Yamaha SRCD User`s manual

SRCD/SRCP
YAMAHA NETWORK BOARD ERCX/SRCX/DRCX
CC-Link
User’s Manual
ENGLISH
E
YAMAHA MOTOR CO., LTD.
IM Operations
882 Soude, Naka-ku, Hamamatsu, Shizuoka 435-0054.Japan
URL http://www.yamaha-motor.jp/robot/index.html
E70-Ver. 5.02
INTRODUCTION
Thank you for purchasing the CC-Link unit for the YAMAHA single-axis/dual-axis robot
controllers SRCP/SRCD/ERCX/SRCX/DRCX series.
This is an optional unit to allow connecting YAMAHA single-axis/dual-axis robot
controllers SRCP/SRCD/ERCX/SRCX/DRCX series (hereafter called "controller") to
the widely used CC-Link which is a de facto standard for FA (factory automation) field
network.
This manual describes typical examples for taking safety measures, installing wiring,
making machine settings and operating the machine to ensure that the CC-Link unit is
used safely and effectively. After reading this manual keep it in a safe, easily accessible
location, so it can be referred to whenever needed. When moving this unit, always make
sure this manual accompanies it, and make sure that the person who will actually use this
CC-Link unit reads this manual thoroughly.
This manual only contains information involving the CC-Link unit. Please refer to the
controller user’s manual for information about basic controller operation and
programming, etc.
The HPB screen displays in this manual are for the DRCX series controllers (hereafter
called "dual-axis controller") and so may differ somewhat from the HPB screen display
for the SRCP/SRCD/ERCX/SRCX series controllers (hereafter called "single-axis
controller"). Please note that this will cause no problem with the functions of the controller
or CC-Link unit.
! CAUTION
• The contents of this manual may be changed in advance without prior notice.
• Every effort was made to ensure the contents of this manual are complete, however please contact us if errors, ambiguities or possible trouble points are found.
• This manual does not constitute a warranty of industrial rights or other rights
nor a concession of utility rights. Further, no responsibility whatsoever is accepted for problems arising from use of the information contents listed in this
manual.
MEMO
Contents
Cautions To Ensure Safety ............................................................1
1-1
1-2
1-3
1-4
1-5
1-6
CC-Link Unit
2-1
2-2
2-3
2-4
2-5
Basic safety points ............................................................................. 2
System design safety points .............................................................. 2
Installation and wiring safety points ................................................... 3
Start-up and maintenance safety points............................................. 4
Precautions when disposing of the unit .............................................. 4
Warranty ............................................................................................. 5
................................................................................7
CC-Link unit features ......................................................................... 8
CC-Link system concept .................................................................... 9
CC-Link cable connections .............................................................. 10
Parallel I/O connector ....................................................................... 11
Controller system settings (remote station) ...................................... 13
2-5-1
2-5-2
2-5-3
Validating the CC-Link unit ........................................................... 13
Setting the station No. .................................................................. 14
Setting the communication speed ................................................ 15
2-6 Sequencer (master station) settings ................................................ 16
2-6-1
Starting data exchange with the controller ................................... 16
2-7 I/O information .................................................................................. 17
2-7-1
2-7-2
2-7-3
2-7-4
2-7-5
2-7-6
2-7-7
2-7-8
2-7-9
2-7-10
2-7-11
2-7-12
Profile (I/O signal table) ................................................................ 17
Dedicated command inputs .......................................................... 19
General-purpose inputs (SI200 - SI231) ...................................... 23
Interlock (LOCK) .......................................................................... 24
Emergency stop input (EMG) ....................................................... 24
Service mode (SVCE) .................................................................. 25
Initial data processing end flag..................................................... 25
Dedicated outputs ........................................................................ 26
General-purpose outputs (SO200 - SO231) ................................ 27
Initial data processing request flag ............................................... 28
Remote READY ........................................................................... 28
Error flag ...................................................................................... 28
2-8 Timing chart...................................................................................... 29
2-8-1
2-8-2
2-8-3
2-8-4
2-8-5
2-8-6
Handshake for starting data exchange ........................................ 29
Dedicated input command execution ........................................... 30
When interlock signal is input ....................................................... 34
When emergency stop signal is input .......................................... 35
When an alarm is issued .............................................................. 36
When point movement commands are run .................................. 37
2-9 I/O assignment change function ....................................................... 38
2-9-1
2-9-2
2-9-3
2-9-4
Changing the I/O assignment....................................................... 38
I/O assignment list........................................................................ 39
I/O assignment selection parameter description .......................... 41
I/O signal descripion ..................................................................... 43
2-9-5
Timing chart ................................................................................. 48
2-10 Robot language ................................................................................ 58
2-10-1
2-10-2
2-10-3
2-10-4
2-10-5
MOVF ........................................................................................... 58
JMPF ............................................................................................ 59
JMPB ............................................................................................ 60
DO ................................................................................................ 60
WAIT ............................................................................................ 61
2-11 Emulated Serialization on parallel DIO ............................................ 62
2-12 Remote command ............................................................................ 64
2-12-1
2-12-2
2-12-3
2-12-4
2-12-5
2-12-6
2-12-7
2-12-8
2-12-9
Remote command specifications ................................................. 64
Remote command & status value list ........................................... 65
Remote command details (robot operation) ................................. 69
Remote command details (data handling) ................................. 103
Remote command details (utilities) ............................................ 126
Remote command details (Special commands) ......................... 130
Status details .............................................................................. 131
Current position indication mode ................................................ 132
Sending/receiving example ........................................................ 133
2-13 Other operations ............................................................................ 134
2-13-1 Serial I/O display ........................................................................ 134
2-13-2 Manual control of general-purpose output ................................. 137
2-14 Error Message ................................................................................ 138
2-15 Troubleshooting.............................................................................. 139
2-16 Specifications ................................................................................. 141
CHAPTER
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1
Cautions To Ensure Safety
CHAPTER1 Cautions To Ensure Safety
1-1
Basic safety points
Besides reading this instruction manual and the controller user’s manual, also be sure to
handle the equipment correctly while paying sufficient attention to safety.
Points regarding safety in this instruction manual only list items involving this product.
Please refer to the controller instruction manual for information regarding safety when
using this unit with the controller.
It is not possible to detail all safety items within the limited space of this manual. So it is
essential that the user have a full knowledge of basic safety rules and also that the operator makes correct judgments on safety procedures during operation.
Industrial robots are highly programmable, mechanical devices that provide a large degree of freedom when performing various manipulative tasks. Failure to take necessary
safety measures or mishandling due to not following the instruction in this manual may
result in trouble or damage to the robot and injury to personnel (robot operator or service
personnel) including fatal accidents.
Important caution points in this manual are from hereon indicated by the term:
! CAUTION
1-2
System design safety points
! CAUTION
When communication errors occur in the CC-Link system, check the status of the
network system and the controller beforehand by referring to the CC-Link
instruction manual and this instruction manual. Also use this communication status information to contrive circuits and interlocks in the sequence program so that
the system including the controller will operate safely.
! CAUTION
Emergency stop signals may sometimes interrupt register operation in the CCLink unit, however this is merely a software control process and is in no way a
problem. Therefore, we strongly advise contriving a hardware interlock circuit
connected to the emergency stop pin contacts in the parallel I/O of the controller.
! CAUTION
Do not bundle control lines or communication cables together or in close contact
with main circuit or motor/actuator lines. As a general rule, maintain a gap of at
least 100mm. Noise in signal lines may cause faulty operation.
2
CHAPTER1 Cautions To Ensure Safety
1-3
Installation and wiring safety points
! CAUTION
Always cut off all power to the controller and the overall system before attempting
installation or wiring jobs. This will prevent possible electrical shocks.
After the controller has been on for a while, some points in the controller may be
extremely hot or remain at high voltages. After cutting off the power when installing or removing the unit, wait at least 5 minutes before starting work.
! CAUTION
Always uses the system specifications as listed in the controller instruction manual
during installation or wiring work on the controller. Attempting to use other than
these system specifications might cause electrical shocks, fire, faulty operation,
product damage or deteriorated performance.
! CAUTION
Securely install the connectors into the unit, and when wiring the connectors, make
the crimp, contact or solder connections correctly, using the tool specified by the
manufacturer. Poor connections will cause faulty operation.
! CAUTION
When installing the unit, be careful not to directly touch any electronic components (except DIP switches) or parts conducting electrical current.
! CAUTION
Make sure that foreign matter such as wiring debris or dust does not penetrate
into the controller.
! CAUTION
Always store network cable inside cable ducts or clamp them securely in place.
Otherwise, excessive play or movement, or mistakenly pulling on the cable may
damage the unit or cables, or poor cable contact may lead to faulty operation.
! CAUTION
When detaching the cable, remove by holding the connector itself and not by tugging on the cable. Otherwise, removing by pulling on the cable itself may damage
the unit or cables, or poor cable contact may lead to faulty operation.
3
CHAPTER1 Cautions To Ensure Safety
1-4
Start-up and maintenance safety points
! CAUTION
Never attempt to disassemble the robot or controller. When a robot or controller
component must be repaired or replaced, contact us for details on how to perform
the servicing.
! CAUTION
Always cut off all power to the controller and the overall system before attempting
maintenance or servicing. This will prevent possible electrical shocks.
After the controller has been on for a while, some points in the controller may be
extremely hot or remain at high voltages. After cutting off the power when installing or removing the unit, wait at least 5 minutes before starting work.
! CAUTION
Do not touch the terminals (or pins) while power is still applied to the unit. This
may cause electrical shocks or faulty operation.
1-5
Precautions when disposing of the unit
! CAUTION
This product must be properly handled as industrial waste when its disposal is
required.
4
CHAPTER1 Cautions To Ensure Safety
1-6
Warranty
For information on the warranty period and terms, please contact our distributor where
you purchased the product.
This warranty does not cover any failure caused by:
1. Installation, wiring, connection to other control devices, operating methods,
inspection or maintenance that does not comply with industry standards or
instructions specified in the YAMAHA manual;
2. Usage that exceeded the specifications or standard performance shown in the
YAMAHA manual;
3. Product usage other than intended by YAMAHA;
4. Storage, operating conditions and utilities that are outside the range specified in
the manual;
5. Damage due to improper shipping or shipping methods;
6. Accident or collision damage;
7. Installation of other than genuine YAMAHA parts and/or accessories;
8. Modification to original parts or modifications not conforming to standard
specifications designated by YAMAHA, including customizing performed by
YAMAHA in compliance with distributor or customer requests;
9. Pollution, salt damage, condensation;
10. Fires or natural disasters such as earthquakes, tsunamis, lightning strikes, wind
and flood damage, etc;
11. Breakdown due to causes other than the above that are not the fault or
responsibility of YAMAHA;
The following cases are not covered under the warranty:
1. Products whose serial number or production date (month & year) cannot be
verified.
2. Changes in software or internal data such as programs or points that were created
or changed by the customer.
3. Products whose trouble cannot be reproduced or identified by YAMAHA.
4. Products utilized, for example, in radiological equipment, biological test
equipment applications or for other purposes whose warranty repairs are judged
as hazardous by YAMAHA.
THE WARRANTY STATED HEREIN PROVIDED BY YAMAHA ONLY COVERS
DEFECTS IN PRODUCTS AND PARTS SOLD BY YAMAHA TO DISTRIBUTORS
UNDER THIS AGREEMENT. ANY AND ALL OTHER WARRANTIES OR
LIABILITIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY
IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A
PARTICULAR PURPOSE ARE HEREBY EXPRESSLY DISCLAIMED BY YAMAHA.
MOREOVER, YAMAHA SHALL NOT BE HELD RESPONSIBLE FOR
CONSEQUENT OR INDIRECT DAMAGES IN ANY MANNER RELATING TO THE
PRODUCT.
Ver.1.00_201205
5
MEMO
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2
CC-Link Unit
CHAPTER2 CC-Link Unit
2-1
CC-Link unit features
The term “CC-Link” is an abbreviation for “Communication & Control Link” and is an
FA field network developed by the Mitsubishi Corporation.
The PLC (sequencer), the master unit in the system, runs the controller under high speed
control though dedicated cables connected to all units in the CC-Link system. This system eliminates the need for a great deal of wiring and therefore makes wiring tasks faster
and more efficient and also reduces maintenance and installation costs.
Main features of this CC-Link unit are as follows:
■ The controller can be connected to the CC-Link system using this unit. This unit
fits directly inside the controller and so does not require any extra installation space.
■ The PLC is connected to the robot system using only one dedicated cable (with 4
wires). This allows the entire system wiring to be reduced and also makes wiring
tasks faster and more efficient while reducing maintenance and installation costs.
■ A total of 32 general-purpose input/output pins and 16 dedicated input/output pins
are available (per 2 stations). The parallel I/O interface can of course be used as is.
■ Emulated serialization on parallel I/O is available
All types of I/O equipment, such as sensors and relays, connected to the parallel I/
O of the controller can be controlled from the PLC (sequencer) just as if connected
to the I/O of the CC-Link system and without using a robot program.
■ When the remote register is used, the message (remote command) can be issued
directly from the sequencer (PLC). The high-ranked commands such as MOVD
command (movement command which directly specifies the position coordinates),
which must use RS-232C unit conventionally, can be easily executed.
Refer to the particular service manual involved when detailed information on connecting
to the master station PLC (sequencer) or on PLC (sequencer) programs is needed when
using other equipment.
Refer to the controller instruction manual for information involving operating the controller unit and on robot programming.
*CC-Link is a registered trademark of the Mitsubishi Corporation.
8
CHAPTER2 CC-Link Unit
2-2
CC-Link system concept
In order to understand how the controller and sequencer (PLC) operate on the CC-Link
system, let’s first take a look at how the system communicates.
Each equipment connected in the CC-Link system is classified according to function as
a master station, remote device station, remote I/O station, etc. The master station is a
station for supervising the entire CC-Link system and can be considered the PLC (sequencer) master unit. The remote device station is controlled by the master station, and
exchanges bit data and word data with the master station. The remote I/O station, like the
remote device station is also controlled by the master station but differs from the remote
device station in that the only data it handles is bit data.
The controllers equipped with the CC-Link unit function as remote device stations.
Master Station
This station controls the entire CC-Link system.
This is equivalent to a master sequencer (PLC) unit.
q
Remote Device
Station
Remote I/O
Station
This station is controlled
in the CC-Link system by
the master station.
This station is controlled
in the CC-Link system by
the master station.
w
Controllers
+
CC-Link unit
These function as remote device
stations.
q The controller on/off information is sent to the master station via the information
network (CC-Link system cable). Moreover, the response from the controller against
the message (remote command) is also similarly sent to the master station via the
network.
w Master station sequencer (PLC) on/off information is sent to the controller via the
information network (CC-Link system cable). Moreover, the message (remote command) from the master station is also similarly sent to the master station via the
network.
* The controller monitors the on/off information and message (remote command) at
10 millisecond intervals.
MEMO
Communication speed and station numbers are set from the HPB.
ON/OFF information handled by the CC-Link unit comes through 32 general-purpose I/
O pins and 16 Dedicated I/O pins (for 2 stations).
ON/OFF information in the robot program is handled by DO statements, WAIT statements, and JMPB statements. (Serial input/outputs (I/O) for the CC-Link are assigned
using I/O numbers from 200 onwards.) Designated I/O ports can be controlled independently of the program by making emulated serialization settings on the parallel I/O.
9
CHAPTER2 CC-Link Unit
2-3
CC-Link cable connections
Wire the CC-Link cable to the accessory CC-Link plug. Make the wiring connections by
referring to the drawing below or the marks on the plug. Make sure the connections are
correct! When finished wiring the cable to the plug, connect it to the CC-Link connector
as shown below.
1. DA (blue)
2. DB (white)
3. DG (yellow)
4. SLD (shield wire)
1 2 3 4 5
CC-Link plug
MSTB2, 5/5-STF-5, 08
Phoenix Contact
This is black
on the controller side.
5. FG
CC-Link cable
CC-Link connector
Controller
Fig. 2-1 CC-Link cable wiring
* The SLD line connects to controller ground internally inside the controller so there is
no connection to pin 5 (FG) on the CC-Link connector. There is no need to make a
connection to pin 5 on the normal connector but a ground wire can be connected to this
pin if the customer wants a more secure frame ground connection.
(Pins 4 and 5 should be connected in the connector in this case.)
! CAUTION
Always cut off the power before making the above connections.
Clamp the cable in place so it will not come loose.
Be sure to put an excessive pulling or weight load on the cable when wiring or
installing.
There are limits on the total cable length and the cable length between stations so
always consult the instruction manual for the master station sequencer (PLC).
MEMO
This CC-Link unit is compatible with CC-Link Ver. 1.10. Using a CC-Link cable compatible with Ver. 1.10 eases restrictions such as on cable length between stations. Please
refer to the instruction manual for the master station sequencer (PLC) for further details.
10
CHAPTER2 CC-Link Unit
2-4
Parallel I/O connector
The I/O connector must be wired into the controller so install as shown below even if not
using the controller’s parallel I/O.
■ When the ERCX/SRCX/DRCX series controllers are used:
1. Short Pin No. A-24 (EMG 1) and B-24 (EMG 2).
2. Short Pin No. B-4 (LOCK) and A-15, to B-15 (0V).
3. Connect an external 24 volts to Pin No. A-13, B-13 (+IN COM).
(On DRCX and SRCX you can connect to A-14, B-14 (+24V) and to A13, B-13 (+IN COM) instead of connecting to an external 24 volt supply.
If Step 1 is not completed, an emergency stop will occur. If Step 2 is not completed, an
interlock will be applied. In either case, the controller cannot be operated (see Chapter
4).
Note that 24 volt power will not be supplied to the I/O circuit unless shorted as in 3.
An alarm is issued (06:24V POWER OFF) when power is not supplied and the operation disabled.
Please refer to “I/O Interface” in the controller instruction manual for detailed information on parallel I/O operation.
Row B, No. 1
Row B
Row A, No. 1
Row A
The register in the CC-Link unit has an emergency stop input however this is just
for control by the software and is not by itself totally adequate. So installing an
interlock circuit for emergency stop using the above mentioned A-24 (EMG1) and
B-24 (EMG2) is recommended.
11
CHAPTER2 CC-Link Unit
■ When the SRCP/SRCD series is used:
1. Short Pin No. 1 (EMG 1) and Pin No. 2 (EMG 2) of the EXT.CN connector.
2. Short Pin No. B-4 (LOCK) of the I/O.CN connector and Pin No. 4 (24G) of
the EXT.CN connector.
(This wiring can be eliminated by disabling bit 6 (Interlock function setting) of PRM34 (System mode selection).)
3. Connect Pin No. 3 (24V) and Pin No. 4 (24G) of the EXT.CN connector
to an external 24 volt supply.
If Step 1 is not completed, an emergency stop will occur. If Step 2 is not completed, an
interlock will be activated. The robot cannot move in either case. Also note that 24
volt power will not be supplied to the I/O circuit unless connected as in Step 3. An
alarm is issued (06:24V POWER OFF) and the operation is disabled.
Refer to “I/O Interface” in the controller user's manual for detailed information on
parallel I/O operation.
← Left: I/O.CN connector pin layout
↓ Below: EXT.CN connector pin layout
3
4
Slotted screwdriver
2
B20
B19
•
•
•
•
•
•
•
•
•
•
•
B3
B2
B1
Terminal numbers are not actually
indicated, but designated from 1 to
4, from the left as viewed from the
front (wire insertion side) as shown
in the drawing.
1
A20
A19
•
•
•
•
•
•
•
•
•
•
•
A3
A2
A1
Triangular mark
(on side of connector)
The register in the CC-Link unit has an emergency stop input. However, this is
just for control by the software and is not by itself totally adequate. So installing
an interlock circuit for emergency stop using the above mentioned Pin No.1
(EMG1) and Pin No. 2 (EMG2) of the EXT.CN connector is strongly
recommended.
12
CHAPTER2 CC-Link Unit
2-5
Controller system settings (remote station)
The communication speed and station No. must be set so that the controller can be correctly identified as a remote station on the CC-Link system.
Thy are set from the HPB.
These settings are enabled after the controller is restarted.
2-5-1
Validating the CC-Link unit
Before the CC-Link unit can be used, it must first be set as follows, to allow it to be
identified by the controller.
1)
Press F3 (SYS) on the initial screen.
[MENU]
select menu
1EDIT2OPRT3SYS 4MON
2)
Press F4 (next) to switch to the function display and then press F2 (OPT).
[SYS]
select menu
1SAFE2OPT 3UTL 4next
3)
Press F1 (DEV).
[SYS-OPT]
select menu
1DEV 2NODE3SPD 4next
4)
5)
The current CC-Link unit identity status
appears on the display.
Now, using the number key pad, enter a 1
to make the CC-Link unit identifiable
from the controller or enter a 0 to prevent
it being identified from the controller, and
then press the
key.
When entry is finished, the screen returns
to 4).
[SYS-OPT-DEV]
CC-Link= 0
0:invalid 1:valid
[SYS-OPT-DEV]
CC-Link= 1
0:invalid 1:valid
13
CHAPTER2 CC-Link Unit
2-5-2
Setting the station No.
