connecting the negative for supplying power to the photocell transmitters, you may, if necessary, also use the FAIL SAFE function (see advanced programming in Chpt. 5.5.2). If this function is enabled, the equipment checks operation of the photocells before every opening or closing cycle. W.L. - 5.5. Power supply to indicator light / timed exit / electric lock / 'traffic lights' (terminal 12) Connect any 24 Vdc - 3 W max indicator light, timed exit, command device for electric lock or 'traffic lights' between this terminal and the +24V (see advanced programming in Chap. 5.5.2). To avoid geopardising correct operation of the system, do not exceed the indicated power. 5.4.5. PROGRAMMING To program operation of the automated system, access the "PROGRAMMING" mode with keys F,+ and -, and using the display on the equipment. Attention: before attempting to power up the system, we advise you to re-position the equipment's cover, to avoid coming into contact with high voltage parts, and to use the push-buttons on the cover to activate the keys (fig. 39). + - F J2 Connector - Rapid connection to Minidec, Decoder and RP This is used for rapid connection of Minidec, Decoder and RP receivers (see fig. 36, 37 and 38). Fit the accessory with the components side toward connector J1. Insert and remove after cutting power. Fig. 39 5.4.6. J5 Connector -Rapid connection to Capacitor Quick-fit connector for connecting the motor starting capacitor. Programming is divided in two parts: BASIC and ADVANCED. 5.5.1. 5.4.7. Double connector J8 - Limit-switch quick fit Quick-fit connector for connecting the limit -switch. For connecting both the MLS limit-switch and the inductive limit-switch (fig. 23 ref.) to the equipment. PLUS BASIC PROGRAMMING To access BASIC PROGRAMMING, press key F: •if you press it (and hold it down), the display shows the name of the first function. •if you release the key, the display shows the value of the function that can be modified with keys + and -. •if you press F again (and hold it down), the display shows the name of the next function, etc. •when you reach the last function, press F to exit the program, and the display resumes showing the gate status. The following table shows the sequence of functions accessible in BASIC PROGRAMMING: MINIDEC F BASIC PROGRAMMING Fig. 36 Display Function Default FUNCTION LOGICS (see table of logics): = Automatic = "Stepped" automatic = "Safety" Automatic = Semi-automatic = "Stepped" Semi-automatic = Dead-man = "B" Semi-automatic = Mixed Log. (B opening / C closing) Fig. 37 PAUSE TIME: This has effect only if the automatic logic was selected. Adjustable from to sec. in one-second steps. Subsequently, display changes to minutes and tens of seconds (separated by a point) and time is adjusted in 10-second steps, up to the maximum value of minutes. RP E.g. if the display shows min. and 50 sec. Fig. 38 27 , pause time is 2 Display Function FORCE: Adjusts Motor thrust. = minimum force = maximum force Default Display If this function is activated, it enables a function test of the photocells before any gate movement. If the test fails (photocells not serviceable signalled by value on the display), the gate does not start moving. OPENING DIRECTION: Indicates the gate opening movement and makes it possible not to change the motor connections on the terminal board. = Rightward opening movement = Leftward opening movement = Active = Disabled PRE-FLASHING (5 s): Activates the flashing lamp for 5 seconds before start of movement. STATUS OF AUTOMATED SYSTEM: Exit from programming, save data, and return to gate status viewing. = Closed = Now opening = At "STOP" = Open = Pause = "FAIL SAFE" tripped = Now closing = Now reversing = Photocells tripped 5.5.2. = Disabled = Only before opening = Only before closing = Before every movement INDICATOR-LIGHT: If is selected, the output functions as a standard indicator-light (lighted at opening and pause, flashing at closing, and off when gate closed). Courtesy light: Different figures correspond to timed activation of the output, which can be used (by a relay) to power a courtesy to lamp. Time can be adjusted from sec. in 1-second steps, and from to min. in 10-second steps. Electric lock command and 'traffic lights' functions: If you press key - from the setting, the closing electric lock is command for the activated; If you press - again, the command for the closing and opening electric lock is set; if you press the - key again, you can set the 'traffic lights' functions and . = Standard indicator-light from to = Timed output. = electric lock command before opening movement = electric lock command before opening and closing movements = 'traffic lights' function: the output is active in "open" and "open on pause" status and is disabled 3 seconds before the closing manoeuvre starts. Note: there is 3 seconds of pre-flashing before the closing manoeuvre. = 'traffic lights' function: the output is active only in "closed" status. Attention: do not exceed the output's maximum load (24Vdc-3W). If necessary, use a relay and a power supply source outside the equipment. ADVANCED PROGRAMMING To access ADVANCED PROGRAMMING, press key F and, as you hold it down, press key +: •if you release key + , the display indicates the name of the first function. •if you release key F too, the display shows the value of the function that can be modified with keys + and -. •if you press key F (and hold it down), the display shows the name of the next function, and if you release it, the value that can be modified with keys + and - is shown. •when you reach the last function, press F to exit the program, and the display resumes showing the gate status. The following table shows the sequence of functions accessible in ADVANCEDPROGRAMMING: ADVANCEDPROGRAMMING Display Function FAIL SAFE: F + Function + Default MAXIMUM TORQUE AT INITIAL THRUST: The motor operate at maximum torque (ignoring the torque setting) at start of movement. Useful for heavy leaves. = Active = Disabled FINAL BRAKING: When the gate engages the opening or closing limit-switch, a braking stroke can be selected to ensure the leaf is stopped immediately. If decelerations are selected, braking starts when they finish. At value, braking is disabled. Time can be adjusted from to in 0.01-second steps. = Braking disabled from to = Timed braking CLOSING PHOTOCELLS LOGIC: Select the tripping mode of the closing photocells. They operate for the closing movement only: they stop movement and reverse it when they are released, or they reverse it immediately. = Reverse on release = Reverse immediately to opening 28 Default Display Function Default Display Function OPENING PHOTOCELLS LOGIC: PARTIAL OPENING: Select the tripping mode of the opening photocells. They operate for the opening movement only: they stop the movement and restart it when they are released, or they reverse it immediately. = Reverse immediately to closing = Restart movement on release You can adjust the width of partial leaf opening. Time can be adjusted from to in 1 second steps. If an encoder is used, the adjustment is not determined by time but by motor revs, thus obtaining greater partial-opening precision. For example, with pinion Z20, partial opening can vary from about 60 cm to 4 m. ENCODER: If the encoder is used, you may select its presence. If the encoder is present and enabled, "decelerations" and "partial opening" are controlled by the encoder (see relevant paragraphs). The encoder operates as an anti-crushing device: If the gate strikes an obstacle during opening or closing, the encoder immediately reverses gate leaf movement for 2 seconds. If the encoder operates again during the 2-seconds reversing time, it stops movement (STOP) without commanding any reversing. If no sensor is . If supplied, the parameter must be set on there is the encoder, adjust the sensitivity of the anti-crushing system, by varying the parameter (maximum sensitivity) and between (minimum sensitivity). WORK TIME (tome-out): We advise you to set a value of 5 to 10 seconds over the time taken by the gate to travel from the closing limit-switch to the opening limit-switch and vice versa. to