The CC-Link unit occupies 2 stations. So the station displayed on the HPB and another
station (the station No.+1) are occupied.
1)
Press F3 (SYS) on the initial screen.
[MENU]
select menu
1EDIT2OPRT3SYS 4MON
2)
Press F4 (next) to switch to the function display and then press F2 (OPT).
[SYS]
select menu
1SAFE2OPT 3UTL 4next
3)
Press F2 (NODE).
[SYS-OPT]
select menu
1DEV 2NODE3SPD 4next
4)
The currently set station No. is displayed.
To change this setting, enter the new station No. with the number pad keys, and
then press the
key.
[SYS-OPT-NODE]
node
= 30
range 1→63
5)
When entry is finished, the screen returns
to 4).
[SYS-OPT-NODE]
node
= 1
range 1→63
14
CHAPTER2 CC-Link Unit
2-5-3
Setting the communication speed
Communication speed can be set to 10M, 5M, 2.5M, 625K, 156K in bps. The communication speed must match the master station speed.
1)
Press F3 (SYS) on the initial screen.
[MENU]
select menu
1EDIT2OPRT3SYS 4MON
2)
Press F4 (next) to switch to the function display and then press F2 (OPT).
[SYS]
select menu
1SAFE2OPT 3UTL 4next
3)
Press F3 (SPD).
[SYS-OPT]
select menu
1DEV 2NODE3SPD 4next
4)
5)
The currently set communication speed
is displayed. To change the speed, press
the function key matching the new communication speed you want to set. If the
new communication speed does not appear, press F4 (next) and the remaining
available communication speeds will appear.
When entry is finished, the screen returns
to 4).
[SYS-OPT-SPD]
speed
= 5M [bps]
110M 25M
[SYS-OPT-SPD]
speed
= 10M [bps]
110M 25M
15
32.5M4next
32.5M4next
CHAPTER2 CC-Link Unit
2-6
Sequencer (master station) settings
The master station sequencer (or PLC) in the CC-Link system can make line tests on the
remote station. Use this function to check whether or not the controller is identified as a
remote station on the CC-Link system before starting any actual work. Refer to the instruction manual for the master station sequencer (PLC) for detailed information.
! CAUTION
When the program is stopped on the master side, an interlock stop may occur in
the controller. If this happens, movement commands cannot be executed.
2-6-1
Starting data exchange with the controller
To correctly transmit and receive data between the master station sequencer (PLC) and
the controller, input the following sequencer (PLC) program from the master station
sequencer (PLC) so the following handshake process will be performed.
If this handshake processing is not performed, and RX(n+3)B is not set to ON, automatic
operation is disabled because emergency stop is triggered.
Perform this handshake process before trying to actually transmit or receive data.
RX(n+3)8
RY(n+3)8
RX(n+3)B
RX(n+3)8 : Initial data request flag
RY(n+3)8 : Initial data end flag
RX(n+3)B : Remote READY
(1) When the controller starts up or when communication with the master station is
disabled because an error occurs in the CC-Link system, the controller turns RX(n+3)8
ON, and turns RX(n+3)B OFF.
(2) Check that RX(n+3)8 is set to ON, and then set RY(n+3)8 to ON from the master
station sequencer (PLC).
(3) After checking that RX(n+3)8 is set to ON, the controller turns RX(n+3)8 OFF, and
turns RX(n+3)B ON.
(4) Check that RX(n+3)8 is set to OFF, and then set RY(n+3)8 to OFF from the master
station sequencer (PLC). The actual data can now be sent and received.
16
CHAPTER2 CC-Link Unit
2-7
I/O information
On/off (I/O) information handled by the CC-Link unit consists of 16 dedicated inputs,
32 general-purpose I/O inputs, 16 dedicated outputs and 32 general-purpose outputs (for
2 stations).
Dedicated inputs are sub-grouped by assigned function into 13 dedicated command inputs, interlock, service mode and emergency stop inputs.
* Some ports are currently reserved for future use and not available for dedicated command input and dedicated outputs.
* CC-Link I/O functions and methods for using them are basically identical to those for
the parallel I/O that are a standard feature in the controller.
2-7-1
Profile (I/O signal table)
The following table is a list profiling the CC-Link unit.
More detailed information on each signal is listed in “2-7-2 Dedicated command inputs”.
Remote I/O signals (for 2 stations)
OUTPUT (Remote→Master)
Device No.
Signal Name
RXn0
Servo status (SRV-O)
RXn1
(ZONE 0)
RXn2
(ZONE 1)
RXn3
(ZONE 2)
RXn4
(ZONE 3)
RXn5
Reserved
RXn6
Origin return status (ORG-O)
RXn7
Reserved
RXn8
Reserved
RXn9
Reserved
RXnA
Reserved
RXnB
Reserved
RXnC
Reserved
RXnD
END
RXnE
BUSY (executing command)
RXnF
READY
RX(n+1)0
SO200
RX(n+1)1
SO201
RX(n+1)2
SO202
RX(n+1)3
SO203
RX(n+1)4
SO204
RX(n+1)5
SO205
RX(n+1)6
SO206
RX(n+1)7
SO207
RX(n+1)8
SO208
RX(n+1)9
SO209
RX(n+1)A
SO210
RX(n+1)B
SO211
RX(n+1)C
SO212
RX(n+1)D
SO213
RX(n+1)E
SO214
RX(n+1)F
SO215
17
INPUT (Master→Remote)
Device No.
Signal Name
RYn0
SERVO (servo recovery)
RYn1
INC-PT (move relative point)
RYn2
ABS-PT (move absolute point)
RYn3
STEP-R (step operation)
RYn4
AUTO-R (auto operation)
RYn5
RESET
RYn6
ORG-S (origin return)
RYn7
LOCK (interlock)
RYn8
Reserved
RYn9
Reserved
RYnA
Reserved
RYnB
Reserved
RYnC
Reserved
RYnD
Reserved
RYnE
SVCE (service mode)
RYnF
EMG (emergency stop input)
RY(n+1)0
SI200
RY(n+1)1
SI201
RY(n+1)2
SI202
RY(n+1)3
SI203
RY(n+1)4
SI204
RY(n+1)5
SI205
RY(n+1)6
SI206
RY(n+1)7
SI207
RY(n+1)8
SI208
RY(n+1)9
SI209
RY(n+1)A
SI210
RY(n+1)B
SI211
RY(n+1)C
SI212
RY(n+1)D
SI213
RY(n+1)E
SI214
RY(n+1)F
SI215
CHAPTER2 CC-Link Unit
OUTPUT (Remote→Master)
Device No.
Signal Name
RX(n+2)0
SO216
RX(n+2)1
SO217
RX(n+2)2
SO218
RX(n+2)3
SO219
RX(n+2)4
SO220
RX(n+2)5
SO221
RX(n+2)6
SO222
RX(n+2)7
SO223
RX(n+2)8
SO224
RX(n+2)9
SO225
RX(n+2)A
SO226
RX(n+2)B
SO227
RX(n+2)C
SO228
RX(n+2)D
SO229
RX(n+2)E
SO230
RX(n+2)F
SO231
RX(n+3)0
RX(n+3)1
RX(n+3)2
RX(n+3)3
Reserved
RX(n+3)4
RX(n+3)5
RX(n+3)6
RX(n+3)7
RX(n+3)8
Initial data request flag
RX(n+3)9
Not Used
RX(n+3)A
Error flag
RX(n+3)B
Remote READY
RX(n+3)C
RX(n+3)D
Reserved
RX(n+3)E
RX(n+3)F
INPUT (Master→Remote)
Device No.
Signal Name
RY(n+2)0
SI216
RY(n+2)1
SI217
RY(n+2)2
SI218
RY(n+2)3
SI219
RY(n+2)4
SI220
RY(n+2)5
SI221
RY(n+2)6
SI222
RY(n+2)7
SI223
RY(n+2)8
SI224
RY(n+2)9
SI225
RY(n+2)A
SI226
RY(n+2)B
SI227
RY(n+2)C
SI228
RY(n+2)D
SI229
RY(n+2)E
SI230
RY(n+2)F
SI231
RY(n+3)0
RY(n+3)1
RY(n+3)2
RY(n+3)3
Reserved
RY(n+3)4
RY(n+3)5
RY(n+3)6
RY(n+3)7
RY(n+3)8
Initial data end flag
RY(n+3)9
RY(n+3)A
Not Used
RY(n+3)B
RY(n+3)C
RY(n+3)D
Reserved
RY(n+3)E
RY(n+3)F
n: Value determined by station number setting.
* Use RXn0-RXnF as dedicated outputs, RX(n+1)0 - RX(n+2)F as general-purpose outputs, RYn0 - RYnF as dedicated inputs, and RY(n+1)0 - RY(n+2)F as general-purpose
inputs.
* RX(n+3) 0 - RX(n+3)F and RY(n+3) 0 - RY (n+3)F are areas reserved for the CC-Link
system.
! CAUTION
• The above profile is for cases where the I/O assignment selection parameter is
set to "Type 0: Conventional type" when the controller has an I/O assignment
function. For information on the profile when the I/O assignment selection parameter is set to another type, refer to "2-9-2 I/O assignment list".
• The zone output is supported by the following controller versions:
ERCX, SRCX : Ver. 13.50 or later DRCX : Ver. 18.50 or later
SRCP, SRCD : Ver. 24.00 or later SRCP30 : Ver. 24.30H or later
18
CHAPTER2 CC-Link Unit
Remote Register
OUTPUT (Remote→Master)
Address
Description
Default
RWrn
Status
RWrn+1
Reserved
0
RWrn+2
RWrn+3
RWrn+4
Command response
0
RWrn+5
RWrn+6
RWrn+7
Address
RWwn
RWwn+1
RWwn+2
RWwn+3
RWwn+4
RWwn+5
RWwn+6
RWwn+7
INPUT (Master→Remote)
Description
Execution command
Command option
Default
0
0
n: Value determined by station number setting.
* For details on the remote register, refer to "2-12 Remote Command".
2-7-2
Dedicated command inputs
Dedicated command inputs are inputs from the sequencer (PLC) to the controller for
performing specific processing such as origin return or servo recovery. To accept these
inputs, the READY, BUSY, and Lock signals must be set as follows:
■ READY : ON
■ BUSY : OFF
■ LOCK : ON
If the above conditions are not satisfied, then dedicated command inputs cannot be accepted. For example, when the BUSY signal is on, this means that the controller is already executing a dedicated command, so other dedicated commands are ignored if they
are input. When the LOCK signal is off, no other commands can be accepted since
interlock was triggered.
(As an exception, the reset command is executed if only the BUSY output conditions are
met. The servo recovery command is executed if the BUSY conditions are met and all
emergency stop inputs to the emergency stop circuit are cancelled.)
A dedicated command input is accepted when the dedicated command input is switched
from OFF to ON (at the instant the contact point closes). Whether the controller accepts
the command or not can be checked by monitoring the BUSY signal.
Note that dedicated command inputs cannot be used as data in a program.
! CAUTION
The dedicated command inputs explained below must always be pulse inputs. In
other words, they must be turned off (contact open) when the BUSY signal turns
on.
If a dedicated command input is not turned off, then the BUSY signal will not turn
OFF even when the command has ended normally. This means that the next command cannot be accepted.
19
CHAPTER2 CC-Link Unit
■ Point movement command with absolute (ABS-PT)
When origin point coordinates are set at 0, this command moves the robot to a position specified in data by point No. (See "2-7-3 General-purpose inputs") specified by
SI200 through SI209, and at a speed specified by SI210 and SI211. On dual-axis
controllers, the axis to be moved can be specified with SI213, SI214 by making PRM10
varid.
! CAUTION
When executing this command (ABS-PT), the status of SI200 and SI211 must be
checked in advance. SI213 and SI214 must also be checked when specifying the
axis.
■ Point movement command with incremental (INC-PT)
This command moves the robot from the current position to a position specified in
data for point No. specified by SI200 through SI209, and at a speed specified by
SI210 and SI211. On dual-axis controllers, the movement axis can be specified with
SI213, SI214 by enabling PRM10.
MEMO
Current position is not necessarily the actual position of robot. It is the data of the
current position that is saved internally in the controller. On each execution of a movement command, the point that was the target position changes to the current position.
Therefore, even if interlock is triggered during execution of the relative movement
command, the operation restarts from the point where the robot is stopped, by executing the same relative movement command again. (This does not constitute a relative
movement based on the interlock-stopped point.)
Likewise, when the robot is moved manually to another position after executing the
robot movement command, the relative movement command which is subsequently
executed does not make a relative movement from the actual position of the robot.
Instead, the robot makes a relative movement based on the target position of the
previous robot movement command. Please bear this movement in mind.
The current position and robot position differ when:
• When emergency stop or interlock (LOCK) is applied during axis
movement;
• A communication command “^C” (movement interruption) is sent
during axis movement;
• The axis is moved manually; and
• The axis is move manually in the servo off state (including emergency stop state).
! CAUTION
S1200 to SI211 status must be checked in advance when running INC-PT. SI213 and
SI214 must also be checked when specifying the axis.
■ Automatic run start command (AUTO-R)
The program is run continuously, starting from the current step.
All tasks are executed when the multi-task program is running.
■ Step run start command (STEP-R)
The program is run step by step, starting from the current step.
The multi-task program only executes the selected task.
20
CHAPTER2 CC-Link Unit
■ Origin return command (ORG-S)
This command performs origin return when the search method was selected as the
origin detection method, or checks the origin return status if the mark method was
selected.
On dual-axis controllers, you can specify the axis for origin return with SI213, SI214
by making PRM10 varid.
MEMO
When performing origin return on a search method axis, if both a mark method axis
and a search method axis are present, then origin return must first be completed on
the mark method. Mark method origin return is performed on the HPB.
MEMO
Once origin return is performed after the absolute battery and robot cable are connected, it does not have to be performed again, even if the power is turned off. (Exceptions to this are if the absolute battery backup was disabled or origin-point related
parameters were changed. Origin point is then incomplete (pending) and must be reperformed.
! CAUTION
Do not halt on-going origin return during origin point detection (while contacting
the mechanical limits) when using the stroke end origin detection method. A controller overload will trigger an alarm stop condition and the power must be turned
off and then on again.
! CAUTION
When repeating origin return by the stroke end detection method is unavoidable,
wait at least 5 seconds before trying it again.
■ Servo ON command (SERVO)
After an emergency stop, cancel it by releasing the emergency stop switch. This triggers an input to turn the servo power on, and the robot can then resume operation.
(The SERVO command is also a pulse input, so must be turned OFF when BUSY
turns ON.)
On dual-axis controllers, the servo recovery axis can be specified with S1213, S1214
by making PRM10 varid.
21
CHAPTER2 CC-Link Unit
■ Reset command (RESET)
This command returns the program step to the first step of the lead program, and
turns DO0 - DO12*1, SO200 - SO231, and the memory I/O all off. The point variable
“P” is also cleared to 0. (Does not clear the counter variables “C” and “D”.
* The output from a parallel I/O port used for emulated serialization does not change
even if reset with the RESET command.
* When the “origin return completed action selection” parameter (single-axis controllers: PRM33, dual-axis controllers: PRM2) is 1 or 3, DO4*2 does not turn OFF
even if reset with the RESET command. In the same way, if the “servo status output
selection” parameter (single-axis controllers: PRM46, dual-axis controllers: PRM21)
is 1, DO7*3 does not turn OFF even if reset with the RESET command.
MEMO
The lead program is a program selected by switching to the last program run by HPB
or POPCOM.
The lead program can also be switched by running the “@SWI” communication command. It can also be switched even when program data is loaded from the memory
card.
*1: DO0 to DO4 when the SRCP/SRCD series controllers are used.
*2: DO5 when the DRCX series controllers are used.
*3: DO3 when the SRCP/SRCD series controllers are used.
22
CHAPTER2 CC-Link Unit
2-7-3
General-purpose inputs (SI200 - SI231)
General-purpose inputs are inputs freely available to the user for handling as data in the
program.
As a special usage method, SI200 - SI209 can specify point numbers, and SI210 - SI211
can specify movement speed during running of ABS-PT or INC-PT point movement
commands. As shown in the table below, a binary code should be entered in SI200 SI209 to specify the point numbers P0 - P999.
The movement speed is 100% when SI210 and SI211 are both OFF. At all other times,
the movement speed is specified by parameters.
By making parameter settings, SI213 and SI214 are sometimes used to specify the movement axis.
Specifying a point number
SI No.
Point No.
P0
P1
P3
P7
P15
P31
P63
P127
P254
P511
P999
SI209 SI208 SI207 SI206 SI205 SI204 SI203 SI202 SI201 SI200
(2 8)
(2 7)
(2 6)
(2 5)
(2 4)
(2 3)
(2 2)
(2 1)
(2 0)
(2 9)
OFF
OFF OFF
OFF OFF
OFF OFF OFF
OFF
OFF
OFF
OFF OFF
OFF OFF
OFF OFF OFF
OFF
ON
OFF
OFF OFF
OFF OFF
OFF OFF OFF
ON
ON
OFF
OFF OFF
OFF OFF
OFF OFF ON
ON
ON
OFF
OFF OFF
OFF OFF
OFF ON
ON
ON
ON
OFF
OFF OFF
OFF OFF
ON
ON
ON
ON
ON
OFF
OFF OFF
OFF ON
ON
ON
ON
ON
ON
OFF
OFF OFF
ON
ON
ON
ON
ON
ON
ON
OFF
OFF ON
ON
ON
ON
ON
ON
ON
OFF
OFF
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
ON
OFF OFF ON
ON
ON
Specifying movement speed
SI211 SI210
OFF OFF
OFF ON
ON
OFF
ON
ON
Movement speed
100%
PRM5*
PRM6*
PRM7*
Specifying the movement axis
(For dual-axis controllers)
SI214 SI213
OFF OFF
OFF ON
ON
OFF
ON
ON
Movement axis
All axes
X axis
Y axis
All axes
* For dual-axis controllers. For single-axis controllers,
the speed is set in order from the top, by PRM41,
PRM42, PRM43.
MEMO
The above tables are for cases where the I/O assignment selection parameter is set to
"Type 0: Conventional type" when the controller has an I/O assignment function. For
examples of specifying each item when the I/O assignment selection parameter is set
to another type, refer to "2-9-4 I/O signal description".
23
CHAPTER2 CC-Link Unit
2-7-4
Interlock (LOCK)
These are inputs to temporarily stop robot movement.
Robot operation can be stopped by setting this input to OFF during running of dedicated
commands from the I/O, during running of a program by HPB (or personal computer), or
during return to origin. (Of course, the program operation also stops.)
When this input is OFF however, dedicated commands from the I/O and running of
programs from the HPB (or personal computer) as well as origin return are all disabled.
Therefore you should normally keep this input at ON.
The only exceptions to this, are the RESET and SERVO commands whose inputs are
enabled regardless of whether this interlock input is ON or OFF.
Once the interlock is set to OFF, the robot remains stopped until another command is
input (AUTO-R, ORG-S) even if the interlock is set to ON again.
MEMO
The interlock input on the parallel I/O of the controller is also always valid. Accordingly, the interlock will be activated to prevent the automatic operation and others if
either of two interlock inputs is OFF. For automatic operation and others, it is necessary to surely keep both interlock inputs ON. (On the SRCP/SRCD series, the parallel I/O interlock can be disabled by the parameter setting. For more details, refer to
"2-4 Parallel I/O connector".)
2-7-5
Emergency stop input (EMG)
Use this EMG input when you want to set the robot to emergency stop. Setting this input
to OFF cuts off the servo power and turns off the servo.
To restart operation, first set this input to ON, then input the servo recovery command
(SERVO) after checking that the READY output is ON. The servo turns ON and the
robot can now be operated.
When the HPB (or personal computer) is connected, you can reset from emergency stop
by the HPB (or personal computer) operation.
The emergency stop input in the CC-Link unit is only controlled by the software
and does not constitute a complete safety circuit. So installing a hardware
interlock circuit for emergency stop utilizing the emergency stop input pins
installed on the parallel I/O of the controller is strongly recommended.
24
CHAPTER2 CC-Link Unit
2-7-6
Service mode (SVCE)
This input is valid when the service mode function of the controller main body is valid.
The service mode input is used to inform the controller whether the current status is the
service mode status or not. In the service mode status, keep this input OFF (the contact is
open.).
MEMO
When the status of the service mode input varies during robot operation, the operation execution will be interrupted.
MEMO
When the service mode function is valid, DI15* on the parallel I/O also functions as
the service mode input. Accordingly, it will be switched to the service mode status if
either of two service mode inputs is merely turned OFF. To escape from the service
mode status, it is necessary to turn ON both service mode inputs.
* DI7 when the SRCP/SRCD series controllers are used.
2-7-7
Initial data processing end flag
This is an input for performing the handshake to start communication between the controller and the master station sequencer (PLC).
During controller start-up, or when an error occurs on the CC-Link system and communication with the master station was not performed, the controller sets the initial data
request flag to ON. When the initial data request flag turns ON, set this input to ON from
the sequencer (PLC). Doing this makes the controller set the initial data request flag to
OFF, so you should then turn this input OFF from the sequencer (PLC).
Refer to “2-6-1 Starting data exchange with the controller” for more detailed information.