sec. in oneAdjustable from second steps. Subsequently, display changes to minutes and tens of seconds (separated by a point) and time is adjusted in 10 second steps, up to a maximum value of minutes. Attention: the set value does not exactly match the motor's maximum operating time, because the latter is modified according to the performed deceleration spaces. ASSISTANCE REQUEST (combined with next function): to = Encoder active and from sensitivity adjustment = Encoder disabled If activated, at the end of countdown (settable with the next function i.e. "Cycle programming") it effects 2 sec. (in addition to the value already set with the PF function) of pre-flashing at every Open pulse (job request). Can be useful for setting scheduled maintenance jobs. = Active = Disabled Pre-limit switch DECELERATION: You can select gate deceleration before the opening and closing limit-switches have been tripped. Time can be adjusted from to in 0.1-second steps. If an encoder is used, the adjustment is not determined by time but by motor revs, thus obtaining greater deceleration precision. CYCLE PROGRAMMING: For setting countdown of system operation cycles. Settable (in thousands) from to thousand cycles. The displayed value is updated as cycles proceed. This function can be used to check use of the board or to exploit the "Assistance request". = Deceleration disabled from to = Deceleration enabled Post-limit switch DECELERATION: GATE STATUS: Exit from programming, data saving, and return to viewing gate status (see par. 5.5.1.). You can select gate deceleration after the opening and closing limit-switches have been tripped. Time can be adjusted from to in 0.1-second steps. If an encoder is used, the adjustment is not determined by time but by motor revs, thus obtaining greater deceleration precision. from Default Note 1: to reset the programming default settings, check if the edge input is closed (SAFE LED ON), and simultaneously press keys +, - and F, holding them down for 5 seconds. = Deceleration disabled to = Deceleration enabled Note 2: modification of programming parameters comes into effect immediately, whereas definitive memory storage occurs only when you exit programming and return to gate status viewing. If the equipment is powered down before return to status viewing, all modifications will be lost. 29 Attention: due to the powerful magnetic fields the supplied magnets produce, the magnets can damage magnetic band components (credit cards, magnetic tapes, floppy disks, etc) and electronic and mechanical equipment (e.g. watches, LCD screens). We advise you not to bring them near to objects that could be damaged if 'immersed' in a magnetic field. 6. START-UP 6.1. ELECTRIC CONNECTIONS Make all electrical connections to the board as in chapter 5, including earthing of the operator (Fig. 40). Notes on magnet positioning • • Fig. 40 6.2. • DEFINITION OF OPENING DIRECTION AND OPERATION OF LIMIT-SWITCH LEDS Power up the system and set the opening direction on the board (see par. 5.5.1). If opening direction is RIGHTWARD ( To ensure correct operation, allow at least 2 cm from the mechanical stop limit in the gate stop position. Carry out this check after determining the values of the pre- and post-limit switch decelerations (see par. 5.5.2.) and after running at least one complete cycle of the automated system. The distance between the limit-switch and magnets must be from 5 to 12 mm. Magnets should be fitted on the rack and not on the fixing screws. If necessary, position the magnet at the side of the screw and adjust decelerations (parag. 5.5.2) in order to obtain the correct stop point. FC1 ): OPENING limit-switch LED = F C 1 CLOSING limit-switch LED = F C 2 If opening direction is LEFTWARD ( ): OPENING limit-switch LED = F C 2 FC2 CLOSING limit-switch LED = F C 1 6.3. DETERMINING THE STOP POINTS AT TRAVEL LIMIT Operator 746 has a limit sensor switch which, by detecting the transit of a reference applied to the rack, commands the gate motor to stop. The device can be MLS (fig. 41) or inductive (fig. 42). 6.3.1. 