25
CHAPTER2 CC-Link Unit
2-7-8
Dedicated outputs
Dedicated outputs inform the sequencer (PLC) of controller status.
■ "Preparation completed" output (READY)
The dedicated output is ON while the controller system is operating normally. However the output turns OFF under any of the following conditions and the motor becomes "free".
• During emergency stop
The READY output turns ON again when emergency stop is canceled. After canceling emergency stop, operation can be restarted by inputting the servo recovery
command (SERVO).
• During alarm
If the READY signal is OFF but the robot is not in emergency stop, then some kind
of alarm was issued. In this case, operation cannot resume unless the power is turned
off and then on again.
■ "Command execution in progress" output (BUSY)
The BUSY signal is ON during execution of a dedicated command input, or execution of a command from the HPB (or personal computer). This signal turns ON when
the dedicated input signal is received, so turn dedicated input signal OFF when the
BUSY signal turns ON. The BUSY output turns OFF when the executing of this
command is ended. (However, all the dedicated inputs must be OFF at this time.)
! CAUTION
Always input the dedicated command input as a pulse signal. If the input stays
ON, the BUSY signal will not turn OFF even after the command is executed.
If the BUSY output is at ON, then the controller cannot accept dedicated inputs
and commands from the HPB (or personal computer). Do not try to operate the
HPB while the I/O interface is controlling the controller.
(This could cause communication errors with the sequencer (PLC) or cause communication error to occur in the HPB.
■ "Execution ended" output (END)
This signal turns OFF when a dedicated command input is received, and then turns
ON when the command ends normally. When an error occurs during execution of a
command or when an interlock or emergency stop has triggered, the END signal
remains unchanged at OFF.
! CAUTION
When the RESET command or a movement command for only a small movement is run, the time for running the command (in other words the interval that
the END signal is OFF) is extremely short. (Sometimes less than 1ms.)
The END signal will not change during operation from the HPB (or personal
computer).
MEMO
By changing the System mode selection parameter setting (single-axis controllers:
PRM34, dual-axis controllers: PRM20), the execution result of a dedicated command
can be output to the END signal at the time when the dedicated command input has
turned OFF after the command execution.
For details on the System mode selection parameter, refer to "Description of each
parameter" in the controller user's manual.
26
CHAPTER2 CC-Link Unit
■ "Servo status" output (SRV-O)
Displays the robot servo status.
This turns ON when all axes are at servo-ON. However, this output is OFF if even just
one axis is in servo-OFF status.
* This servo status output is always enabled, even if the "servo status output selection" parameter (single-axis controllers: PRM46, dual-axis controllers: PRM21)
does not have to be changed.
■ "Origin return status" output (ORG-O)
This outputs the robot origin return status.
This output is ON when origin return is complete on all axes. This output however
turns OFF if even origin return on even just one axis is incomplete.
* This output is always enabled, even if the "origin return completed action selection" parameter (single-axis controllers: PRM33, dual-axis controllers: PRM2) does
not have to be changed.
■ Zone output (ZONE0 to ZONE3)
This specifies the output destination of the zone output function.
The zone output is used to control the signal output when the robot's current position
is within the specified range.
To use the zone output function, the desired zone output must be enabled by the Zone
output selection parameter (single-axis controllers: PRM53, dual-axis controllers:
PRM24). This parameter also sets the zone output logic.
Use point data to specify the range. Point numbers and output signal names used for
each zone are shown below.
For details on the zone output, refer to the "Zone output selection" parameter described in the controller user's manual.
Setting range and output port for each zone
ZONE No.
ZONE 0
ZONE 1
ZONE 2
ZONE 3
Specified range Output signal name
P900-P901
ZONE 0
P902-P903
ZONE 1
P904-P905
ZONE 2
P906-P907
ZONE 3
MEMO
The zone output is supported by the following controller versions:
ERCX, SRCX : Ver. 13.50 or later
DRCX
: Ver. 18.50 or later
SRCP, SRCD : Ver. 24.00 or later
SRCP30 : Ver. 24.30H or later
2-7-9
General-purpose outputs (SO200 - SO231)
These are outputs available to the user and can be freely turned on and off within the
program. All general-purpose outputs are reset (OFF) when the power is turned on or
when the program is reset.
* A parallel I/O port used for emulated serialization cannot be controlled while a program is running. Also, the output from a parallel I/O port used for emulated serialization does not change even if reset with the RESET command.
27
CHAPTER2 CC-Link Unit
2-7-10
Initial data processing request flag
This is an output for performing the handshake to start communication between the
controller and the master station sequencer (PLC).
During controller start-up, or when communication with the master station was not performed because an error occurs on the CC-Link system, the controller sets this output to
ON. When this output turns ON, set the initial data end flag to ON from the sequencer
(PLC).
Doing this makes the controller set this output to OFF, so you should then set the “initial
data processing end flag” to OFF on the sequencer (PLC).
Refer to “2-6-1 Starting data exchange with the controller” for more detailed information.
2-7-11
Remote READY
This output turns ON when normal communication exchange between the controller and
the master station sequencer (PLC) can be performed.
This output turns OFF in the following cases. In such cases the controller sets to emergency stop and auto operation is impossible.
• Controller power cannot turn on
• Alarm occurs on controller
• Alarm was issued on CC-Link system and communication with the master station
is impossible.
• Handshake for starting communication between the controller and master station
sequencer (PLC) cannot be performed.
Refer to, “2-6-1Starting data exchange with the controller” for information involving
handshake for communication start-up.
2-7-12
Error flag
This output turns ON when an alarm occurred on the controller.
If this output turns ON, refer to “Alarm and Countermeasures” in the controller instruction manual for information on eliminating the problem.
To restore operation, first eliminate the cause of the alarm, and then turn the controller
power off and then back on again.
28
CHAPTER2 CC-Link Unit
2-8
Timing chart
Timing charts are included so please refer to them when creating a sequencer (PLC)
program.
2-8-1
Handshake for starting data exchange
RX(n+3)8
RY(n+3)8
RX(n+3)B
RX(n+3)8 : Initial data request flag
RY(n+3)8 : Initial data end flag
RX(n+3)B : Remote READY
(1) When the controller starts up or when communication with the master station was
disabled because an error occurs in the CC-Link system, the controller turns RX(n+3)8
ON, and turns RX(n+3)B OFF.
(2) Check that RX(n+3)8 is set to ON, and then set RY(n+3)8 to ON from the master
station sequencer (PLC).
(3) After checking that RX(n+3)8 is set to ON, the controller turns RX(n+3)8 OFF, and
turns RX(n+3)B ON.
(4) Check that RX(n+3)8 is set to OFF, and then set RY(n+3)8 to OFF from the master
station sequencer (PLC). The actual data can now be sent and received.
■ The handshake operation is a process always necessary for normal communication
between the controller and the master station sequencer (PLC). The remote READY
output turns ON when the handshake is performed correctly. The robot sets to emergency stop if this handshake operation is not performed, and then robot cannot operate.
■ The robot always sets to servo-off when the controller power is turned on. To operate
the robot, first perform the handshake operation, and then cancel emergency stop
while referring to “2-8-2 Dedicated input command execution” and then run the
SERVO (servo recovery) command.
29
CHAPTER2 CC-Link Unit
2-8-2
Dedicated input command execution
■
The BUSY output turns ON when a dedicated command input is received. Whether
or not the received command ended normally is checked by the END output at the
point when the BUSY output turns OFF. In other words, the END output that is ON
at this time, shows the command ended normally. However the command did not end
normally if the END output is OFF.
■ Always input the dedicated command input as a pulse signal. If this input stays on,
the BUSY signal cannot turn OFF even if the command is complete.
(1) When a long execution time command runs and ends normally:
(The command execution is in progress and the END signal off when the dedicated
command input turns off (contact open))
Dedicated
command
BUSY
END
30ms or less
(1)
(2)
(3)
(4)
1ms or less
1ms or less
At the rise of the dedicated command input, the END signal turns off and the
BUSY signal turns on.
Turns off the dedicated command input after the BUSY signal turns on.
Wait until the BUSY signal turns off.
The END signal should be on when the BUSY signal turns off, indicating that
the command has ended normally.
! CAUTION
With the auto run (AUTO-R) command, the END signal turns on and the BUSY
signal turns off when the program has ended or a STOP statement was executed.
When an endless program (one that always automatically returns to the top line
of the program from the last step) was run, the BUSY signal does not turn off
unless an interlock or emergency stop is triggered.
30
CHAPTER2 CC-Link Unit
(2) When a short execution time command runs and ends normally
(In the following cases, when the dedicated command input is turned OFF, the command has already ended, and END has turned ON.)
• When running a movement command (ABS-PT, INC-PT) with an extremely short
movement distance.
• When RESET was run.
• When running steps of a command having an extremely short processing time such
as L or DO statements.
Dedicated
command
BUSY
END
30ms or less 1ms or less
(1)
(2)
(3)
(4)
30ms or less
At the rise of the dedicated command input, the END signal turns off and the
BUSY signal turns on.
Turns off the dedicated command input after the BUSY signal turns on.
Wait until the BUSY signal turns off. (The BUSY signal immediately turns off
since the command execution time is short.)
The END signal should be on when the BUSY signal turns off, indicating that
the command has ended normally.
The "bit 7 END output sequence setting at command execution completion" in the
System mode selection parameter (single-axis controllers: PRM34, dual-axis controllers: PRM20) can be changed so that the END signal turns ON when the dedicated command input turns OFF.
MEMO
The "bit 7 END output sequence setting at command execution completion" in the
System mode selection parameter (single-axis controllers: PRM34, dual-axis controllers: PRM20) is supported by the following controller versions:
ERCX, SRCX : Ver. 13.74 or later
DRCX
: Ver. 18.74 or later
SRCP, SRCD : Ver. 24.32 or later
SRCP30 : Ver. 24.32H or later
31
CHAPTER2 CC-Link Unit
Dedicated command
execution completion
Even after dedicated command
execution completion, the END
signal does not turn on until the
dedicated command input turns
off.
Dedicated
command
BUSY
END
30ms or less 1ms or less 1ms or less 1ms or less
(3) When running a command was impossible from the start
(In the following cases, END will not turn ON, when running of command was
impossible from the start.)
• When a movement command (ABS-PT, INC-PT) was run without first completing
return to origin.
• When an operation start command (AUTO-R, STEP-R) was run without first completing return to origin (except when pre-operation selection parameter (singleaxis controllers: PRM48, dual-axis controllers: PRM9) was set to 1 or 3).
• When an unregistered point No. was specified, and a movement command (ABSPT, INC-PT) was run.
• When a dedicated command was run while in emergency stop or an interlock triggered. (except for RESET and SERVO commands)
Dedicated
command
BUSY
END
30ms or less 1ms or less
(1)
(2)
(3)
(4)
30ms or less
At the rise of the dedicated command input, the END signal turns off and the
BUSY signal turns on.
Turns off the dedicated command input after the BUSY signal turns on.
Wait until the BUSY signal turns off. (The BUSY signal immediately turns off
since the command cannot be executed.)
The END signal remains off when the BUSY signal turns off, indicating that
the command could not end normally.
32
CHAPTER2 CC-Link Unit
(4) When an on-going command becomes impossible to run
(In the following cases, END will not turn ON, when running of an on-going command becomes impossible.)
• When an interlock or emergency stop was triggered during running of a dedicated
command.
• When a jump to an unregistered program was made during automatic operation, a
move to an unregistered point was made or some kind of error occurred.
Command execution impossible
Dedicated
command
BUSY
END
Differs according to execution command
(1)
(2)
(3)
(4)
(5)
At the rise of the dedicated command input, the END signal turns off and the
BUSY signal turns on.
Turns off (contact open) the dedicated command input after the BUSY signal
turns on.
Wait until the BUSY signal turns off.
The BUSY signal turns off because the command execution becomes impossible before it is fully executed.
The END signal remains off when the BUSY signal turns off, indicating that
the command could not end normally.
33
CHAPTER2 CC-Link Unit
2-8-3
When interlock signal is input
Interlock
LOCK
Dedicated
command
BUSY
END
Differs according to execution command
■ The BUSY output turns OFF when an interlock signal is input during running of a
dedicated command. The READY output and the END output remain unchanged.
34
CHAPTER2 CC-Link Unit
2-8-4
When emergency stop signal is input
Emergency stop
EMG
Dedicated
command
BUSY
END
READY
5ms or less 1ms or less
■ The READY output turns OFF. The BUSY output turns OFF during running of a
dedicated command. The END output is unchanged.
■ To resume robot operation, after canceling emergency stop and checking that the
READY output is ON, input the SERVO command.
35
CHAPTER2 CC-Link Unit
2-8-5
When an alarm is issued
Alarm occurs
Dedicated
command
RX(n+3)B
RX(n+3)A
BUSY
END
READY
5ms or less 30ms or less
1ms or less
RX(n+3)B : Remote READY
RX(n+3)A : Error flag
■ The remote READY output turns OFF, and the error flag turns ON. The READY,
BUSY, END outputs are all OFF.
■ Refer to “Alarm and Countermeasures” in the controller instruction manual for information on eliminating the problem.
36
CHAPTER2 CC-Link Unit
2-8-6
When point movement commands are run
■ When executing a point movement command (ABS-PT, INC-PT), the point data
and speed data must be input before inputting the dedicated command. When
specifying the moving axis, the axis selection data must be input.
The point data and speed data inputs are designated with SI200 to SI211. The axis
selection data input is designated with SI213 to SI214. (Refer to “2-7-3 Generalpurpose input (SI200 to SI231)”.)
Point data (SI200 to 209)
Speed data (SI210,SI211)
Axis selection data (SI213,SI214)
Data retention
Point movement command
(ABS-PT,INC-PT)
BUSY
Actual robot operation
Robot movement
END
30ms or more
(1) Input the point and speed data into SI200 - SI211. To specify a movement axis,
input the axis (designation) data into SI213, SI214. Please hold this data until the
BUSY signal turns on. (Changing data while busy may sometimes cause data
recognition errors.)
(2) Input the point movement commands (ABS-PT, INC-PT) after delaying the time
to 30 ms or more.
(3) The END signal turns off at the rise of the dedicated input pulse, and the BUSY
signal turns on.
(4) After checking that the BUSY is on, the dedicated input command is set to off.
From hereon, point data, speed data (SI200 - SI211), and the axis (designation)
data (SI213 and SI214) may be changed as needed.
(5) Waits until the BUSY signal turns off.
(6) When the BUSY signal has turned off, the END signal is at ON, indicating that
the command ended normally.
37
CHAPTER2 CC-Link Unit
2-9
I/O assignment change function
2-9-1
Changing the I/O assignment
The I/O assignment change function changes the function assigned to each input/output
(I/O) signal.
I/O assignment can be changed by setting the I/O assignment selection parameter (singleaxis controllers: PRM59, dual-axis controller: PRM26). For the contents of I/O assignment, refer to "2-9-2 I/O assignment list". Also refer to "2-9-3 I/O assignment selection
parameter description" for details on the I/O assignment selection parameter and "2-9-4
Input/output signal description" for details on each input/output signal used for I/O assignment selection. After changing the I/O assignment, the controller must be restarted
to enable the changes.
MEMO
The I/O assignment change function is supported by the following controller versions:
ERCX, SRCX : Ver. 13.57 or later
DRCX
: 18.57 or later
SRCP, SRCD : Ver. 24.17 or later
SRCP30 : Ver. 24.30H or later
38
CHAPTER2 CC-Link Unit
2-9-2
I/O assignment list
The table below shows the function assigned to each input/output (I/O) signal by setting
the I/O assignment selection parameter.
For details on the I/O assignment selection parameter, refer to "2-9-3 I/O assignment
selection parameter description". For details on each I/O signal, refer to "2-9-4 I/O signal description".
I/O assignment list
Type
Type 0
(Conventional type)
Type 1
Type 2
(Point number output type)
Type 3
(Point teaching type)
Point
trace
mode
I/O assignment
selection
parameter
0
Teaching
mode
Point
trace
mode
Teaching
mode
−
xx20 *1
xx21 *1
xx30 *1
xx31 *1
1000
−
64
16
64
16
No. of speed
switching points *3
4
−
None
4
None
4
Program operation by I/O
Yes
−
No
No
No
No
Function
No. of points *2
(Standard)
Device No.
RYn0
SERVO
SERVO
SERVO
RYn1
INC-PT
INC-PT
INC-PT
INC-PT
SERVO
JOG-
INC-PT
JOG-
RYn2
ABS-PT
ABS-PT
ABS-PT
ABS-PT
JOG+
ABS-PT
JOG+
RYn3
STEP-R
RYn4
AUTO-R
RYn5
RESET
RESET
RESET
RESET
RESET
RYn6
ORG-S
ORG-S
ORG-S
ORG-S
ORG-S
RYn7
LOCK
LOCK
LOCK
LOCK
LOCK
RYnE
SVCE
SVCE
SVCE
SVCE
SVCE
RYnF
EMG
EMG
EMG
EMG
EMG
RY(n+1)0
SI200
PI200
PI200
PI200
PI200
RY(n+1)1
SI201
PI201
PI201
PI201
PI201
RY(n+1)2
SI202
PI202
PI202
PI202
PI202
RY(n+1)3
SI203
Cannot
PI203
PI203
PI203
PI203
RY(n+1)4
SI204
be used.
PI204
SPD201
PI204
SPD201
RY(n+1)5
SI205
PI205
SPD202
PI205
SPD202
RY(n+1)6
SI206
RY(n+1)7
SI207
RY(n+1)8
SI208
RY(n+1)9
SI209
RY(n+1)A
SI210
RY(n+1)B
SI211
CHG
SERVO
CHG
PSET
PSET
RYn8
RYn9
RYnA
RYnB
RYnC
Input (Master → Remote)
RYnD
RY(n+1)C
SI212
RY(n+1)D
SI213 *4
*4
*4
*4
*4
RY(n+1)E
SI214 *4
*4
*4
*4
*4
RY(n+1)F
SI215
RY(n+2)0
to
RY(n+2)F
SI216
to
SI231
(continued to next page)
39
CHAPTER2 CC-Link Unit
RXn0
SRV-O
SRV-O
SRV-O
SRV-O
SRV-O
RXn1
(ZONE0)
(ZONE0)
(ZONE0)
(ZONE0)
(ZONE0)
RXn2
(ZONE1)
(ZONE1)
(ZONE1)
(ZONE1)
(ZONE1)
RXn3
(ZONE2)
(ZONE2)
(ZONE2)
(ZONE2)
(ZONE2)
RXn4
(ZONE3)
(ZONE3)
(ZONE3)
(ZONE3)
(ZONE3)
ORG-O
ORG-O
ORG-O
ORG-O
ORG-O
END
END
END
END
RXn5
RXn6
RXn7
RXn8
Output (Remote → Master)
RXn9
RXnA
RXnB
Cannot
RXnC
RXnD
END
be used.
RXnE
BUSY
BUSY
BUSY
BUSY
BUSY
RXnF
READY
READY
READY
READY
READY
RX(n+1)0
SO200
PO200
PO200
PO200
PO200
RX(n+1)1
SO201
PO201
PO201
PO201
PO201
RX(n+1)2
SO202
PO202
PO202
PO202
PO202
RX(n+1)3
SO203
PO203
PO203
PO203
PO203
RX(n+1)4
SO204
PO204
ORG-O/ZONE0
PO204
ORG-O/ZONE0
RX(n+1)5
SO205
PO205
SRV-O/ZONE1
PO205
SRV-O/ZONE1
RX(n+1)6
to
SO206
to
RX(n+1)F
SO215
RX(n+2)0
to
SO216
to
RX(n+2)F
SO231
n: Value determined by station number setting
*1: The PO output format differs depending on the values in the "hundreds" and "thousands" places of the I/O
assignment selection parameter (single-axis controllers: PRM59, dual-axis controllers: PRM26).
*2: Specifies the permissible number of movement points for a point movement command (ABS-PT, INC-PT).
*3: Specifies the permissible number of speed switching points for a point movement command (ABS-PT, INC-PT).
*4: In dual-axis controllers, a desired axis can be specified using SI213 and SI214 when executing I/O dedicated
commands (ABS-PT, INC-PT, ORG-S, and SERVO). In this case, the PRM10 (control axis selection with I/O
command) must first be set to "Valid". The same applies when specifying a control axis for executing JOG
movement commands (JOG+, JOG-).
40
CHAPTER2 CC-Link Unit
2-9-3
I/O assignment selection parameter description
The I/O assignment selection parameter (single-axis controllers: PRM59, dual-axis controllers: PRM26) selects the function to be assigned to each I/O signal.
This parameter setting allows changing the function assigned to each I/O signal. This
makes it possible to output the destination point number and perform jog movement.
After changing the I/O assignment, the controller must be restarted to enable the changes.
MEMO
The I/O assignment selection parameter is supported by the following controller versions:
ERCX, SRCX : Ver. 13.57 or later
DRCX
: Ver. 18.57 or later
SRCP, SRCD : Ver. 24.17 or later
SRCP30 : Ver. 24.30H or later
I/O assignment selection parameter
Parameter number
Single-axis controllers : PRM59
Dual-axis controllers : PRM26
Input range
0 or another number (Refer to "2-9-2 I/O assignment list".)
Meaning
PRM59/PRM26 = x x xx
↑ ↑ ↑
ew q
q I/O assignment type selection
Value
00
Description
Type 0 (Conventional type/standard)
20
Type 2 (Point number output type)
21
30
Type 3 (Point teaching type)
31
MEMO
Type 1 cannot be used with the SRCP, SRCD, SRCX, SRCX,
and DRCX.
w Point output selection
Make setting only for Type 2 (Point number output type) or
Type 3 (Point teaching type).
Value
Description
0
Outputs PO when movement ends normally.
1
Outputs PO when movement command is received.
2
Point zone output
Outputs PO when the robot enters the ± position judgment parameter
range for point data registered in the controller.
3
Movement point zone output
Outputs PO when the robot enters the ± position judgment parameter
range for point data that is registered in the controller and serves as the
movement target position of a point movement command (ABS-PT,
INC-PT).
MEMO
The movement point zone output is supported by the following
controller versions:
ERCX, SRCX : Ver. 13.64 or later DRCX : Ver. 18.64 or later
SRCP, SRCD : Ver. 24.21 or later SRCP30 : Ver. 24.30H or later
41
CHAPTER2 CC-Link Unit
e Point zone judgment method selection
The position judgment parameter is selected when the point
output selection is "2" (point zone output) or "3" (movement
point zone output).
Value
Description
0
OUT valid position
1
Positioning-completed pulse
MEMO
• The Point zone judgment method selection is supported by
the following controller versions:
ERCX, SRCX : Ver. 13.64 or later DRCX : Ver. 18.64 or later
SRCP, SRCD : Ver. 24.21 or later SRCP30 : Ver. 24.30H or later
• In controller versions prior to the above versions, the "OUT
valid position" is the only point zone judgment method.
Initial value
0
! CAUTION
Any value other than the above is handled as a "0" (Type 0).
(Example) If set to 2331, this is handled as a "0" (Type 0).
If set to 10, this is handled as a "0" (Type 0).
Moreover, if Type 2 (Point number output type) or Type 3 (Point teaching type)
is selected in controller versions not supporting the movement point zone output
while the point output selection is specified as "3", this is also processed as a "0"
(Type 0) setting.
(Example) In controller versions not supporting the movement point zone
output:
If set to 331, this is handled as a "0" (Type 0).
42
CHAPTER2 CC-Link Unit
2-9-4
I/O signal descripion
The meaning of each signal is explained below. For the meaning of signals not described
here, refer to "2-7-2 Dedicated command input" and the following sections.
■ Point number designation inputs 200 to 205 (PI200 to PI205)
These inputs designate the point number of the target position where the robot moves
with a point movement command (ABS-PT, INC-PT). (For details on the ABS-PT
and INC-PT commands, see 2-7-2, "Dedicated command input" in this chapter.)
These inputs are also used to designate the point number of the target position
where point data is written with a point data write command (PSET).
The point number of the target position must be specified before running a point
movement command or point write command. The point number is specified by a
binary code. See the table below to specify each point number.
Point number designation example
PI No.
PI205
PI204
4
PI203
3
PI202
2
PI201
1
PI200
(2 )
(2 )
(2 )
(2 )
(2 )
(20)
P0
OFF
OFF
OFF
OFF
OFF
OFF
P1
OFF
OFF
OFF
OFF
OFF
ON
P7
OFF
OFF
OFF
ON
ON
ON
P15
OFF
OFF
ON
ON
ON
ON
P31
OFF
ON
ON
ON
ON
ON
P63
ON
ON
ON
ON
ON
ON
Point No.
5
■ Movement speed setting (SPD201, SPD202)
Designates the speed at which the robot moves with a point movement command
(ABS-PT, INC-PT) or jog movement command (JOG+, JOG-). (For details on the
ABS-PT and INC-PT commands, see 2-7-2, "Dedicated command input" in this
chapter.)
The movement speed must be specified before running a point movement command or jog movement command. See the table below to specify the movement
speed.
Movement speed setting example
SPD202 SPD201
OFF
100%
OFF
Movement speed
OFF
ON
I/O point movement command first speed
(single-axis controllers: PRM41, dual-axis controllers: PRM5)
ON
OFF
I/O point movement command second speed
(single-axis controllers: PRM42, dual-axis controllers: PRM6)
ON
ON
I/O point movement command third speed
(single-axis controllers: PRM43, dual-axis controllers: PRM7)
■ Jog movement (+ direction) command (JOG+)
Moves the robot in jog mode along the + (plus) direction.
The robot moves in jog mode along the + (plus) direction as long as this signal is
on. The movement speed is 100mm/sec.
This speed can be changed by using SPD201 and SPD202. In this case, the
movement speed is given by the following equation.
Movement speed [mm/sec] = 100 × (Movement speed [%] specified with SPD201 and SPD202) / 100
In the case of dual-axis controllers, the X-axis is usually used for jog movement.
However, the Y-axis can be specified with SI213 and SI214 by enabling PRM10
(Control axis selection with I/O command). (Refer to "PRM10: Control axis
selection with I/O command" in the DRCX controller user's manual.)
43
CHAPTER2 CC-Link Unit
Axis selection example
SI214 SI213
OFF
OFF
ON
ON
OFF
ON
OFF
ON
JOG+, JOGSelected axis
X-axis
X-axis
Y-axis
X-axis
! CAUTION
• If the CHG (mode switch input) signal is switched during jog movement, the
robot comes to an error stop.
• When selecting the axis of a dual-axis controller, the status of SI213 and SI214
must first be determined. (Refer to "Jog movement (JOG+, JOG-)" in "2-9-5
Timing chart".)
■ Jog movement (- direction) command (JOG-)
Moves the robot in jog mode along the - (minus) direction.
The robot moves in jog mode along the - (minus) direction as long as this signal is
on. The movement speed is 100mm/sec.
This speed can be changed by using SPD201 and SPD202. In this case, the movement speed is given by the following equation.
Movement speed [mm/sec] = 100 × (Movement speed [%] specified with SPD201 and SPD202) / 100
In the case of dual-axis controllers, the X-axis is usually used for jog movement.
However, the Y-axis can be specified with SI213 and SI214 by enabling PRM10
(Control axis selection with I/O command). (Refer to "PRM10: Control axis
selection with I/O command" in the DRCX controller user's manual.)
Axis selection example
SI214 SI213
OFF
OFF
ON
ON
OFF
ON
OFF
ON
JOG+, JOGSelected axis
X-axis
X-axis
Y-axis
X-axis
! CAUTION
• If the CHG (mode switch input) signal is switched during jog movement, the
robot comes to an error stop.
• When selecting the axis of a dual-axis controller, the status of SI213 and SI214
must first be determined. (Refer to "Jog movement (JOG+, JOG-)" in "2-9-5
Timing chart".)
■ Mode switch input (CHG)
Switches the Type 3 (Point teaching type) mode. Selectable modes are as follows.
(1) Point trace mode
(2) Teaching mode
The Type 3 (Point teaching type) mode is switched to "Point trace mode" when the
CHG signal is off, and is switched to "teaching mode" when the CHG signal is on.
! CAUTION
If the CHG signal is switched during execution of a point movement command
(ABS-PT, INC-PT) or jog movement command (JOG+, JOG-), the robot comes
to an error stop.
44
CHAPTER2 CC-Link Unit
■ Point data write command (PSET)
Writes the current position data in the specified point number.
To use this command, the point number for writing the current position data must
first be specified using a PI (point number designation input) input.
The PSET is enabled only when return-to-origin has been completed.
■ Target position's point number outputs 200 to 205 (PO200 to PO205)
These are the output signals for the point movement command (ABS-PT, INC-PT)
target position point numbers, and for the point numbers corresponding to the
point zone output and movement point zone output functions. (For details on ABSPT and INC-PT commands, see 2-7-2, "Dedicated command input" in this
chapter.)
The "point zone output function" outputs the corresponding point number to the
PO when the robot enters the point zone output range (corresponding point ±
position judgment parameter range). The corresponding point of this point zone
output range is the point data registered at the controller.
Moreover, the point zone output range's corresponding point can be further
narrowed to correspond to point movement commands (ABS-PT, INC-PT), with
the point number being output to the PO. This is referred to as the movement point
zone output function.
Point zone output function
For single-axis controller
Point zone output range
Corresponding point (Pn)
a
a
ON
PO
OFF
OFF
a : Position judgment parameter range
(selected by the PRM59 "thousands" digit value)
For dual-axis controller
Point zone output range
b
a
a
b
PO : OFF
PO : OFF
Corresponding point (Pn)
45
PO : OFF
a : X-axis position judgment parameter range
(selected by the PRM26 "thousands" digit value)
b : Y-axis position judgment parameter range
(selected by the PRM26 "thousands" digit value)
CHAPTER2 CC-Link Unit
Target position point numbers for point movement commands (ABS-PT, INC-PT)
are output as binary values. The same applies to point numbers which correspond to
the point zone output function and the movement point zone output function.
The PO output format is specified in the "hundreds" place of the I/O assignment
selection parameter setting (single-axis controllers: PRM59, dual-axis controllers:
PRM26)
0: PO output occurs at normal movement completion.
1: PO output occurs when movement command is received.
2: Point zone output
(PO output occurs when the current position enters the point data (registered
at the controller) ± position judgment parameter range.)
3: Movement point zone output
(PO output occurs when the current position enters the point data registered
at the controller, and the point movement command's (ABS-PT, INC-PT)
movement point data ± position judgment parameter range.)
MEMO
The movement point zone output function is supported by the following controller
versions.
ERCX, SRCX : Ver. 13.64 or later
DRCX
: Ver. 18.64 or later
SRCP, SRCD : Ver. 24.21 or later
SRCP30 : Ver. 24.30H or later
Output example
PO204
PO203
PO202
PO201
PO200
(25)
(24)
(23)
(22)
(21)
(20)
P0
OFF
OFF
OFF
OFF
OFF
OFF
P1
OFF
OFF
OFF
OFF
OFF
ON
P7
OFF
OFF
OFF
ON
ON
ON
P31
OFF
ON
ON
ON
ON
ON
P63
ON
ON
ON
ON
ON
ON
PO No. PO205
Point No.
! CAUTION
When using PO as an output signal that indicates the target position’s point
number for point movement commands (ABS-PT, INC-PT):
• If moving the robot to point 0 with at the first point movement command
which is executed after turning the controller on, all the PO200 to PO205
signals still remain off (because P0 = 000000 (binary)) even after the robot has
moved to point 0. This means that the PO200 to PO205 signal statuses do not
change even after the robot has moved to P0, so no information is available
to indicate whether the robot motion to P0 is complete (or whether the movement command was received). This should be kept in mind when moving the
robot to point 0.
When using PO as an output signal that indicates the corresponding point number at the point zone output function or the movement point zone output function:
• If outputting point 0 (P0) as the corresponding point for the point zone output function or the movement point zone output function, all the PO200 to
PO205 signals remain off (because P0 = 000000 (binary)). This means that the
PO200 to PO205 signal statuses do not change even after the robot has entered the zone specified by P0. This should be kept in mind when monitoring
P0.
46
CHAPTER2 CC-Link Unit
MEMO
When using PO as an output signal that indicates the target position's point number
for point movement commands (ABS-PT, INC-PT):
• When a point movement is received through a parallel I/O, the target position's
point number is output to the corresponding parallel I/O (PO0 to PO5). When
received through a serial I/O such as a CC-Link, the target position's point number is output to the corresponding serial I/O (PO200 to PO205).
• All PO outputs are reset (OFF) when a program reset is performed.
When using PO as an output signal that indicates the corresponding point number at
the point zone output function:
• The corresponding point number for the point zone output function is output to
both the corresponding parallel I/O (PO0 to PO5) and the serial I/O (PO200 to
PO205). In the SRCP/SRCD series, however, the point number is only output to
the serial I/O.
• All PO outputs are reset (OFF) when a program reset is performed.
When using PO as an output signal that indicates the corresponding point number at
the movement point zone output function:
• The corresponding point number for the movement point zone output function is
output to both the corresponding parallel I/O (PO0 to PO5) and the serial I/O
(PO200 to PO205). In the SRCP/SRCD series, however, the point number is only
output to the serial I/O.
• Movement points are reset immediately after a controller power on, and all PO
outputs are therefore turned off at that time. Movement points are also reset if a
program reset is performed, and the movement point zone PO outputs are reset
(OFF) at that time as well.
■ Return-to-origin complete output / Zone output 0 (ORG-O / ZONE0)
This output notifies that return-to-origin operation is complete. When Zone 0 output
is enabled with the Zone output selection parameter (single-axis controllers: PRM53,
dual-axis controllers: PRM24), the ORG-O output is used as the output port of Zone
0 (ZONE0).
The ORG-O output is an output signal having the same function as device No. RXn6.
For details on the output signal, refer to "Return-to-origin status output (ORG-O)" in
"2-7-8 Dedicated output".
The ZONE0 output is an output signal having the same function as device No. RXn1.
For details on the output signal, refer to "Zone output (ZONE0 to ZONE3)" in "2-78 Dedicated output" and also to "Zone output selection" described in the controller
user's manual.
■ Servo status output / Zone output 1 (SRV-O / ZONE 1)
This is the servo status output. When Zone 1 output is enabled with the Zone output
selection parameter (single-axis controllers: PRM53, dual-axis controllers: PRM24),
the SRV-O output is used as the output port of Zone 1 (ZONE1).
The SRV-O output is an output signal having the same function as device No. RXn0.
For details on the output signal, refer to "Servo status output (SRV-O)" in "2-7-8
Dedicated output".
The ZONE1 output is an output signal having the same function as device No. RXn2.
For details on the output signal, refer to "Zone output (ZONE0 to ZONE3)" in "2-78 Dedicated output" and also to "Zone output selection" described in the controller
user's manual.
47
CHAPTER2 CC-Link Unit
2-9-5
Timing chart
This section shows timing charts for the operations that are added by changing the I/O
assignment.
■ Jog movement (JOG+, JOG-)
CHG
(Mode switch input)
Data retention
Axis designation data *
SI213, SI214
JOG+/JOG
(JOG movement command)
END
BUSY
READY
Robot movement
Robot movement
30ms or more 30ms or less 1ms or less
30ms or less 1ms or less
* For dual-axis controllers only. In the case of dual-axis controllers, the X-axis is usually
used for jog movement. However, the Y-axis can be specified with SI213 and SI214
by enabling PRM10 (Control axis selection with I/O command).
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
Turn on the CHG signal.
To specify the movement axis by a dual-axis controller, input the axis designation data to SI213 and SI214.
• The input status specified here must be kept unchanged until step (4) is
complete. If this input status is changed, the controller might misrecognize
the data.
Turn on the JOG+ (or JOG-) input signal while the CHG signal is on.
The END signal turns off and the BUSY signal turns on, indicating that the
controller received the jog movement command.
The robot moves in jog mode as long as the JOG+ (or JOG-) input signal is on.
Turn off the JOG+ (or JOG-) input signal.
Wait until the BUSY signal turns off.
The BUSY signal turns off. The END signal should be on at this point, indicating that the jog movement is normally complete.
! CAUTION
• If the CHG signal is switched during execution of a jog movement command
(JOG+, JOG-), the robot comes to an error stop and the END signal remains
off.
• When specifying the axis, the SI213 and SI214 status must be checked beforehand. (Refer to "PRM10: Control axis selection with I/O command" in the
DRCX controller user's manual.
48
CHAPTER2 CC-Link Unit
■ Point data write (PSET)
CHG
(Mode switch input)
PSET
(Point data write command)
PI200 to 205 *
(Point number designation inputs
200 to 205)
Data retention
END
BUSY
READY
Point data write
Point data writing
30ms or more 30ms or less 1ms or less
30ms or less
* The number of point number outputs that can be used depends on the I/O assignment type.
Precondition: The CHG signal is on before and during point data writing (until the
following procedure is complete).
(1)
(2)
(3)
(4)
(5)
(6)
Designate the point number input (PI200 to PI205) to write the point data.
• The point numbers that can be used depend on the I/O assignment type.
Refer to the I/O assignment list in “2-9-2 Changing the I/O assignment”.
• The input status for designating the point number must be kept unchanged
until step (3) is complete. If this input status is changed, the controller
might misrecognize the data.
After 30ms or more has elapsed, turn on the PSET.
The END signal turns off and the BUSY signal turns on, indicating that the
controller received the point data write command.
Turn off the PSET.
Wait until the BUSY signal turns off.
The BUSY signal immediately turns off since point data writing is already
finished. The END signal should be on at this point, indicating that the point
data writing was completed normally.
49
CHAPTER2 CC-Link Unit
■ Target position's point number output (PO)
(1) Outputting the point number at the timing that movement is normally
completed
Data retention q
Axis designation data *1
SI213, SI214
ABS-PT/INC-PT
(Point movement command)
Data retention w
Command q
PO200 to 205 *2
(Target position's point number
outputs 200 to 205)
Command w
Point number output q
Point number output w
END
BUSY
Movement
q
Robot movement
30ms or more
30ms or less 1ms or less
Movement
w
30ms or more
1ms or less
30ms or less 1ms or less
1ms or less
*1 For dual-axis controllers only. In the case of dual-axis controllers, all axes are usually
used for movement. However, the desired axis can be specified with SI213 and SI214
by enabling PRM10 (Control axis selection with I/O command).
*2 The number of point number outputs that can be used depends on the I/O assignment type.
Precondition: 1) The following steps are explained assuming that the I/O assignment selection parameter (single-axis controllers: PRM59, dualaxis controllers: PRM26) is set to 30.
When I/O assignment selection parameter = 30
(single-axis controllers: PRM59, dual-axis controllers: PRM26)
I/O assignment type
Type 3 (point teaching type)
Permissible number of movement points 64 points
Point output selection
Point No. output to PO when movement ends normally
2) The point numbers of the target positions are designated before
running a point movement command (ABS-PT, INC-PT).
[Point movement command execution q]
(1) To specify the movement axis by a dual-axis controller, input the axis designation data to SI213 and SI214.
• The input status specified here must be kept unchanged until step (3) is complete. If this input status is changed, the controller might misrecognize the
data.
(2) Turn on the ABS-PT (or INC-PT).
(3) The END signal turns off and the BUSY signal turns on, indicating that the
controller received the point movement command.
(4) Turn off the ABS-PT (or INC-PT).
(5) Wait until the BUSY signal turns off.
(6) The BUSY signal turns off. The END signal should be on at this point, indicating that the point movement is normally finished.
(7) When the END signal is on in step (6), the target position's point number is
output from the specified point number (PO200 to PO205).
• The output status of the target position's point number is retained until execution of the next point movement command is complete.
50
CHAPTER2 CC-Link Unit
↓
[Point movement command execution w]
(8) Execute the next point movement command.
(9) Point movement ends.
(10) The END signal turns on. The previous target position's point number being
output from the specified point number (PO200 to PO205) is cleared and the
current target position's point number is then output.
! CAUTION
• If moving the robot to point 0 with a point movement command that is first
executed after turning on the controller, all of PO200 to PO205 still remain off
(because P0 = 000000 (binary)) even after the robot has moved to point 0. This
means that the PO200 to PO205 status does not change even after the robot
has moved to P0, so no information is available to indicate whether the robot
motion to P0 is complete (or whether the movement command was received).
This should be kept in mind when moving the robot to point 0.
• When specifying the axis, the SI213 and SI214 status must be checked beforehand. (Refer to "PRM10: Control axis selection with I/O command" in the
DRCX controller user's manual.
51
CHAPTER2 CC-Link Unit
(2) Outputting the point number at the timing that a movement command
is received
Data retention q
Axis designation data *1
SI213, SI214
ABS-PT/INC-PT
(Point movement command)
Data retention w
Command q
PO200 to 205 *2
(Target position's point number
outputs 200 to 205)
Command w
Point number output q
Point number output w
END
BUSY
Movement
q
Robot movement
30ms or more
30ms or less 1ms or less
Movement
w
30ms or more
1ms or less
30ms or less 1ms or less 1ms or less
*1 For dual-axis controllers only. In the case of dual-axis controllers, all axes are usually
used for movement. However, the desired axis can be specified with SI213 and SI214
by enabling PRM10 (Control axis selection with I/O command).
*2 The number of point number outputs that can be used depends on the I/O assignment type.
Precondition: 1) The following steps are explained assuming that the I/O assignment selection parameter (single-axis controllers: PRM59, dualaxis controllers: PRM26) is set to 130.
When I/O assignment selection parameter = 130
(single-axis controllers: PRM59, dual-axis controllers: PRM26)
I/O assignment type
Type 3 (point teaching type)
Permissible number of movement points 64 points
Point output selection
Point No. output to PO when movement command is received
2) The point numbers of the target positions are designated before
running a point movement command (ABS-PT, INC-PT).
[Point movement command execution q]
(1) To specify the movement axis by a dual-axis controller, input the axis designation data to SI213 and SI214.
• The input status specified here must be kept unchanged until step (3) is complete. If this input status is changed, the controller might misrecognize the
data.
(2) Turn on the ABS-PT (or INC-PT).
(3) The END signal turns off and the BUSY signal turns on, indicating that the
controller received the point movement command.