1 2 MLS limit-switch The MLS limit sensor switch detects the transit of two magnets fitted on the side of the rack facing the operator. Procedure for correct positioning of the two supplied magnets: 1) Check if the operator is in manual mode (see chapter 8). 2) Manually take the gate to opening position, leaving 2 - 5 cm from the travel limit mechanical stop. 3) Fit the magnet (without removing the protective film from the adhesive side) on the side of the rack facing the operator, aligning the upper edges. Slide the magnet on the rack in opening direction until the relevant LED goes off (Fig. 22 and 41), then move the magnet forward a further 45 mm. 4) Manually take the gate to closing position, leaving 2 - 5 cm from the travel limit mechanical stop. 5) Fit the magnet (without removing the protective film from the adhesive side) on the side of the rack facing the operator, aligning the upper edges. Slide the magnet on the rack in closing direction until the relevant LED goes off (Fig. 22 and 41), then move the magnet forward by about a further 45 mm. 6) Take the gate to its halfway travel point and relock the system (see chapter 9). 7) Find out the desired pre- and post-limit-switch deceleration values (see parag. 5.5.2) and run the automated system for at least one complete cycle. 8) Check if the gate stops at about 2 - 5 cm from its mechanical stop point. If necessary, correct the position of the magnets and check if the stop point is correct. 9) Mark the position of the magnets on the rack, and remove them. 10) Clean the rack on its fitting points, remove the film on the adhesive parts of the magnets (fig. 41 ref. 1) and re-position the magnets with the adhesive strip in contact with the rack (fig. 41 ref. 2). 6.3.2. Fig. 41 Inductive limit-switch Operator 746 has an inductive limit-switch which detects the transit of the two steel plates fitted on the top of the rack. Procedure for correct positioning of the two supplied steel plates: 1) Assemble the limit-switch by centring the plate with respect to threaded pins of the support (Fig. 42). 2) Check if the operator is in manual operating mode (see chapter 8). 3) Manually move the gate to opening position, allowing 2 - 5 cm from the mechanical stop limit. 4) Allow the plate to move on the rack in opening direction until the relevant LED goes OFF (Figs. 22 and 42); next, move the plate forward by about another 45 mm and secure it to the rack by tightening the screws. 5) Manually move the gate to closing position, allowing 2 - 5 cm from the mechanical stop limit. 6) Allow the plate to move on the rack in closing direction until the relevant LED goes OFF (Figs. 22 and 42); next, move the plate forward by about another 45 mm and secure it to the rack by tightening the screws. FC1 FC2 Fig. 42 30 Notes on plate positioning • • • To reduce torque, turn the screw anti-clockwise. Ü The operator is supplied with the clutch set to maximum level. Therefore, you must initially turn the screw anti-clockwise to reach the best setting. To ensure correct operation, allow at least 2 cm from the mechanical stop limit in the gate stop position. Carry out this check after determining the values of the pre- and post-limit switch decelerations (see par. 5.5.2.) and after running at least one complete cycle of the automated system. The distance between the limit-switch and the plates must be < 5mm. For nylon racks, use the plate only (without support), securing it directly to the rack by the self-tapping screws. Make the above mentioned adjustments. Note: a steel core is situated 5 mm under the surface of the nylon rack. Therefore, drill until you reach the steel core and screw with the self-tapping screws. 3) Power up the automated system and check that the torque you have just set is correct. Fig. 44 6.7. 