(4) When the BUSY signal turns on in step (3), the target position's point number
is output from the specified point number (PO200 to PO205).
• The output status of the target position's point number is retained until the
next point movement command is received.
(5) Turn off the ABS-PT (or INC-PT).
(6) Wait until the BUSY signal turns off.
(7) The BUSY signal turns off. The END signal should be on at this point, indicating that the point movement finished normally.
↓
52
CHAPTER2 CC-Link Unit
[Point movement command execution w]
(8) Execute the next point movement command.
(9) When the controller received the point movement command and the BUSY
signal turned on, the previous target position's point number being output from
the specified point number (PO200 to PO205) is cleared and the current target
position's point number is then output.
! CAUTION
• If moving the robot to point 0 by specifying it with a point movement command that is first executed after turning on the controller, all of PO200 to
PO205 still remain off (because P0 = 000000 (binary)) even after the robot has
moved to point 0. This means that the PO200 to PO205 status does not change
even after specifying P0 as the target position, so no information is available to
indicate whether the movement command to P0 was received. This should be
kept in mind when moving the robot to point 0.
• When specifying the axis, the SI213 and SI214 status must be checked beforehand. (Refer to "PRM10: Control axis selection with I/O command" in the
DRCX controller user's manual.
53
CHAPTER2 CC-Link Unit
(3) Outputting the corresponding point number by the point zone output
function
Zone outputs (ZONE 0, ZONE 1) are also explained here.
PO
203
(23)
PO
202
(22)
PO
201
(21)
PO
200
(20)
m-No. is output as binary value
PO200 to 203
(Target position's point number
outputs 200 to 203)
PO
203
(23)
PO
202
(22)
PO
201
(21)
PO
200
(20)
OFF
OFF
OFF
OFF
Point output
(point m)
PO
203
(23)
PO
202
(22)
PO
201
(21)
PO
200
(20)
n-No. is output as binary value
Point output
(point n)
ZONE0 (Zone output 0)
*Positive logic
ZONE1 (Zone output 1)
*Positive logic
Pm
P900
P900
P901
P901
P901 P902
P902
P902
Pn
P903
P903
P903
Current robot position
* For single-axis type
X+
a
a
Point zone output range
Point zone output range
Zone output range
Zone output range
P901
Y+
P903
Pm
Current robot position
* For dual-axis type
Pn
b
X+
b
a
q
P900
a
w
e
P902
t
r
a: X-axis position judgment parameter range
b: Y-axis position judgment parameter range
(In this case, this is the OUT valid position range.)
* The number of target point number outputs that can be used depends on I/O assignment type.
Precondition: 1) The following steps are explained assuming that the I/O assignment selection parameter (single-axis controllers: PRM59, dualaxis controllers: PRM26) is set to 221.
When I/O assignment selection parameter = 221
(single-axis controllers: PRM59, dual-axis controllers: PRM26)
I/O assignment type
Type 2 (Point No. output type)
Permissible number of movement points 16 points
Point output selection
Point zone output
Point zone judgment method
(position judgment parameter)
OUT valid position
2) The Zone 0 output and Zone 1 output are enabled and set to positive logic output by the Zone output selection parameter (singleaxis controllers: PRM53, dual-axis controllers: PRM24).
(1)
Target position's point number outputs PO200 to PO203 are off since the current robot position is not within the point zone output range. ZONE 0 and
ZONE 1 output signals are also off since the robot does not yet enter the zone
output range.
54
CHAPTER2 CC-Link Unit
(2)
(3)
(4)
(5)
Outputs the corresponding point number through PO200 to PO203 since the
current robot position is within the point zone output range (Pm ± OUT valid
position range). ZONE 0 and ZONE 1 output signals are still off since the
robot does not yet enter the zone output range.
As with (1), all the target position's point number outputs PO200 to PO203,
ZONE 0 signal and ZONE 1 output signal are off.
ZONE 0 output signal turns on since the current robot position is within the
zone output range (P900 to P901). (ZONE 1 signal remains off since the robot
is not within the zone output range of P902 to P903). At this point, the target
position's point number outputs PO200 to PO203 are still off since the robot is
not within the point zone output range.
Outputs the corresponding point number through PO200 to PO203 since the
current robot position is within the zone output range (P902 to P903) and also
within the point output range (Pn ± OUT valid position range). At this point,
ZONE 1 output signal turns on. (ZONE 0 output signal turns off since the
robot is not within the zone output range of P900 to P901).
MEMO
• When using an option unit, the corresponding point number for the point zone
output function is output to both the corresponding parallel I/O (PO0 to PO5) and
the serial I/O (PO200 to PO205). In the SRCP/SRCD series, however, the point
number is only output to the serial I/O.
• In controllers of the following versions, the position judgment parameter for selecting the point judgment method can be set to either "OUT valid position" or "Positioning-completed pulse" (this is specified in the "thousands" place of the I/O assignment selection parameter). In controllers prior to the following versions, the
point zone judgment method (specified by the position judgment parameter) can
only be set to "OUT valid position".
ERCX, SRCX : Ver. 13.64 or later
DRCX : Ver. 18.64 or later
SRCP, SRCD : Ver. 24.21 or later
SRCP30 : Ver. 24.30H or later
• The "OUT valid position" can be changed by parameter setting (single-axis controllers: PRM20, dual-axis controllers: PRM56 for X-axis, PRM96 for Y-axis).
• The "Positioning-completed pulse" can be changed parameter setting (single-axis
controllers: PRM6, dual-axis controllers: PRM53 for X-axis, PRM93 for Y-axis).
! CAUTION
• When the current robot position is within two or more point zone output ranges,
the smaller or smallest point number is output.
Example : If the current robot position is within two point output ranges
specified by P2 and P5, then P2 is output.
• If the current robot position is not within any point output range, all of PO200
to PO205 turn off.
• A 10ms sampling time is needed for position monitoring, so the point zone
output might not be detected when moving the robot at high speeds.
• For point zone output and zone output, PO and ZONE0 to ZONE3 are output
only when the all axes of the robot are within the output range specified for
each zone.
• If outputting point 0 (P0) as the corresponding point for the point zone output
function, all of PO200 to PO205 remain off (because P0 = 000000 (binary)). This
means that the PO200 to PO205 status does not change even after the robot
has entered the zone specified by P0. This should be kept in mind when monitoring P0.
55
CHAPTER2 CC-Link Unit
(4) Outputting the corresponding point number by the movement point
zone output function
Zone outputs (ZONE 0) are also explained here.
PO
203
(23)
PO
202
(22)
PO
201
(21)
PO
200
(20)
PO
203
(23)
PO
202
(22)
PO
201
(21)
PO
200
(20)
PO
203
(23)
PO
202
(22)
PO
201
(21)
PO
200
(20)
OFF
OFF
OFF
OFF
OFF
ON
ON
OFF
OFF
OFF
OFF
OFF
PO200 to 203 *
(Target position's point number
outputs 200 to 203)
Point output
(point 6)
ZONE0 (Zone output 0)
*Positive logic
P1
P6
P902
P
P902
900
P903
P903
P901
Current robot position
* For single-axis type
X+
a
a
a
a
Point zone output range
Zone output range
Y+
P901
P1
P6
b
b
Current robot position
a
a
q
X+
b
b
* For dual-axis type
a
w
a
P900
e
r
a: X-axis position judgment parameter range
b: Y-axis position judgment parameter range
(In this case, this is the OUT valid position range.)
* The number of target point number outputs that can be used depends on I/O assignment type.
Precondition: 1) The following steps are explained assuming that the I/O assignment selection parameter (single-axis controllers: PRM59, dualaxis controllers: PRM26) is set to 321.
When I/O assignment selection parameter = 321
(single-axis controllers: PRM59, dual-axis controllers: PRM26)
I/O assignment type
Type 2 (Point No. output type)
Permissible number of movement points 16 points
Point output selection
Movement point zone output
Point zone judgment method
(position judgment parameter)
OUT valid position
2) The Zone 0 output is enabled and set to positive logic output by the
Zone output selection parameter (single-axis controllers: PRM53,
dual-axis controllers: PRM24).
3) Set the movement point as P6.
(1)
(2)
Although the robot is within the P1 ± OUT valid position range (point zone
output range), all the PO200 to PO203 target position point number outputs are
off because P1 is not the movement point. Moreover, the ZONE 0 output is
also off because the robot is not within the specified zone output range.
All the PO200 to PO203 target position point number outputs are off because
the robot is not within the point zone output range. Moreover, the ZONE 0
output is also off because the robot is not within the specified zone output
range.
56
CHAPTER2 CC-Link Unit
(3)
(4)
The corresponding point number P6 is output to PO200 through PO203 (P201,
P202 are on; P200, P203 are off) because the robot is within the P6 ± OUT
valid position range (point zone output range), and because P6 is the movement point. ZONE 0 remains off at this time because the robot is not within the
specified zone output range.
The ZONE 0 output turns on because the robot is within the specified zone
output range (P900 to P901). All the PO200 to PO203 target position point
number outputs are off at this time because the robot is not within any point
zone output range.
MEMO
• The movement point zone output function is supported by the following controller
versions.
ERCX, SRCX : Ver. 13.64 or later
DRCX : Ver. 18.64 or later
SRCP, SRCD : Ver. 24.21 or later
SRCP30 : Ver. 24.30H or later
• When using an option unit, the corresponding point number for the movement point
zone output function is output to both the corresponding parallel I/O (PO0 to PO5)
and the serial I/O (PO200 to PO205). In the SRCP/SRCD series, however, the point
number is only output to the serial I/O.
• The movement point number specified just prior to movement START by point
movement command (ABS-PT, INC-PT) is registered as the movement point.
• Because movement points are reset immediately after a controller power on, all PO
outputs turn off. Movement points are also reset when the RESET command is
executed, and movement point zone outputs by PO are cleared.
• The position judgment parameter for selecting the point zone judgment method can
be set to either "OUT valid position" or "Positioning-completed pulse" (this is specified in the "thousands" place of the I/O assignment selection parameter).
• The "OUT valid position" can be changed by parameter setting (single-axis controllers: PRM20, dual-axis controllers: PRM56 for X-axis, PRM96 for Y-axis).
• The "Positioning-completed pulse" can be changed parameter setting (single-axis
controllers: PRM6, dual-axis controllers: PRM53 for X-axis, PRM93 for Y-axis).
! CAUTION
• All the PO200 to PO205 outputs are off when the robot is not within the point
zone output range.
• A 10ms sampling time is needed for position monitoring, so the point zone
output may not be detected during high-speed robot motion.
• For movement point zone output and zone output, PO and ZONE0 to ZONE3
are output only when the all axes of the robot are within the output range
specified for each zone.
• When outputting point 0 (P0) as the corresponding point for the movement
point zone output function, all the PO200 to PO205 outputs remain off (because P0 = 000000 (binary)). Therefore, the PO200 to PO205 statuses do not change
even after the robot has entered the zone specified by P0. This should be kept
in mind when monitoring P0.
57
CHAPTER2 CC-Link Unit
2-10
Robot language
The robot language expanded by using in the CC-Link unit.
2-10-1
MOVF
Function:
Format:
Example:
Moves until the specified DI or SI No. is input.
MOVF <point no.> <DI or SI No.> <input status>
MOVF 1,2,1
This command moves the robot towards P1, ends movement when D12
turns ON, and proceeds to the next step.
Explanation: MOVF is used when searching for the target position with sensors, etc.
The robot starts movement when all axes enter the positioning-complete
pulse range, and stops when the SI and DI conditions are met. Even if the
SI or DI conditions are not met, the command ends at the stage the robot
reaches the specified point, and proceeds to the next step.
(1) Point numbers
Point numbers are identifying numbers assigned to 1,000 points in a
range from 0 to 999. These point numbers are used to create point
data in point mode. As a special usage method, when a character called
‘P’ is input here, a point variable defined by the P character is set in
the point No.
(2) DI or SI numbers
Specify one from among serial general-purpose inputs 200 - 231 (32
points) or general-purpose inputs 0 - 15 (16 points)*.
(3) Input status
Here, “1” means ON, and “0” means OFF.
Other:
• The speed during execution of the MOVF statement can be set with
the MOVF speed parameter. This has no effect on speed in OPRT
mode.
* 0 to 7 (8 points) for the SRCP/SRCD series controllers
58
CHAPTER2 CC-Link Unit
2-10-2
JMPF
Function:
Jumps to the specified label of the specified program when the jump condition input matches the value that was set.
Format:
JMPF <label No.> <program No.> <input condition value>
Example:
JMPF 12,3,5
Jumps to label 12 of program 3 when the condition jump input value is 5.
If not, proceeds to the next step.
Explanation: JMPF is a command to control the program flow according to the condition jump input.
(1) Label No.
The label No. is a number defined by the character L, and signifies
the jump destination. This number can be specified from 0 to 255.
(2) Program No.
The program numbers are numbers assigned to 100 programs ranging
from 0 to 99.
(3) Input condition value
This value sets the condition for the jump. A general-purpose input or
a serial general-purpose input is considered a binary input value, and
the jump is performed if it matches the input value conditions. The
number of points that can be sub-grouped by input condition depends
on the number of conditional input points. The number of conditional
input points is set by the conditional input point parameter (singleaxis controllers: PRM8, dual-axis controllers: PRM0).
Others:
• The conditional input point parameters have been expanded as follows.
Input range:
1 - 8, 11 - 18
Initial value:
4
Conditional input points - general-purpose input and condition range
Conditional
input points
General-purpose inputs used
1
2
3
4
5
6
7
8
11
12
13
14
15
16
17
18
DI0
DI0-DI1
DI0-DI2
DI0-DI3
DI0-DI4
DI0-DI5
DI0-DI6
DI0-DI7
SI200
SI200-SI201
SI200-SI202
SI200-SI203
SI200-SI204
SI200-SI205
SI200-SI206
SI200-SI207
59
Settable conditional input range
0-1
0-3
0-7
0-15
0-31
0-63
0-127
0-255
0-1
0-3
0-7
0-15
0-31
0-63
0-127
0-255
CHAPTER2 CC-Link Unit
2-10-3
JMPB
Function:
Jumps to the specified label when the specified general-purpose input or
memory input or serial general-purpose input is on (or off).
Format:
JMPB <label No.> <DI or MI or SI No.> <input status>
Example:
JMPB 12,8,1
Jumps to level 12 when D18 is ON. If not, proceeds to the next step.
Explanation: JMPF is a command to control the program flow according to the general-purpose input or memory input or serial general-purpose input.
(1) Label No.
The label No. is a number defined by the character L, and signifies
the jump destination. This number can be specified from 0 to 255.
(2) DI or MI or SI No.
Specify 1 number from among the general-purpose inputs 0 - 15 (16
points)* or memory input 100 -147 (48 points) or the serial generalpurpose inputs 200- 231 (32 points).
(3) Input status
Here, “1” means ON, and “0” means OFF.
* 0 to 7 (8 points) for the SRCP/SRCD series controllers
2-10-4
DO
Function:
Turns the general-purpose output or memory output or serial generalpurpose output on or off.
Format:
DO
<DO or MO or SO No.> <Output status>
Example:
DO
3,1
Sets DO3 to ON.
Explanation: The DO command turns the general-purpose output or memory output or
serial general-purpose output ON or OFF.
(1) DO or MO or SO No.
Specify one from among the general-purpose outputs 0 - 12 (13
points)* or memory output 100 -131 (32 points) or the serial generalpurpose outputs 200- 231 (32 points).
(2) Output status
Here, “1” means ON, and “0” means OFF.
* 0 to 4 (5 points) for the SRCP/SRCD series controllers
60
CHAPTER2 CC-Link Unit
2-10-5
WAIT
Function:
Waits until the specified general-purpose input or memory input or serial
general-purpose input sets to the specified status.
Format:
WAIT <DI or MI or SI No.> <Input status>
Example:
WAIT 5,1
Waits until DI5 sets to ON.
Explanation: The WAIT command adjusts the timing according to the status of the
general-purpose input or memory input or serial general-purpose input.
(1) DI or MI or SI numbers
Specifies one from among the general-purpose inputs 0 - 15 (16
points)* or memory input 100 -147 (48 points) or the serial generalpurpose outputs 200- 231 (32 points).
(2) Input status
Here, “ 1” means the input is ON, and “0” means the input is OFF.
* 0 to 7 (8 points) for the SRCP/SRCD series controllers
61
CHAPTER2 CC-Link Unit
2-11
Emulated Serialization on parallel DIO
This is a function to directly send the input from the master sequencer (PLC) to the
external parallel I/O, or to directly send an external parallel I/O input to a master sequencer (PLC). An I/O port set for this function, can be controlled by the master sequencer (PLC), independently of the robot program so outputs can be handled as if from
a separate remote I/O station.
This function is selected on the HPB, and can be set for any I/O. The SI200 - SI212*1
inputs match the DO0 - DO12*2 outputs, and the DI0 - DI15*3 inputs match the SO200
- SO215*4 outputs. (Emulated serialization cannot be performed on SI213 - SI231*5.)
Normal
Controller
Sequencer (PLC)
SI200-231
DI0-15 *3
Sensors, etc.
Sequencer (PLC)
SO200-231
DO0-12 *2
Grippers, etc.
CC-Link
External I/O
Emulated serialization
Controller
SI200-212 *1
Sequencer (PLC)
Sequencer (PLC)
SO200-215 *
4
DI0-15
*3
Sensors, etc.
2
Grippers, etc.
DO0-12 *
External I/O
CC-Link
More specifically, when emulated serialization is only for DI1, the DI1 status is
output to SO201. Output of SO201 with the DO statement is disabled at this time.
DI0, DI2 - DI15 and SO200, SO202 - SO215 can be used as normal input/outputs.
* The DO statement is invalid on output ports that used emulated serialization on a
parallel I/O.
* Do not make simultaneous function settings with parameters such as for emulated
serialization parallel I/O settings, origin return end action selection and servo status output selection, and alarm number output selection since the functions will not
operate normally.
*1:
*2:
*3:
*4:
*5:
SI200 to SI204 when the SRCP/SRCD series controllers are used.
DO0 to DO4 when the SRCP/SRCD series controllers are used.
DI0 to DI7 when the SRCP/SRCD series controllers are used.
SO200 to SO207 when the SRCP/SRCD series controllers are used.
SI205 to SI231 when the SRCP/SRCD series controllers are used.
62
CHAPTER2 CC-Link Unit
1)
Press F3 (SYS) on the initial screen.
[MENU]
select menu
1EDIT2OPRT3SYS 4MON
2)
Press F4 (next) to switch to the function display. When the function display
[SYS]
appears, then press F2 (OPT).
select menu
1SAFE2OPT 3UTL 4next
3)
Press F4 (next) to switch the function
display. To directly send the external parallel I/O input to the master sequencer
(PLC) press F1 (D→SO). To directly
send the input from the master sequencer
(PLC) to the external parallel I/O, press
F2
4)
5)
6)
[SYS-OPT]
select menu
1D→SO2S→DO3
4next
(S→DO).
This is the screen when F1 (D→SO)
was selected above in step 3). The DI15 DI0 current settings appear on the screen
from the left side. Here, “0” indicates
normal status, and “1” indicates a emulated serialization setting.
To change a setting, press the function key
displaying the DI No. you want to set. If
the DI No. you want to set is not shown,
just press the F4 (next) as many times
as needed to select DI3 - DI15.
This is the screen when F2 (S→DO)
was selected above in step 3). The DO12
- DO0 current settings appear on the
screen from the left side. Here, “0” indicates normal status, and “1” indicates a
emulated serialization setting.
To change a setting, press the function key
displaying the DI No. you want to set. If
the DI No. you want to set is not shown,
just press the F4 (next) as many times
as needed to select DO3 - DO12.
Press the ESC key to return to the screen
in step 3).
[SYS-OPT-D→SO]
DI 00001111 00000000
DI→SO connect
1DI0 2DI1 3DI2 4next
[SYS-OPT-S→DO]
DO
00011 00000000
SI→DO connect
1DO0 2DO1 3DO2 4next
[SYS-OPT]
select menu
1D→SO2S→DO3
63
4next
CHAPTER2 CC-Link Unit
2-12
Remote command
When the remote register is used, the message command can be issued directly from the
sequencer (PLC). The high-ranked commands such as MOVD command (movement
command which directly specifies the position coordinates), which must use RS-232C
unit conventionally, can be easily executed. The method to use these commands is explained in this section.
2-12-1
Remote command specifications
The following functions are assigned to the remote register.
OUTPUT (Remote→Master)
Address
Description
RWrn
Status
RWrn+1
Reserved
RWrn+2
RWrn+3
RWrn+4
Command response
RWrn+5
RWrn+6
RWrn+7
Address
RWwn
RWwn+1
RWwn+2
RWwn+3
RWwn+4
RWwn+5
RWwn+6
RWwn+7
INPUT (Master→Remote)
Description
Execution command
Command option
n: Value determined by station number setting.
■ The remote command is executed by setting RWwn and RWwn+1 with the command
code desired to execute. When the controller receives the command, it will execute
the process, and inform the result (status) to the master sequencer (PLC) side via
RWrn. When the command is ended, set RWwn to 0, and clear the status. After the
status is cleared, the next command can be executed.
■ The command is sometimes provided with options on the remote command. The option data is set at RWwn+2 to RWwn+7. Since the number of options, size and setting
address of the command option are different in each command, refer to "2-12-3 Remote command details (robot operation)" and the subsequent sections.
Similarly, some commands return the data to the master sequencer (PLC) side as the
response. In this case, the response data is set at RWrn+2 to RWrn+7. Like the command option, the number of options, size and setting address of the response data are
also different in each command.
* Even if the data is set at the register not defined as any command option when the command is executed, there is not
any problem. (It is unnecessary to clear the not-defined register to 0.). Moreover, the register which is not defined as
the response data is not influenced during the command execution, and the register content before the command
execution is held.
■ It is necessary to set the command option to the register at the same time when or
before the command desired to execute is set.
■ The data is set with the binary code. If the data size exceeds 16 bits (1 word), set the
data of the upper-ranked bit at the higher address. (Little endian)
Example: To set 12345678 (hexadecimal) at the register of RWwn+2 and RWwn+3,
set 1234 (hexadecimal) at RWwn+3 and 5678 (hexadecimal) at RWwn+2.
■ RWrn+1 is the system reservation. When it is read, 0 is returned.
64
CHAPTER2 CC-Link Unit
2-12-2
Remote command & status value list
The remote command code and status code are expressed in the hexadecimal mode.
Remote Command
Remote Command
(RWwn+1, RWwn)
0000xxxx
0001xxxx
Meaning of command
The command of the code xxxx is executed.
The command of the code xxxx is executed
with the current position information indicated
at RWrn+4 to RWrn+7.
Status
Status value (RWrn)
0000
0100
0200
40xx
80xx
81xx
Meaning of status
Command ready
Command executing
Command normal end
Error occurrence
(xx: Error code)
X axis alarm occurrence
(xx: Alarm code)
Y axis alarm occurrence
(xx: Alarm code)
1. Robot movement
1.
2.
3.
4.
5.
Remote Command (RWwn)
Command details
Code
0101 Return-to-origin execution
0102 Program reset
0103 Automatic operation start
0104 Step operation start
0105 Servo status change
6.
0106
JOG movement (inching)
7.
0107
JOG movement
8.
0108
Direct position specification
movement execution
No.
Command option
register
Option
Axis
RWwn+2
Axis
Status
Axis
Movement direction
Axis
Movement direction
Axis
Speed
X axis position
Y axis position
Position specification
movement execution
9.
0109
10.
010A Movement stroke specification
movement execution
11.
010B General-purpose input
response movement execution
65
Axis
Point number
Speed
Axis
Point number
Speed
Axis
Point number
DI/SI number
0 or 1
RWwn+2
RWwn+3
RWwn+2
RWwn+3
RWwn+2
RWwn+3
RWwn+2
RWwn+3
RWwn+5,
RWwn+4
RWwn+7,
RWwn+6
RWwn+2
RWwn+3
RWwn+4
RWwn+2
RWwn+3
RWwn+4
RWwn+2
RWwn+3
RWwn+4
RWwn+5
Command response
response
register
CHAPTER2 CC-Link Unit
No.
12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
32.
Remote Command (RWwn)
Command option
register
Option
Command details
Code
RWwn+2
010C Pallet work position specification Axis
movement execution
Pallet work position RWwn+3
RWwn+4
Speed
RWwn+2
Axis
010D Position specification arch
motion definition
Specified position RWwn+3
RWwn+2
Axis
010E Distance specification arch
motion definition
Specified distance RWwn+3
DO/MO/SO number RWwn+2
010F General-purpose output or
memory output status change
RWwn+3
0 or 1
DI/MI/SI number RWwn+2
0110 General-purpose input or
memory input wait
0 or 1
RWwn+3
Time
RWwn+2
0111 Specified time waiting
Line number
RWwn+2
0112 Matrix definition
Array number
RWwn+3
Pallet number
RWwn+4
RWwn+2
0113 Movement matrix specification Pallet number
Point number
RWwn+2
0114 Point variable P definition
Addition value
RWwn+2
0115 Addition of specified value
to point variable P
Subtraction value RWwn+2
0116 Subtraction of specified value
from point variable P
RWwn+2
0117 Arrangement element specification Arrangement
of counter arrangement variable C element No.
Counter value
RWwn+2
0118 Counter arrangement
variable C definition
Addition value
RWwn+2
0119 Addition of specified value to
counter arrangement variable C
011A Subtraction of specified value from Subtraction value RWwn+2
counter arrangement variable C
Counter value
RWwn+2
011B Counter variable D definition
Addition value
RWwn+2
011C Addition of specified value
to counter variable D
Subtraction value RWwn+2
011D Subtraction of specified value
from counter variable D
RWwn+2
011E Shift execution of position data Point number
Axis
RWwn+2
011F Linear interpolation
movement execution
Point number
RWwn+3
Speed
RWwn+4
Point number
RWwn+2
0120 Circular interpolation
movement execution
Speed
RWwn+3
Locus specification RWwn+4
66
Command response
response
register
CHAPTER2 CC-Link Unit
2. Data handling
DI/MI/SI number RWwn+2
DO/MO/SO number RWwn+2
Output status
0216
General-purpose input and
memory input status read
General-purpose output and
memory output status read
Specified parameter data read
Command response
response
register
RWrn+5,
X axis position
RWrn+4
RWrn+7,
Y axis position
RWrn+6
Program number RWrn+2
Step number
RWrn+2
Task number
RWrn+2
Point number
RWrn+2
Version value
RWrn+2
Axis number
RWrn+2
Emergency stop status RWrn+2
Servo status
RWrn+2
Return-to-origin status RWrn+2
Service mode status RWrn+2
Operation mode status RWrn+2
Array number
RWrn+2
Line number
RWrn+3
Matrix No.
RWrn+2
Point number
RWrn+2
Arrangement
RWrn+2
element No.
Counter arrangement RWrn+2
variable
Counter variable RWrn+2
X axis shift data RWrn+5,
RWrn+4
Y axis shift data RWrn+7,
RWrn+6
Input status
RWrn+2
Parameter number RWwn+2
0217
Specified point data read
Point number
Parameter value RWrn+3,
RWrn+2
X axis data
RWrn+5,
RWrn+4
Y axis data
RWrn+7,
RWrn+6
1.
Remote Command (RWwn)
Code
Command details
0201 Current position read
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
0202
0203
0204
0205
0206
0207
0208
0209
020A
020B
020C
020D
14.
15.
16.
18.
19.
020E Currently specified matrix No. read
020F Current point variable P read
0210 Arrangement element No. read
of currently specified C
Arrangement
0211 Counter arrangement
variable C read
element No.
0212 Current counter variable D read
0213 Current shift data read
20.
0214
21.
0215
22.
23.
No.
17.
Current program No. read
Current step No. read
Current task No. read
Current point No. read
ROM version No. read
Axis number read
Emergency stop status check
Servo status check
Return-to-origin status check
Service mode status check
Operation mode check
Matrix definition content read
67
Command option
register
Option
Axis
RWwn+2
Axis
Axis
RWwn+2
RWwn+2
Pallet number
RWwn+2
RWwn+2
RWwn+2
RWrn+2
CHAPTER2 CC-Link Unit
3. Utility
No.
1.
2.
3.
4.
Remote Command (RWwn)
Command option
Command details
register
Option
Code
0301 Execution program No. switching Program number RWwn+2
RWwn+2
Task number
0302 Execution task No. switching
Parameter number RWwn+2
0303 Parameter data write
Parameter data RWwn+5,
RWwn+4
RWwn+2
Point number
0304 Point data write
RWwn+3
Axis
RWwn+5,
X axis data
RWwn+4
RWwn+7,
Y axis data
RWwn+6
Command response
response
register
4. Special commands
No.
1.
2.
Remote Command (RWwn)
Code
Command details
0000 No execution (status clear)
0401 Response register initialization
68
Command option
register
Option
Initial value data RWwn+7,
RWwn+6,
RWwn+5,
RWwn+4,
RWwn+3,
RWwn+2
Command response
response
register
Initial status
RWrn+7,
RWrn+6,
RWrn+5,
RWrn+4,
RWrn+3,
RWrn+2
CHAPTER2 CC-Link Unit
2-12-3
Remote command details (robot operation)
(1)
Return-to-origin execution .................................................... Code 0101
The return-to-origin operation of all axes or specified axis is executed, or the return-to-origin status is judged. If the search system is selected for the origin-point
detection system, the return-to-origin operation is executed, and if the mark system is selected, the return-to-origin status is judged.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Axis
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Axis:
0 means all axes, 1 means X axis, and 2 means Y axis. On dualaxis controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 and 1 alone can be specified.
(Example)
Transmission example 1:
Return-to-origin is executed to all axes.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0101
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
Response example 2:
Origin incomplete occurs since the return-to-origin is not completed in the axis of the mark system.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
4020
MEMO
If any axis of the mark system and axis of the search system are mixed, it is necessary
to previously complete the return-to-origin of the axis of the mark system in order to
execute the return-to-origin of the axis of the search system. The return-to-origin of
the mark system is executed with HPB.
MEMO
If the return-to-origin is once executed after the robot cable is connected to the absolute battery, it is unnecessary to execute it again even if the power supply is turned
off. (As an exceptional example, it is necessary to execute the return-to-origin again
since the origin is incomplete if the absolute back-up function is made to be invalid or
if any parameter concerned with the origin is changed.)
69
CHAPTER2 CC-Link Unit
! CAUTION
In return-to-origin of the stroke end origin system, do not stop return-to-origin
operation during origin detection (mechanical limit in contact). The alarm stop
results from the overload of the controller, and it is necessary to turn ON the
power supply again.
! CAUTION
If return-to-origin of the stroke end origin system is inevitably repeated, provide
an interval of 5 seconds or more between the repeated operations.
70
CHAPTER2 CC-Link Unit
(2)
Program reset ......................................................................... Code 0102
Return the step of the program to the 1st step of the head program, and turn OFF all
DO0 to DO12*1, SO200 to SO231 and memory I/O. Moreover, also clear the point
variable "P" to 0. (Do not clear the counter variables "C" and "D".)
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Example)
Transmission example 1:
Execute the program reset.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0102
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
! CAUTION
At the output port which has simulatively serialized the parallel I/O, any output
does not vary even if the reset command is executed.
! CAUTION
If the return-to-origin completing operation selection parameter (single-axis
controllers:PRM33, dual-axis controllers:PRM2) is set to 1 or 3, DO4*2 will not
be turned OFF even if the reset command is executed. If the servo status output
s e l e c t i o n p a r a m e t e r ( s i n g l e - a x i s c o n t ro l l e r s : P R M 4 6 , d u a l - a x i s
controllers:PRM21) is set to 1, DO7*3 will similarly not be turned OFF even if
the reset command is executed.
MEMO
The head program is the program selected by switching the program which is finally
executed at HPB or POPCOM.
The head program is also switched when the communication command "@SWI" is
executed. Moreover, when the program data is loaded from the memory card to the
controller, it is sometimes switched.
*1: DO0 to DO4 when the SRCP/SRCD series controllers are used.
*2: DO5 when the DRCX series controllers are used.
*3: DO3 when the SRCP/SRCD series controllers are used.
71
CHAPTER2 CC-Link Unit
(3)
Automatic operation start ...................................................... Code 0103
The program is executed to the final step.
In the multi task program, all tasks are executed.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Example)
Transmission example 1:
Automatic operation is started.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0103
Response example 1:
It is executed to the final step.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
Response example 2:
The origin incomplete error occurs to interrupt the robot operation.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
4020
! CAUTION
If any endless program (in which it unconditionally return to the program head
from the final step) is executed, the response will stay at 0100 (command executing) since the program is not ended. In this case, the program is stopped by
inputting the stop command of the interlock, etc. or activating the emergency
stop to forcibly stop.
72
CHAPTER2 CC-Link Unit
(4)
Step operation start ............................................................... Code 0104
The program is executed by one step.
In the multi task program, the task selected at the time is executed.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Example)
Transmission example 1:
The step operation is started.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0104
Response example 1:
The step operation is completely executed.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
Response example 2:
The origin incomplete error occurs to interrupt the robot operation.
RWrn+7
0000
RWrn+6
0000
73
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
4020
CHAPTER2 CC-Link Unit
(5)
Servo status change .............................................................. Code 0105
The servo of all axes or specified axis is turned ON and OFF.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
(Details)
Axis:
Status:
RWwn+3
Status
RWwn+2
Axis
RWrn+3
RWrn+2
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
1 means servo-ON, and 0 means servo-OFF.
(Example)
Transmission example 1:
Servo-OFF is set for all axes.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0105
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
74
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(6)
JOG movement (inching) ....................................................... Code 0106
The specified axis moves in the specified direction at the stroke shown with the
following formula.
Movement stroke = 1 × (Teach movement data (%)*/100 (mm)
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
(Details)
Axis:
Direction:
RWwn+3
Direction
RWwn+2
Axis
RWrn+3
RWrn+2
1 means X axis, and 2 means Y axis.
On single-axis controllers, 1 alone can be specified.
0 means + direction, and 1 means - direction.
(Example)
Transmission example 1:
Y axis is moved only at the specified stroke in the - direction.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0001
0001
0000
RWwn
0106
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
! CAUTION
If the robot is the rotary axis, the unit is degree.
* Single-axis controllers: PRM26, dual-axis controllers: PRM12
75
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(7)
JOG movement ....................................................................... Code 0107
The specified axis continues moving in the specified direction at the movement
speed shown with the following formula until the interlock input is OFF or it reaches
the software limit.
Movement speed = 100 × (Teach movement data (%)*/100 (mm)
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
(Details)
Axis:
Direction:
RWwn+3
Direction
RWwn+2
Axis
RWrn+3
RWrn+2
1 means X axis, and 2 means Y axis.
On single-axis controllers, 1 alone can be specified.
0 means + direction, and 1 means - direction.
(Example)
Transmission example 1:
Y axis is moved only at the specified speed in the - direction.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0001
0001
0000
RWwn
0107
Response example 1:
It reaches the software limit, and is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
! CAUTION
If the robot is the rotary axis, the unit is degree.
! CAUTION
In the JOG movement, it is also regarded as the normal end that the movement
is stopped after the interlock input is OFF.
! CAUTION
Take care that the software limit is invalid in the origin incomplete state.
* Single-axis controllers: PRM26, dual-axis controllers: PRM12
76
CHAPTER2 CC-Link Unit
(8)
Direct position specification movement execution ............ Code 0108
It moves to the specified coordinate position.
RWwn+7
RWwn+6
Y axis position
Command option
RWwn+5
RWwn+4
X axis position
RWwn+3
Speed
RWwn+2
Axis
RWrn+7
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
RWrn+6
(Details)
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Speed:
It can be set at 100 intervals from 1 to 100, and 100=3000rpm if
the program execution speed parameter*1 is set to 100. (In this
case, the maximum speed setting parameter*2 is set to 3000.)
Axis position: The desired movement position is directly specified (unit: 0.01mm).
When the robot is set at the rotary axis, the unit of the movement
position is 0.01 degrees. When the axis is specified, the axis data
is free for any other axis not specified. Similarly, it does not matter
that the data of Y axis is free on single-axis controllers.
(Example)
Transmission example 1:
In the current position indication mode, it moves to the position of
X=50.37 and Y=45.55 at the 100% speed.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
11CB
0000
0001
0000
0064
0000
13AD
RWwn
0108
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
11CB
RWrn+5
0000
RWrn+4
13AD
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
Transmission example 2:
It moves to the position of Y=850.00 at the 50% speed.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
4C08
0000
0000
0001
0032
0002
0000
RWwn
0108
Response example 2:
The software limit over occurs.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
*1: Single-axis controllers: PRM30, dual-axis controllers: PRM17
*2: Single-axis controllers: PRM44, dual-axis controllers: PRM64 and PRM104
77
RWrn
401E
CHAPTER2 CC-Link Unit
(9)
Position specification movement execution ....................... Code 0109
The specified axis moves the position of the data of the point No. specified with
the number.
RWwn+7
RWwn+6
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
Speed
RWwn+3
Point number
RWwn+2
Axis
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Point number:This is the inherent number assigned to each of 1000 points as a
total from 0 to 999. To specify the point variable P, register 4095
(=0FFF (hexadecimal)).
Speed:
It can be set at 100 intervals from 1 to 100, and 100=3000rpm if
the program execution speed parameter*1 is set to 100. (In this
case, the maximum speed setting parameter*2 is set to 3000.)
(Example)
Transmission example 1:
It moves to the position of P123 at the speed 100%.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
007B
0000
0064
RWwn
0109
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
401E
Response example 2:
The software limit over occurs.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
*1: Single-axis controllers: PRM30, dual-axis controllers: PRM17
*2: Single-axis controllers: PRM44, dual-axis controllers: PRM64 and PRM104
78
CHAPTER2 CC-Link Unit
(10) Movement stroke specification
movement execution ............................................................. Code 010A
The specified axis moves from the current position by the data of the point number
specified.
RWwn+7
RWwn+6
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
Speed
RWwn+3
Point number
RWwn+2
Axis
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Point number:This is the inherent number assigned to each of 1000 points as a
total from 0 to 999. To specify the point variable P, register 4095
(=0FFF (hexadecimal)).
Speed:
It can be set at 100 intervals from 1 to 100, and 100=3000rpm if
the program execution speed parameter*1 is set to 100. (In this
case, the maximum speed setting parameter*2 is set to 3000.)
(Example)
Transmission example 1:
It moves from the current position by the P123 stroke alone at the
speed 100%.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
007B
0000
0064
RWwn
010A
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
401E
Response example 2:
The software limit over occurs.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
! CAUTION
Since the current position on the program does not vary if the movement is interrupted due to the stop (interlock), etc., the movement can be continued by
executing the command again. However, if resetting is executed, the current position on the program will be initialized at the position of the robot.
*1: Single-axis controllers: PRM30, dual-axis controllers: PRM17
*2: Single-axis controllers: PRM44, dual-axis controllers: PRM64 and PRM104
79
CHAPTER2 CC-Link Unit
(11) General-purpose input response
movement execution ............................................................. Code 010B
Until the conditions of DI/SI input are established, the specified axis continues
moving to the specified point position. When the DI/SI conditions are established,
the robot stops and the command is normally ended. Even if any DI/SI condition is
not established, the command is normally ended at the step where it reaches the
target point.
RWwn+7
RWwn+6
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
DI/SI status
DI/SI number
RWwn+3
Point number
RWwn+2
Axis
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Point number: This is the inherent number assigned to each of 1000 points as a
total from 0 to 999. To specify the point variable P, register 4095
(=0FFF (hexadecimal)).
DI/SI number: Specify one among the general-purpose input DI0 to 15*1 and SI200
to 231.
DI/SI status: 1 means ON, and 0 means OFF.
(Example)
Transmission example 1:
Y axis alone is continuously moved to the position of P2 until
SI210=1 (ON).
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0001
0000
0000
0002
0001
00D2
RWwn
010B
Response example 1:
Since the conditions are established on the way of movement, the
robot stops with the normal end.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
! CAUTION
The movement speed is set with MOVF speed parameter*2 but is not influenced
by the program execution speed parameter*3.
*1: DI0 to DI7 when the SRCP/SRCD series controllers are used.
*2: Single-axis controllers: PRM9, dual-axis controllers: PRM4
*3: Single-axis controllers: PRM30, dual-axis controllers: PRM17
80
CHAPTER2 CC-Link Unit
(12) Pallet work position specification
movement execution ............................................................. Code 010C
It moves to the pallet work position specified with the matrix.
RWwn+7
RWwn+6
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
Speed
RWwn+3
Pallet work position
RWwn+2
Axis
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Pallet work position:
It is the inherent number which is given to each square of the matrix, being a value in the range of 1 to max. 65025 (= 255×255). In
addition, the counter arrangement variable "C" or "D" can also be
used. 65535 (=FFFF (hexadecimal)) is registered for C, and 65534
(=FFFE (hexadecimal)) is registered for D.
Speed:
It can be set at 100 intervals from 1 to 100, and 100=3000rpm if
the program execution speed parameter*1 is set to 100. (In this
case, the maximum speed setting parameter*2 is set to 3000.)
(Example)
Transmission example 1:
If the matrix of 4×3 is defined, it moves to the 2nd line and 2nd
array at the speed 100%.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0005
0000
0064
RWwn
010C
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
Transmission example 2:
If the matrix of 5×5 is defined, Y axis alone moves at the speed
50% to the pallet work position specified with the counter variable
D.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
FFFE
0002
0032
RWwn
010C
Response example 2:
Since the D value is not proper, the data error occurs.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
4017
! CAUTION
Since it is calculated on the presumption that the robot moves in the cartesian
coordinate system, the SCARA robot does not move as expected.
*1: Single-axis controllers: PRM30, dual-axis controllers: PRM17
*2: Single-axis controllers: PRM44, dual-axis controllers: PRM64 and PRM104
81
CHAPTER2 CC-Link Unit
(13) Position specification arch motion definition .................... Code 010D
The arch motion of the position specification is defined.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWwn+3
Specified position
RWwn+2
Axis
RWrn+3
RWrn+2
(Details)
Axis:
It is the execution axis number of the arch motion. 1 means X axis,
and 2 means Y axis.