6.4. CHECK OF INPUTS The table below shows the status of the LEDs in relation to to the status of the inputs. Note the following: LED LIGHTED = closed contact LED OFF = open contact Check the status of the LEDs as per Table. Tab. 2 Operation of the signalling status LEDs LEDS OP-A OP-B FC1 FC2 FSW OP FSW CL STOP SAFE ENC LIGHTED Command activated Command activated Limit-switch free Limit-switch free Safety devices disengaged Safety devices disengaged Command inactive Safety devices disengaged Flashes while the motor rotates OFF Command inactive Command inactive Limit-switch engaged Limit-switch engaged Safety devices engaged Safety devices engaged Command activated Safety devices engaged 6.8. 7. FINAL OPERATIONS At end of installation, apply the danger sticker on the top of the cover (Fig. 45). Fig. 45 CHECK OF MOTOR CONNECTION Check if the motor wiring is as shown in Fig. 43 (standard connection). MOT 2 MOT 1 MOT COM BROWN BLACK BLUE J6 6.6. SAFETY DEVICES AND ACCESSORIES CHECK Check correct operation of all the safety and anti-crushing devices (ENCODER sensor), and of the accessories used on the system. NB.: The status of the LEDs while the gate is closed at rest are shown in bold. If opening direction is leftward, the status of LEDS FC1 and FC2 is reversed. 6.5. CHECK OF STOP POINTS Take care over the setting of the post-limit-switch deceleration and braking: If deceleration is too long and braking is insufficient, the reference fitted on the gate's rack (magnet or steel plate) can overtake the sensor until the latter is disengaged. When the gate stops, check if only the limit-switch involved is engaged. The relevant LED must be OFF - if it went OFF and then ON again, or if both the limit-switch LEDS are OFF, you must reduce the post-limit-switch deceleration value and/or increase braking value (see par.5.5.2). Snap-fit the side panels, fit the equipment's cover and fit the cover with the supplied screws (Fig. 46). M Remove the vent stop screw (fig. 47). Hand the "User's Guide" to the Customer, explain correct operation and use of the gearmotor, and indicate the potentially dangerous areas of the automated system. Fig. 43 ADJUSTMENT OF MECHANICAL CLUTCH In addition to its electronic safety devices (encoder and force adjustment), the 746 operator is also equipped with a mechanical clutch. For gate force and the encoder, please consult paragraphs 5.5.1 and 5.5.2. Procedure for adjusting the operating threshold of the mechanical clutch (you are recommend to set it to conform with current regulations): 1) 2) Cut electrical power to the automated system. Keep the motor shaft locked with a wrench and turn the clutch adjustment screw with an Allen wrench or screwdriver as shown in Fig. 44. To increase torque, turn the screw clockwise. Fig. 46 31 Fig. 50 Fig. 47 12.MAINTENANCE Check the operational efficiency of the system at least once every 6 months, especially as regards the efficiency of the safety and release devices (including operator thrust force). 8. MANUAL OPERATION If the gate has to be operated manually due to a power cut or malfunction of the automated system, use the release device as follows: 1) Open the protection door and fit the supplied key in the lock (Fig. 48). 12.1. DISASSEMBLING THE TRANSFORMER-BOARD UNIT If you have to disassemble the transformer-board unit, proceed as follows: Remove all terminal boards and connectors from the board. Unscrew the 3 securing screws of the board and the 2 of the transformer. Lift the unit up and gently remove the transformer from the couplings on the board as shown in Fig. 51. Fig. 48 2) 3) Turn the key clockwise and pull the release lever as shown in Fig. 49. Open and close the gate manually. Fig. 51 12.2. OIL TOP-UPS Periodically check oil level inside the operator. A once-a-year check is enough for medium or low use frequency. For heavier duty, every 6 months is recommended. To access the tank, temporarily remove the oil filling plug (Fig. 52). Oil level (visually checked) must be in line with the copper windings of the electric motor. To top up, pour in oil up to the required level. Use FAAC XD 220 oil only. Fig. 49 9. RESTORING NORMAL OPERATION To prevent an involuntary pulse from activating the gate during the manoeuvre, cut power to the system before re-locking the operator. 1) Re-close the release lever. 