Specified position:
It is the movement position (absolute position of origin reference)
of the arch motion execution axis.
The position can be specified in the range of -9999 to 9999 in the
millimeter units.
(Example)
Transmission example 1:
The arch motion in which Y axis returns to Y=10.00 is defined.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
000A
0002
0000
RWwn
010D
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
! CAUTION
This command is invalid for single-axis controllers.
82
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(14) Distance specification arch motion definition .................... Code 010E
The arch motion of the distance specification is defined.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWwn+3
Specified distance
RWwn+2
Axis
RWrn+3
RWrn+2
(Details)
Axis:
It is the execution axis number of the arch motion. 1 means X axis,
and 2 means Y axis.
Specified distance:
It is the movement position (relative position of origin reference)
of the arch motion execution axis.
The position can be specified in the range of -9999 to 9999 in the
millimeter units.
(Example)
Transmission example 1:
The arch motion in which Y axis returns by -100.00 is defined.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
FF9C
0002
0000
RWwn
010E
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
! CAUTION
This command is invalid for single-axis controllers.
! CAUTION
Since the current position on the program does not vary if the movement is interrupted due to the stop (interlock), etc., the movement can be continued by
executing the command again. However, if resetting is executed, the current position on the program will be initialized at the position of the robot.
83
CHAPTER2 CC-Link Unit
(15) General-purpose output or
memory output status change .............................................. Code 010F
ON/OFF control of the general-purpose output or memory output is performed.
RWwn+7
Command option
RWwn+5
RWwn+4
RWwn+6
RWwn+3
Output status
RWrn+7
Command response
RWrn+5
RWrn+4
RWrn+6
RWrn+3
RWwn+2
DO/MO/SO
number
RWrn+2
(Details)
DO/MO/SOnumber:
One is specified among the general-purpose output 0 to 12 (13
points)*, serial general-purpose output 200 to 231 (32 points) or
memory output 100 to 131 (32 points).
Output status: 1 means ON, and 0 means OFF.
(Example)
Transmission example 1:
The serial general-purpose output 203 is turned ON.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0001
00CB
0000
RWwn
010F
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
* 0 to 4 (5 points) for the SRCP/SRCD series controllers
84
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(16) General-purpose input or memory input wait ..................... Code 0110
It waits until the specified general-purpose input or memory input comes into the
specified state.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWwn+3
Input status
RWwn+2
DI/MI/SI number
RWrn+3
RWrn+2
(Details)
DI/MI/SI number:
One is specified among the general-purpose input 0 to 15 (16
points)*, serial general-purpose input 200 to 231 (32 points) or
memory input 100 to 147 (48 points).
Input status: 1 means ON, and 0 means OFF.
(Example)
Transmission example 1:
It waits until SI201=1.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0001
00C9
0000
RWwn
0110
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
* 0 to 7 (8 points) for the SRCP/SRCD series controllers
85
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(17) Specified time waiting ............................................................ Code 0111
It waits for the specified time alone.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Time
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Time:
It can be specified in the range of 1 to 65535 in the 10 millisecond
units.
(Example)
Transmission example 1:
It waits for 1 second.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0064
0000
RWwn
0111
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
86
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(18) Matrix definition ...................................................................... Code 0112
The matrix is defined.
RWwn+7
RWwn+6
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
Pallet number
Command response
RWrn+5
RWrn+4
RWwn+3
Line number
RWwn+2
Array number
RWrn+3
RWrn+2
(Details)
Array number, Line number:
A value of 1 to 255 can be applied to each matrix.
Pallet number:
It is the inherent number of 0 to 31 for the matrix discrimination.
(Example)
Transmission example 1:
The matrix of 5×2 is defined at the 1st number.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0002
0005
0001
RWwn
0112
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
87
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(19) Movement matrix specification. ............................................ Code 0113
The movement matrix is specified with the pallet work position specification movement execution command (code: 010C).
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Pallet number
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Pallet number: It is the inherent number of 0 to 31 for matrix discrimination.
(Example)
Transmission example 1:
The matrix of the pallet No. 0 is specified.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0113
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
88
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(20) Point variable P definition ..................................................... Code 0114
The point variable P is set.
Command option
RWwn+7
RWwn+6
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Point number
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Point number: A value of 0 to 999 can be specified.
(Example)
Transmission example 1:
The point variable P is set to 100.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0064
0000
RWwn
0114
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
MEMO
Since the point variable is prepared to treat the point number as the variable, a value
of 0 to 999 can be specified.
! CAUTION
Though the content of the point variable is held even if the controller power
supply is turned OFF, the point variable is initialized to 0 if the program is reset
or the execution program switch or other operation which the program reset is
applied.
89
CHAPTER2 CC-Link Unit
(21) Addition of specified value to point variable P ................... Code 0115
The specified value is added to the point variable P.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Addition value
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Addition value:
A value of 1 to 999 can be specified.
(Example)
Transmission example 1:
10 is added to the point variable P.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
000A
0000
RWwn
0115
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
90
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(22) Subtraction of specified value
from point variable P .............................................................. Code 0116
The specified value is subtracted from the point variable P.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Subtraction value
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Subtraction value:
A value of 1 to 999 can be specified.
(Example)
Transmission example 1:
10 is subtracted from the point variable P.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
000A
0000
RWwn
0116
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
91
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(23) Arrangement element specification
of counter arrangement variable C ....................................... Code 0117
The arrangement elements of the counter arrangement variable C used are specified.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Arrangement
element No.
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Arrangement element No.:
It expresses the inherent number of 0 to 31 to specify the arrangement element of the counter arrangement variable.
If 65534 (=FFFE (hexadecimal)) is input here, the value in the
counter variable "D" is used to specify the element of the counter
variable.
(Example)
Transmission example 1:
Hereafter, the counter arrangement variable of the element No. 1
is used.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0001
0000
RWwn
0117
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
92
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(24) Counter arrangement variable C specification .................... Code 0118
The counter value is set at the counter arrangement variable C specified with the
arrangement element specification command (code 0117).
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Counter value
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Counter value:
A value of 0 to 65535 can be specified.
(Example)
Transmission example 1:
200 is set at the counter arrangement variable C.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
00C8
0000
RWwn
0118
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
MEMO
The counter arrangement variable is the arrangement variable of 32 elements, and a
desired number of 0 to 65535 can be set to each.
93
CHAPTER2 CC-Link Unit
(25) Addition of specified value
to counter arrangement variable C ....................................... Code 0119
The specified value is added to the counter arrangement variable C specified with
the arrangement element specification command (code 0117).
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Addition value
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Addition value:
A value of 1 to 65535 can be specified.
(Example)
Transmission example 1:
10 is added to the counter arrangement variable C.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
000A
0000
RWwn
0119
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
94
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(26) Subtraction of specified value
from counter arrangement variable C ................................. Code 011A
The specified value is subtracted from the counter arrangement variable C specified with the arrangement element specification command (code 0117).
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Subtraction value
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Addition value:
A value of 1 to 65535 can be specified.
(Example)
Transmission example 1:
10 is subtracted from the counter arrangement variable C.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
000A
0000
RWwn
011A
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
95
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(27) Counter variable D definition ............................................... Code 011B
The counter variable D is set.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Counter value
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Counter value:
A value of 0 to 65535 can be specified.
(Example)
Transmission example 1:
200 is set to the counter variable D.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
00C8
0000
RWwn
011B
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
MEMO
The counter variable D is a variable which can be set as desired by the user, and a
desired value of 0 to 65535 can be set.
96
CHAPTER2 CC-Link Unit
(28) Addition of specified value to counter variable D .............. Code 011C
The specified value is added to the counter variable D.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Addition value
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Addition value:
A value of 1 to 65535 can be specified.
(Example)
Transmission example 1:
10 is added to the counter variable D.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
000A
0000
RWwn
011C
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
97
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(29) Subtraction of specified value
from counter variable D ........................................................ Code 011D
The specified value is subtracted from the counter variable D.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Subtraction value
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Addition value:
A value of 1 to 65535 can be specified.
(Example)
Transmission example 1:
10 is subtracted from the counter variable D.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
000A
0000
RWwn
011D
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
98
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(30) Shift execution of position data ............................................ Code 011E
The position data is shifted by the specified point data. It is valid until this code is
executed again or the program reset is applied.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Point number
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Point number: It is the inherent number which is assigned to a total of 1000 points
of 0 to 999. To specify the point variable P, register 4095 (=0FFF
(hexadecimal)).
(Example)
Transmission example 1:
Hereafter, the position data is shifted by the data of the point 1
during movement.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0001
0000
RWwn
011E
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
99
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(31) Linear interpolation movement execution ........................... Code 011F
It moves to the position of the data of the specified point number in the linear
interpolation mode.
RWwn+7
RWwn+6
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
Speed
RWwn+3
Point number
RWwn+2
Axis
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Axis:
In the linear interpolation movement, 0: All axes alone can be assigned.
Point number: It is the inherent number which is assigned to a total of 1000 points
of 0 to 999. To specify the point variable P, register 4095 (=0FFF
(hexadecimal)).
Speed:
It can be set at 100 steps of 1 to 100, and when the program execution speed parameter*1 is 100, 100=1000mm/s is established.
(When the maximum speed setting parameter*2 is 3000, and the
lead length is 20mm.)
(Example)
Transmission example 1:
It moves to the P123 position at the speed 20% in the linear interpolation mode.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
007B
0000
0014
RWwn
011F
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
11CB
RWrn+5
0000
RWrn+4
13AD
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
401E
Response example 2:
The software limit over occurs.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
! CAUTION
This command is invalid for single-axis controllers.
! CAUTION
The SCARA robot, etc. which do not operate in the cartesian coordinates cannot
be moved in the linear interpolation mode.
*1: Single-axis controllers: PRM30, dual-axis controllers: PRM17
*2: Single-axis controllers: PRM44, dual-axis controllers: PRM64 and PRM104
100
CHAPTER2 CC-Link Unit
(32) Circular interpolation movement execution ........................ Code 0120
The circular interpolation movement which passes the specified point is executed.
If the point specification number is n, it moves on the circular locus on which the
current position is the start point, the point n is passed, and the point n+1 is the end
point. If the circle is specified, it moves on the circle locus on which the current
position is the start point, the points n and n+1 are passed, and the start point is the
end point.
RWwn+7
RWwn+6
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
Locus specification
RWwn+3
Speed
RWwn+2
Point number
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Point number: A point number of 0 to 998 can be specified. If the point variable P
is specified, 4095(=0FFF (hexadecimal)) is registered.
Speed:
It can be set at 100 steps of 1 to 100, and when the program execution speed parameter*1 is 100, 100=1000mm/s is established.
(When the maximum speed setting parameter*2 is 3000, and the
lead length is 20mm.)
Locus specification:
The locus type is selected. 0: Circular segment 1: Circle
(Example)
Transmission example 1:
It moves at the speed 20% on the circular locus where the start
point is the current position, the point 123 is passed, and the point
124 is the end point.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
007B
0001
0000
RWwn
0120
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
Transmission example 2:
It moves at the speed 5% on the circle locus where the start point is
the current position, P100 and P101 are passed, and the start point
is the end point.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0005
0064
0001
RWwn
0120
Response example 2:
The software limit over occurs.
RWrn+7
0000
RWrn+6
0000
101
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
401E
CHAPTER2 CC-Link Unit
! CAUTION
This command is invalid for single-axis controllers.
! CAUTION
The applicable radius is max. 1000mm and min. 2mm.
! CAUTION
The SCARA robot, etc. which do not operate in the cartesian coordinates cannot
be moved in the circular interpolation mode.
*1: Single-axis controllers: PRM30, dual-axis controllers: PRM17
*2: Single-axis controllers: PRM44, dual-axis controllers: PRM64 and PRM104
102
CHAPTER2 CC-Link Unit
2-12-4
Remote command details (data handling)
(1)
Current position read ............................................................. Code 0201
The current positions of all axes or specified axes are read.
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Y axis position
Command response
RWrn+5
RWrn+4
X axis position
RWwn+7
RWwn+3
RWwn+2
Axis
RWrn+3
RWrn+2
(Details)
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Axis position: The current position of the robot is indicated (unit: 0.01mm). When
the robot is set at the rotary axis, the unit of the movement position
is 0.01 degrees.
Single-axis controllers does not use RWrn+6 to RWrn+7.
Similarly, writing is not applied to the unspecified axis with the
command option.
(Example)
Transmission example 1:
The current position information of all axes is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0201
Response example 1:
The current position of the robot is X=321.05 and Y=100.15.
RWrn+7
0000
RWrn+6
271F
RWrn+5
0000
RWrn+4
7D69
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
! CAUTION
Reset the current position indication mode, and execute the command.
MEMO
If any robot position cannot be judged due to the incomplete origin state, cable breakage, etc., the robot position is not determined.
103
CHAPTER2 CC-Link Unit
(2)
Current program number read .............................................. Code 0202
The execution program number is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Program number
(Details)
Program number:
It is the inherent number of 0 to 99 assigned to each program.
(Example)
Transmission example 1:
The execution program is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0202
Response example 1:
No. 31 is being executed.
RWrn+7
0000
RWrn+6
0000
104
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
001F
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(3)
Current step number read ..................................................... Code 0203
The current step number is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Step number
(Details)
Step number: It is the inherent value of 1 to 255 assigned to each step.
(Example)
Transmission example 1:
The execution step number is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0203
Response example 1:
The 170th line is being executed.
RWrn+7
0000
RWrn+6
0000
105
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
00AA
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(4)
Current task number read ..................................................... Code 0204
The task number currently selected is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Task number
(Details)
Task number: It is the inherent number of 0 to 3 assigned to each task.
(Example)
Transmission example 1:
The execution task number is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0204
Response example 1:
The currently selected task is 0 (main task).
RWrn+7
0000
RWrn+6
0000
106
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(5)
Current point No. read ........................................................... Code 0205
The point number currently selected is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Point number
(Details)
Point number: It is the inherent value of 0 to 999 assigned to each point.
(Example)
Transmission example 1:
The current point number is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0205
Response example 1:
The point number currently selected is 57.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0039
RWrn+1
0000
RWrn
0200
MEMO
It is used to know what point number was used for movement or search for the point
which causes an error if the error is caused by the point data.
107
CHAPTER2 CC-Link Unit
(6)
ROM version number read .................................................... Code 0206
The controller system version value is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Version value
(Details)
Version value: It is the system version which is possessed by the controller. If the
version is V13.30, 1330 (=532 (hexadecimal)) is indicated.
(Example)
Transmission example 1:
The controller system version is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0206
Response example 1:
The version is V13.30.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
MEMO
The controller versions are as follows.
ERCX/SRCX :V13.xx
DRCX
:V18.xx
SRCP
:V24.xx
SRCD
:V24.xxB
SRCP30
:V24.xxH
108
RWrn+4
0000
RWrn+3
0000
RWrn+2
0532
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(7)
Number of axes read .............................................................. Code 0207
The total number of operable axes is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Axis number
(Example)
Transmission example 1:
The total number of axes is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0207
Response example 1:
2 axes are operable.
RWrn+7
0000
RWrn+6
0000
109
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0002
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(8)
Emergency stop status check ............................................... Code 0208
The status of the emergency stop is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Emergency stop
(Details)
Emergency stop:
1 means the emergency stop status, and 0 means that the emergency stop is canceled.
(Example)
Transmission example 1:
The status of the emergency stop is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0208
Response example 1:
0 (the emergency stop is canceled.) is established.
RWrn+7
0000
RWrn+6
0000
110
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(9)
Servo status check ................................................................. Code 0209
The servo statuses of all axes or specified axes are read.
When all axes are specified, the result becomes 1 only if the servos of all axes are
on.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Axis
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Servo status
(Details)
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Servo status: 1 means the servo-on and 0 means the servo-off.
(Example)
Transmission example 1:
The servo statuses of all axes are read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0209
Response example 1:
The servos of all axes are on.
RWrn+7
0000
RWrn+6
0000
111
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0001
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(10) Return-to-origin status check .............................................. Code 020A
It reads that the return-to-origin is completed in all axes or specified axes.
In thee all-axis specification mode, the result becomes 1 only when all axes are
completely returned to the origin.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Axis
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Origin status
(Details)
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Origin status: 0 means that the origin is incomplete, and 1 means that the returnto-origin is completed.
(Example)
Transmission example 1:
It reads that the return-to-origin is completed in all axes.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
020A
Response example 1:
The return-to-origin is completed in all axes.
RWrn+7
0000
RWrn+6
0000
112
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0001
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(11) Service mode status check .................................................. Code 020B
The service mode status is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Status
(Details)
Status:
1 means that the servo mode is valid, and 0 means that it is invalid.
(Example)
Transmission example 1:
The service mode status is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
020B
Response example 1:
1 (service mode status) is established.
RWrn+7
0000
RWrn+6
0000
113
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0001
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(12) Operation mode check .......................................................... Code 020C
The robot status is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Operation mode
(Details)
Operation mode:
0: Stop status 1: The program is being executed with the communication of HPB, personal computer , etc. 2: The program is being
executed with I/O command.
(Example)
Transmission example 1:
The robot status is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
020C
Response example 1:
0 (stop status) is established.
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
! CAUTION
The data handling with the remote command is received during stop alone. Accordingly, the response of this mode is set to 0 (stop status) alone.
114
CHAPTER2 CC-Link Unit
(13) Matrix definition content read .............................................. Code 020D
The matrix definition content is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWwn+3
RWwn+2
Pallet number
RWrn+3
Line number
RWrn+2
Array number
(Details)
Pallet number: It is the inherent number of 0 to 31 for matrix discrimination.
Array number, Line number:
It is the value of 1 to 255.
(Example)
Transmission example 1:
The data of the pallet No. 1 is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0001
0000
RWwn
020D
Response example 1:
It is the matrix of line number 20 and array number 30.
RWrn+7
0000
RWrn+6
0000
115
RWrn+5
0000
RWrn+4
0000
RWrn+3
001E
RWrn+2
0014
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(14) Currently specified matrix number read ............................. Code 020E
The pallet number of the currently specified matrix is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Pallet number
(Details)
Pallet number: It is the inherent number of 0 to 31 for matrix discrimination.
Array number, Line number:
It is the value of 1 to 255.
(Example)
Transmission example 1:
The currently specified pallet number is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
020E
Response example 1:
The pallet 0 is specified.
RWrn+7
0000
RWrn+6
0000
116
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(15) Current point variable P read ................................................ Code 020F
The point variable P is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Point number
(Details)
Point number: It is the inherent number assigned to the point of 0 to 999.
(Example)
Transmission example 1:
The point variable P is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
020F
Response example 1:
The point variable is P=100
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0064
RWrn+1
0000
RWrn
0200
! CAUTION
Though the content of the point variable P is held even when the controller power
supply is turned off, the point variable P is initialized to 0 in case of the program
reset or any operation which the program reset is applied with the execution
program switch, etc.
117
CHAPTER2 CC-Link Unit
(16) Arrangement element number
read of currently specified C ................................................. Code 0210
The element number of the counter arrangement variable C currently specified is
read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Element No.
(Example)
Transmission example 1:
The element number of the counter arrangement variable C is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0210
Response example 1:
The element No. is 31.
RWrn+7
0000
RWrn+6
0000
118
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
001F
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(17) Counter arrangement variable C read .................................. Code 0211
The value of the counter arrangement variable C of the specified element number
is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Element No.
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Counter value
(Details)
Element No.: The number specifies the arrangement element in the range of 0 to
31.
(Example)
Element No.: The value of the counter arrangement variable C is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0211
Response example 1:
The element No. is 21202.
RWrn+7
0000
RWrn+6
0000
119
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
52D2
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(18) Current counter variable D read ........................................... Code 0212
The value of the counter variable D is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Counter value
(Example)
Transmission example 1:
The value of the counter variable D is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0212
Response example 1:
The element No. is 65535.
RWrn+7
0000
RWrn+6
0000
120
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
FFFF
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(19) Current shift data read ........................................................... Code 0213
The currently set shift data is read.
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Y axis position
Command response
RWrn+5
RWrn+4
X axis position
RWwn+7
RWwn+3
RWwn+2
RWrn+3
RWrn+2
(Details)
Axis position: The shift data is indicated (unit: 0.01mm). When the robot is set at
the rotary axis, the unit of the position is 0.01 degrees.
Single-axis controllers does not use RWrn+6 to RWrn+7.
(Example)
Transmission example 1:
The current shift data is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0213
Response example 1:
The shift data is X=150.00, Y=250.00.
RWrn+7
0000
RWrn+6
61A8
121
RWrn+5
0000
RWrn+4
3A98
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(20) General-purpose input and
memory input status read ..................................................... Code 0214
The status of the general-purpose input or memory input is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
DI/MI/SI number
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Input status
(Details)
DI/SI/MI number:
One number is specified among the general-purpose input 0 to 15
(16 points)*, memory input 100 to 147 (48 points) and serial general-purpose input 200 to 231 (32 points).
Input status: 1 means ON, and 0 means OFF.
(Example)
Transmission example 1:
The status of SI201 is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
00C9
0000
RWwn
0214
Response example 1:
The SI201 status is SI201=1(ON).