2) Turn the key anti-clockwise 3) Remove the key and close the lock protection door. 4) Move the gate until the release meshes. 10.INSTALLING THE CN 60E CONTROL UNIT (OPTIONAL) The operator is designed to house (with the aid of a DIN bar) the CN 60E control unit of the safety conductive edge. Cut the DIN bar to measure and secure it to the operator with two screws in the appropriate holes and attach the CN 60E control unit to it (Fig. 50). For connection and operation, refer to the specific instructions. 11.SPECIAL APPLICATIONS Fig. 52 There are no special applications. 13.REPAIRS For any repairs, contact the FAAC authorised Repair Centres. 32 33 No effect (1) (3) Closes the leaf (3) OPENING LOCKED Stops operation (3) Closes the leaf (with Closing Safety devices engaged, opens at the 2nd pulse) (3) OPENING LOCKED Closes the leaf (3) LOCKED Re-opens the leaf immediately Stops operation (3) Closes the leaf (with Closing Safety devices engaged, opens at the 2nd pulse) (3) CLOSING OPENING LOCKED Opens leaf for the partial opening time Re-closes the leaf immediately (3) Opens the leaf CLOSED OPEN OPEN-A Logic "E" GATE STATUS OPEN-B Re-closes the leaf immediately (3) OPENING Tab. 3/d Re-opens the leaf immediately CLOSING Opens the leaf and closes it after pause time CLOSED Re-closes the leaf immediately (3) Opens leaf for the partial opening time and closes after pause time OPEN on PAUSE OPEN-B OPEN-A GATE STATUS Logic "S" Tab. 3/c Re-opens the leaf immediately CLOSING CLOSED Stops operation (3) Opens leaf for the partial opening time and closes after pause time Opens the leaf and closes it after pause time OPEN on PAUSE OPEN-B OPEN-A GATE STATUS Logic "AP" Tab. 3/b Re-opens the leaf immediately (1) CLOSING CLOSED Reloads pause time (1)(3) Opens leaf for the partial opening time and closes after pause time (1) Opens the leaf and closes it after pause time (1) OPEN on PAUSE OPEN-B OPEN-A GATE STATUS Logic "A" Tab. 3/a No effect (OPEN disabled) Stops operation STOP No effect (OPEN disabled) Stops operation STOP No effect (OPEN disabled) Stops operation STOP No effect (OPEN disabled) Stops operation STOP PULSES No effect CLOSING SAFETY DEVICES see paragraph 5.5.2. No effect (saves OPEN) No effect No effect (if on part.opng. OPEN A disabled) No effect (OPEN disabled) OPENING SAFETY DEVICES Reverses to close for 2" (2) Reverses to close for 2" (2) Locks and, on release, continues opening No effect see paragraph 5.5.2. Reverses to close for 2" (2) Reverses to open for 2" (2) Reloads pause time (1) (OPEN disabled) EDGE SAFETY DEVICE Reverses to close for 2" (2) Locks and, on release, continues opening No effect (OPEN disabled) Reverses to open for 2" (2) Locks and, on release, reverses to open No effect (OPEN disabled) No effect (OPEN disabled) OP/CL SAFETY DEVICE No e f f e c t OPEN disabled) Locks and, on release, continues opening On release, closes after 5" (OPEN disabled) No effect (saves OPEN) No effect (3) (OPEN disabled) EDGE SAFETY DEVICE No effect (OPEN disabled) OP/CL SAFETY DEVICE No effect (OPEN disabled) Reverses to open for 2" (2) Locks and, on release, reverses to open Reloads pause time (OPEN disabled) Reloads pause time (OPEN disabled) EDGE SAFETY DEVICE No effect (OPEN disabled) OP/CL SAFETY DEVICE No e f f e c t (OPEN disabled) Reverses to open for 2" (2) Locks and, on release, continues opening Reloads pause time (1) (OPEN disabled) Locks and, on release, reverses to open Reloads pause time (1) (OPEN disabled) Locks and, on release, reverses to open No effect EDGE SAFETY DEVICE No effect (OPEN disabled) OP/CL SAFETY DEVICE see paragraph 5.5.2. CLOSING SAFETY DEVICES No effect PULSES see paragraph 5.5.2. No effect (saves OPEN) No effect On release, closes after 5" (OPEN (if on part.opng. OPEN A disabled) disabled) (3) No effect (OPEN disabled) OPENING SAFETY DEVICES No effect see paragraph 5.5.2. Reloads pause time (3) (OPEN disabled) No effect CLOSING SAFETY DEVICES No effect PULSES see paragraph 5.5.2. No effect (saves OPEN) No effect (if on part.opng. OPEN A disabled) No effect (OPEN disabled) OPENING SAFETY DEVICES No effect see paragraph 5.5.2. Reloads pause time (1) (3) No effect CLOSING SAFETY DEVICES No effect PULSES see paragraph 5.5.2. No effect (saves OPEN) No effect (if on part.opng. OPEN A disabled) No effect (OPEN disabled) OPENING SAFETY DEVICES 34 PULSES Stops operation / CLOSING OPENING No effect Reverses to open No effect Opens the leaf OPEN CLOSING OPENING LOCKED Opens the leaf No effect Reverses to open No effect Opens the leaf CLOSED OPEN CLOSING OPENING LOCKED Closes the leaf No effect No effect Closes the leaf No effect OPEN-B (closing) No effect (OPEN A/B disabled) Stops operation No effect (OPEN B disabled) STOP No effect (OPEN A/B disabled) Stops operation No effect (OPEN B disabled) STOP Stops operation No effect (OPEN-A/B disabled) STOP (1) If maintained, it prolongs the pause until disabled by the command (timer function) (2) If a new pulse occurs within 2 seconds after reversing, it immediately stops operation. OPEN-A (opening) GATE STATUS Logic "B/C" Closes the leaf No effect No effect Closes the leaf No effect OPEN-B (closing) Stops operation OPENING PULSE/CLOSING HOLD TO RUN CONTROLS Opens the leaf CLOSED Tab. 3/h OPEN-A (opening) GATE STATUS Logic "B" Tab. 3/g Closes the leaf No effect (OPEN-B disabled) OPEN / No effect (OPEN-A disabled) Opens the leaf CLOSED OPEN-B (closing) OPEN-A (opening) Logic "C" GATE STATUS CONTROLS ALWAYS HELD DOWN Stops operation (OPEN-A disabled) No effect Stops operation (OPEN-A disabled) EDGE SAFETY DEVICE Reverses to close for 2" (2) Locks and, on release, continues opening EDGE SAFETY DEVICE EDGE SAFETY DEVICE Reverses to close for 2" (2) Reverses to open for 2" (2) No effect (OPEN-A/B disabled) Reverses to close for 2" (2) Reverses to open for 2" (2) No effect (OPEN-A/B disabled) EDGE SAFETY DEVICE Reverses to close for 2" (2) Reverses to open for 2" (2) No effect (OPEN-A/B disabled) No effect (OPEN A/B disabled) Stops operation (OPEN-A/B disabled) No effect (OPEN B disabled) No effect (OPEN A disabled) OP/CL SAFETY DEVICE No effect (OPEN A/B disabled) Stops operation (OPEN-A/B disabled) No effect (OPEN B disabled) No effect (OPEN A disabled) OP/CL SAFETY DEVICE Stops operation (OPEN-A/B disabled) No effect (OPEN B disabled) No effect (OPEN A disabled) OP/CL SAFETY DEVICE No effect (OPEN disabled) Reverses to open for 2" (2) Locks and, on release, reverses to open No effect (OPEN disabled) No effect (OPEN disabled) OP/CL SAFETY DEVICE (3) During the partial opening cycle, an OPEN A pulse causes total opening. NB.: Effects on other active pulse inputs in brackets. No effect (OPEN B disabled) Stops operation (OPEN-B disabled) No effect (saves OPEN A) No effect (OPEN-A disabled) No effect (OPEN B disabled) No effect CLOSING SAFETY DEVICES No effect No effect (OPEN A disabled) OPENING SAFETY DEVICES PULSES No effect (OPEN B disabled) No effect No effect (saves OPEN A) No effect (OPEN-A disabled) Stops operation (OPEN-B disabled) No effect No effect No effect (OPEN B disabled) No effect (OPEN A disabled) OPENING SAFETY DEVICES CLOSING SAFETY DEVICES No effect Stops operation (OPEN-A disabled) PULSES Stops operation (OPEN-B disabled) No effect (OPEN B disabled) No effect CLOSING SAFETY DEVICES PULSES No effect (if it must close, it disables OPEN) No effect see paragraph 5.5.2. No effect (OPEN disabled) (3) No effect CLOSING SAFETY DEVICES No effect No effect (OPEN A disabled) No effect (OPEN A disabled) OPENING SAFETY DEVICES LOCKED Tab. 3/f No effect (if it must open, it disables OPEN) Restarts movement in reverse direction (3) (always closes after a Stop) OPENING No effect (OPEN disabled) see paragraph 5.5.2. Stops operation No effect (saves OPEN) No effect (if on part.opng. OPEN A disabled) No effect (OPEN disabled) OPENING SAFETY DEVICES Stops operation (3) Stops operation STOP CLOSING Re-closes the leaf immediately (3) Opens the leaf CLOSED Opens leaf for the partial opening time OPEN-B OPEN OPEN-A GATE STATUS Logic "EP" Tab. 3/e
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Key Features
- Electro-mechanical operator
- Non-reversing system
- Adjustable anti-crushing safety
- Manual release
- Electronic control equipment