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
* 0 to 7 (8 points) for the SRCP/SRCD series controllers
122
RWrn+3
0000
RWrn+2
0001
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(21) General-purpose output and
memory output status read ................................................... Code 0215
The status of the general-purpose output or memory output is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
DO/MO/SO
number
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Output status
(Details)
DO/SO/MO number:
One number is specified among the general-purpose output 0 to
12 (13 points)*, memory output 100 to 131 (32 points) and serial
general-purpose output 200 to 231 (32 points).
Output status: 1 means ON, and 0 means OFF.
(Example)
Transmission example 1:
The status of SO202 is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
00CA
0000
RWwn
0215
Response example 1:
The SO202 status is SO202=0(OFF).
RWrn+7
0000
RWrn+6
0000
RWrn+5
0000
RWrn+4
0000
* 0 to 4 (5 points) for the SRCP/SRCD series controllers
123
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(22) Specified parameter data read .............................................. Code 0216
The specified parameter data is read.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Parameter number
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
Parameter value
(Details)
Parameter number:
The inherent number assigned to each parameter is 0 to 63 for
single-axis controllers, and is 0 to 127 for dual-axis controllers.
(Example)
Transmission example 1:
Y-axis transfer mass parameter (PRM90) is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
005A
0000
RWwn
0216
Response example 1:
The parameter is PRM90=5(kg).
RWrn+7
0000
RWrn+6
0000
124
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0005
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(23) Specified point data read ....................................................... Code 0217
The specified point data is read.
RWwn+6
Command option
RWwn+5
RWwn+4
RWrn+7
RWrn+6
Y axis position
Command response
RWrn+5
RWrn+4
X axis position
RWwn+7
RWwn+3
RWwn+2
Point number
RWrn+3
RWrn+2
(Details)
Point number: It is the inherent number of 0 to 999 assigned to each point.
(Example)
Transmission example 1:
Data of P254 is read.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
00FE
0000
RWwn
0217
Response example 1:
The shift data is X=-0.05, Y=0.01.
RWrn+7
0000
RWrn+6
0001
125
RWrn+5
FFFF
RWrn+4
FFFB
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
2-12-5
Remote command details (utilities)
(1)
Execution program number switching ................................. Code 0301
The execution program number is switched. If the program reset is hereafter executed, it will return to the 1st step of the program selected here.
When this command is issued, the program reset will be applied.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Program number
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Program number:
It is the inherent number of 0 to 99 assigned to each program.
(Example)
Transmission example 1:
The program is switched to NO31.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
001F
0000
RWwn
0301
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
126
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(2)
Execution task number switching. ....................................... Code 0302
The execution task number is switched. If the step operation is hereafter executed,
the program of the task selected here will be executed as one step.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
RWwn+3
RWwn+2
Task number
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Task number: It is the inherent number of 0 to 3 assigned to each task.
(Example)
Transmission example 1:
Task is switched to 1.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0001
0000
RWwn
0302
Response example 1:
The specified task is not executed.
RWrn+7
0000
RWrn+6
0000
127
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
4048
CHAPTER2 CC-Link Unit
(3)
Parameter data write .............................................................. Code 0303
Data is written into the specified parameter.
RWwn+7
RWwn+6
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
Parameter data
Command response
RWrn+5
RWrn+4
RWwn+3
RWwn+2
Parameter number
RWrn+3
RWrn+2
(Details)
Parameter number:
The inherent number assigned to each parameter is 0 to 63 for
single-axis controllers, and is 0 to 127 for dual-axis controllers.
Parameter data:
For the parameter data, refer to "Chapter 5 Parameters" of each
controller manual.
(Example)
Transmission example 1:
The Y-axis transfer mass parameter (PRM90) is set to 3 kilograms.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
005A
0003
RWwn
0303
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
128
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
(4)
Point data write ....................................................................... Code 0304
The data is written into the specified point.
RWwn+7
RWwn+6
Y axis position
RWrn+7
RWrn+6
Command option
RWwn+5
RWwn+4
X axis position
RWwn+3
Axis
RWwn+2
Point number
Command response
RWrn+5
RWrn+4
RWrn+3
RWrn+2
(Details)
Point number: It is the inherent number of 0 to 999 assigned to each point.
Axis:
0 means all axes, 1 means X axis and 2 means Y axis. On dual-axis
controllers, all axes are also specified when 3 is set.
On single-axis controllers, 0 or 1 alone can be specified.
Axis data:
The position data desired to register is directly specified (Unit:
0.01 mm). When the rotary axis is set for the robot, the unit of the
movement position is 0.01 degrees. If any axis is specified, the
data of other axes not specified is free. It does not matter that the
data of Y axis is free in single-axis controllers.
(Example)
Transmission example 1:
X=25.00 and Y=10.00 are written into P100.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
03E8
0000
0000
0000
0000
0064
09C4
RWwn
0304
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
129
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
2-12-6
Remote command details (Special commands)
(1)
No execution (status clear) ................................................... Code 0000
The status is cleared to 0000 for the command ready (remote command acceptable
status).
(2)
Initialization of response register ......................................... Code 0401
The command option register is copied to the response register. If 0000 (hexadecimal) is set to RWwn+2 to RWwn+7, the response will be initialized.
RWwn+7
RWwn+6
Command option
RWwn+5
RWwn+4
Copy source data
RWwn+3
RWwn+2
RWrn+7
RWrn+6
Command response
RWrn+5
RWrn+4
Copy destination data
RWrn+3
RWrn+2
(Details)
Copy data:
The data in the option register RWwn+2 to RWwn+7 is copied to
RWrn+2 to RWrn+7.
(Example)
Transmission example 1:
The response register is initialized.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0000
0000
0000
0000
0000
RWwn
0401
Response example 1:
It is normally ended.
RWrn+7
0000
RWrn+6
0000
130
RWrn+5
0000
RWrn+4
0000
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
CHAPTER2 CC-Link Unit
2-12-7
Status details
When the controller receives the command, the relevant process will be executed, and
the result (status) will be informed to the master sequencer (PLC) side via RWrn. The
meanings indicated with the statuses are described in this section.
Code 0000 .............................................................................. Command ready
It indicates that the remote command is not executed and can be newly received.
When the command is issued to the controller, the status must be surely 0000. Here,
0000 is set to RWwn in order to set 0000 to the status.
Code 0100 ...................................................................... Command executing
It indicates that the controller receives the remote command and is on the way of the
execution.
* If the reset command or other command of a short execution time is executed, the
code 0100 can sometimes not be detected on the sequencer (PLC) side due to the
scan time (10 milliseconds) on the controller side. Take sufficient care to assemble
the sequence program.
Code 0200 ................................................................ Normal end of command
It indicates that the controller normally completes the remote command.
Code 40xx .......................................................... Command error occurrence
It indicates that an error occurs and the execution of the remote command cannot be
normally completed.
The occurrence error number is set at the area of xx.
For example, if the 403E code is sent to the sequencer (PLC) side, it indicates from
3E (hexadecimal) = 62 (decimal) that the command is interrupted by the interlock
from I/O.
* For the error numbers, refer to "Message tables" in "Instruction Manual for Controller".
Code 80xx (81xx) ................................................ X (Y)axis alarm occurrence
It indicates that an alarm occurs in the controller. If any alarm occurs at the X axis,
80xx will be sent to the sequencer (PLC) side, and if it occurs at the Y axis, 81xx will
be sent to the sequencer (PLC) side. The occurrence alarm number will be set at the
xx area.
For example, if the 800F code is sent to the sequencer (PLC) side, it indicates from
0F (hexadecimal) = 15 (decimal) that the alarm of the feed back error 2 occurs.
* To cancel the alarm, it is necessary to turn off the controller power supply. For the
alarm number and alarm treatment method, refer to "Troubleshooting" in "Instruction Manual for Controller".
131
CHAPTER2 CC-Link Unit
2-12-8
Current position indication mode
The current position indication mode is selected by setting 0001 to RWwn+1.
In the current position indication mode, the current position of the robot is always output
to RWrn+4 to RWrn+7 regardless of the execution status or no-execution status of the
remote command. The position of the robot can be always grasped by selecting the current position indication mode.
Remote command
RWwn+1
RWwn
0001
Meaning of command
Current position information is displayed in RWrn+4 to
RWrn+7.
xxxx
Command response
RWrn+5
RWrn+4
X axis position
RWrn+7
RWrn+6
Y axis position
RWrn+3
RWrn+2
(Details)
Axis position: The current position of the robot is indicated (unit: 0.01mm). If
the rotary axis is set for the robot, the unit of the movement position is 0.01 degrees.
RWrn+6 to RWrn+7 is not used in single-axis controllers.
(Example)
Transmission example 1:
Current position is output by current position display mode.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
0000
0000
0001
0000
0000
0000
0000
RWwn
0000
Response example 1:
The current position of the robot is X=321.05 and Y=-0.02.
RWrn+7
FFFF
RWrn+6
FFFE
RWrn+5
0000
RWrn+4
7D69
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0000
Transmission example 2:
Move to the position of X=50.37 and Y=45.55 at the 100% speed
in the current position indication mode.
RWwn+7 RWwn+6 RWwn+5 RWwn+4 RWwn+3 RWwn+2 RWwn+1
11CB
0000
0001
0000
0064
0000
13AD
RWwn
0108
Response example 2:
Moving to the target position is normally ended. (The current position of the robot is X=50.37 and Y=45.55)
RWrn+7
0000
RWrn+6
11CB
RWrn+5
0000
RWrn+4
13AD
RWrn+3
0000
RWrn+2
0000
RWrn+1
0000
RWrn
0200
! CAUTION
Before executing a command which uses RWrn+4 to RWrn+7 as the response
such as the specified point data read command (code 0217), cancel the current
position indication mode. If the current position indication mode is kept, the
command response overlaps with the current position indication and the data
cannot be normally read out.
Do not use the current position indication mode when executing a command
which uses RWrn+4 to RWrn+7 as the response.
MEMO
The renewal interval of the current position is every 10 milliseconds. Accordingly,
when the robot moves at a high speed, the error becomes large between the actual
position of the robot and the robot position sent as the response.
132
CHAPTER2 CC-Link Unit
MEMO
If the robot position cannot be judged due to the incomplete origin position status,
cable breakage, etc., the robot position will not be determined.
2-12-9
Sending/receiving example
The sending/receiving example is shown when the direct position specification movement execution (code 0108). (Values are expressed in the hexadecimal mode.)
RWwn (0000)
(0108)
(0000)
Command
RWwn+1
(0000 or 0001)
RWwn+2~RWwn+7
Axis moving
Axis movement
Status
(1)
(2)
(3)
(4)
RWrn
Ready
Executing (0100)
Result
(0000)
Executing
The direct position specification movement execution command is executed
by setting 0108 to RWwn. Here, the options (movement axis, speed, target
position) necessary for movement are set at the specified addresses in RWwn+2
to RWwn+7 before the command is set to RWwn or at the same time when the
command is set.
0000 is usually set to RWwn+1, and 0001 is set to execute the command in the
current position indication mode. (In the current position indication mode, the
following process is executed with the current position indicated at RWrn+4 to
RWrn+7.)
When the controller receives the command, it starts the axis movement together with 0100 return to RWrn. When the status is changed into the execution status, it does not matter that RWwn+2 to RWrn+7 (command option) is
changed.
When the movement is completed, the result is set to RWrn. If it is normally
completed, 0200 is set.
When 0000 is set to RWwn, the status is cleared. This ends the cycle of the
command execution.
Here, after verifying that the status becomes 0000, issue the next command.
133
CHAPTER2 CC-Link Unit
2-13
Other operations
2-13-1
Serial I/O display
Serial I/O (input/output) status can be displayed on the screen. Both initial screen and
OPRT screen are used for display.
1)
Press F4 (MON) on the initial screen.
[MENU]
select menu
1EDIT2OPRT3SYS 4MON
2)
Since the parallel input/output state continues displayed, press DIO here.
DI
10000000 00000000
10000000
For the display meaning of the parallel
input/output status, refer to "How to see
the screen" in "Instruction Manual for
Controller".
3)
The serial input/output statuses of RY(n),
RY(n+1), RX(n) and RX (n+1) are continuously displayed from the upper row.
Each row starts from the left in order from
F to 0.
DO
00000000 10100000
XO:1 YO:1 XS:1 YS:1
SI
10000000 10000000
00000000 00000000
SO
10100000 01000001
00000000 00000000
4)
Press DIO above in 3), and the display
will be switched to the serial input/output
status display of RY(n+2), RY(n+3),
RX(n+2) and RX(n+3).
Each row starts from the left in order from
F to 0.
134
SI
00000000 00000000
00000000 00000000
SO
00001000 00000000
00000000 00000000
CHAPTER2 CC-Link Unit
5)
6)
7)
Press DIO (above in 4), and the screen will
be switched to the remote register mode.
Each remote register will be displayed in
the hexadecimal mode.
(Each register is indicated with 4 characters.)
The top row displays the statuses of
RWwn+3, RWwn+2, RWwn+1 and
RWwn from the left.
The 2nd row indicates the statuses of
RWwn+7, RWwn+6, RWwn+5 and
RWwn+4 from the left.
The 3rd row indicates the statuses of
RWrn+3, RWrn+2, RWrn+1 and RWrn
from the left.
The bottom row indicates the statuses of
RWrn+7, RWrn+6, RWrn+5 and RWrn+4
from the left.
Press DIO above in 5), and the screen will
be switched to the parallel input/output
status mode again. Hereafter, each push
of DIO will switch the screen.
To return to the original screen, press
ESC .
Press F2 (OPRT) in the initial screen
to display the serial input/output statuses
in the OPRT screen.
WI
00000000 00000000
FFFF1000 00000000
WO
00000000 00000000
00000000 00000000
[MENU]
select menu
1EDIT2OPRT3SYS 4MON
[MENU]
select menu
1EDIT2OPRT3SYS 4MON
8)
Press F2 (STEP) or F3 (AUTO).
The step operation screen is explained in
the subsequent steps.
[OPRT]
select menu
1ORG 2STEP3AUTO
9)
Press F4 (next) 2 times to switch to the
function table, and then press F2 (SIO).
[OPRT-STEP] 100 0: 0
001:MOVA 254,100
[
0.00,
1MI0 2SI0 3
135
0.00]
4next
CHAPTER2 CC-Link Unit
10) Press F1 (SI01) to display the RY(n),
RY(n+1) and RX(n), RX(n+1) status.
Press F2 (SI02) to display the RY(n+2),
RY(n+3), and RX(n+2), RX(n+3). Press
F3
(WIO) to display the status of the
remote register.
11) Continue displaying the status of each serial I/O.
If F1 (SI01) was pressed above in step
10), then the RY(n), RY(n+1), RX(n),
RX(n+1) status is displayed from the upper row.
[OPRT-STEP] 100 0: 0
001:MOVA 254,100
[
0.00,
0.00]
1SI012SI023WIO
SI
00000000 00000000
00000000 00000000
SO
00000000 00000000
00000000 00000000
If F2 (SI02) was pressed above in step
10), then the RY(n+2), RY(n+3),
RX(n+2), RX(n+3) status is displayed
from the upper row.
Each row start from the left in order from
F - 0.
12) This is the screen when F3 (WI0) is
pressed.
Each remote register will be displayed in
the hexadecimal mode.
(Each register is indicated with 4 characters.)
The top row displays the statuses of
RWwn+3, RWwn+2, RWwn+1 and
RWwn from the left.
The 2nd row indicates the statuses of
RWwn+7, RWwn+6, RWwn+5 and
RWwn+4 from the left.
The 3rd row indicates the statuses of
RWrn+3, RWrn+2, RWrn+1 and RWrn
from the left.
The bottom row indicates the statuses of
RWrn+7, RWrn+6, RWrn+5 and RWrn+4
from the left.
13) Press the ESC key to return to the screen
in step 10).
WI
00000000 00000000
FFFF1000 00000000
WO
00000000 00000000
00000000 00000000
[OPRT-STEP] 100 0: 0
001:MOVA 254,100
[
0.00,
1SI012SI023WIO
136
0.00]
CHAPTER2 CC-Link Unit
2-13-2
Manual control of general-purpose output
The serial general-purpose output can be manually controlled from HPB.
1)
Press F1 (EDIT) on the initial screen.
[MENU]
select menu
1EDIT2OPRT3SYS 4MON
2)
Press F2 (PNT).
[MENU]
select menu
1PGM 2PNT 3UTL
3)
Press F2 (TCH) or F3 (DTCH).
[EDIT-PNT]
The teaching play back screen is explained in the subsequent steps.
select menu
1MDI 2TCH 3DTCH4DEL
4)
During movement of the robot, it reaches
the position where the general-purpose
output is desired for operation. At this
time, stop the operation once, and press
F2
5)
(DO).
The current status of the general-purpose
output appears on the screen. Just press
F4 (next) as many times as needed to
select SO200 to SO231.
Press the function key displaying the SO
number desired to control to hilight the
output status.
6)
To return to the screen in step 4), press
ESC .
[EDIT-PNT-TCH](1) 50
P0
X=0.00
[mm]
[
0.00,
0.00]
1CHG 2DO 3Y
4next
[EDIT-PNT-TCH](1) 50
SO 200=0 201=0 2O2=0
SO 203=0 204=0 205=0
1S2002S2013S2024next
[EDIT-PNT-TCH](1) 50
P0
X=0.00
[mm]
[
0.00,
0.00]
1CHG 2DO
3Y
4next
* The manual control is invalid on the port that used emulated serialization on a parallel
I/O.
137
CHAPTER2 CC-Link Unit
2-14
Error Message
Regarding CC-Link system, the following error message is added.
Message
Error No. Cause
38
Remedy
net link error
connection was forcibly disconnected because an error
occurred in the network connection.
Remedy the network connection error, and then restart.
138
CHAPTER2 CC-Link Unit
2-15
Troubleshooting
Check the following items if any problems occur during operation. Also, refer to “Troubleshooting” in the controller instruction manual and always refer to the section on troubleshooting in the master station sequencer (PLC) instruction manual. If the following items
do not eliminate the problem, promptly contact your Yamaha dealer or Yamaha for assistance.
No.
Symptom
1
When using
the master
station
sequencer
line test
function,
unable to
verify from
the master
station
sequencer
(PLC), that
the robot
controller is
correctly
connected to
the CC-Link
system.
2
Servo won’t
turn on.
Causes
Checkpoints
Remedy
1) CC-Link cable
not correctly
connected.
• Check if CC-Link cable is not
connected, is miswired, or wires are
broken.
• Correctly repair any miswirings or
unconnected wiring. Replace the
cable if broken.
2) CC-Link unit is
not validated so
cannot be
identified from
controller.
• Refer to “2-5-1 Validating the CC-Link
unit”, and check that the CC-Link unit
is properly validated.
• Validate the CC-Link unit, and turn
on the controller power again.
3) Wrong station
No. setting.
• Refer to “2-5-2 Setting the station
No.” and check the station No.
• Reset the station No. correctly, and
turn on the controller power again.
4) Wrong
communication
speed setting.
• Refer to “2-5-3 Setting the
communication speed” and check the
communication speed.
• Reset the communication speed
correctly, and turn on the controller
power again.
5) Alarm occurring
on controller.
• Connect the HPB and check for an
alarm.
• Check if the status LED is lit in red.
• Refer to the controller instruction
manual and troubleshoot according to
the particular alarm.
6) CC-Link cable
• Check the CC-Link cable wiring.
length does not
meet
specifications for
the CC-Link, or a
terminating
resistor is not
connected.
• Repair the wiring.
7) CC-Link cable is • Check the CC-Link cable installation.
in proximity to a
noise source such
as motor/power
lines.
• Reinstall the CC-Link unit away from
the source of noise (motor/power
lines.)
8) CC-Link unit is
defective.
• Replace the CC-Link unit.
• If this solves the problem, replace the
CC-Link unit.
1) Handshake was
not performed at
communication
startup.
• Check RX(n+3)B status, and check if
it was possibly set to OFF.
• Refer to “2-6-1 Starting data
exchange with the controller”
correctly perform handshake for
communication start-up.
2) Set to emergency • Check RYnF status.
stop with RYnF
at OFF.
• To turn on the servo (servo-on) set
RYnF to ON.
3) Set to emergency • Check if set to emergency stop at HPB
stop from HPB
or external parallel I/O.
or external
parallel I/O.
• Cancel emergency stop on the HPB
or external parallel I/O in order to set
the servo to on (servo-on).
4) Controller alarm
was issued.
• Refer to the controller instruction
manual and troubleshoot per the
particular alarm.
• Connect the HPB and check the alarm
that was issued.
• Status LED is lit up in red.
(continued to next page)
139
CHAPTER2 CC-Link Unit
No.
3
Symptom
Causes
Checkpoints
Remedy
1) Error occurred on • Check RX(n+3)B status, and check if it • Check for any problems with noise or
Program
the CC-Link
was possibly set to OFF.
stops by itself
the wiring specifications, and
system during
during
eliminate factors causing errors on the
communication.
automatic
CC-Link system.
operation.
• Referring to “2-5-1 Validating the
2) Controller is
• If the program stops by itself even
defective.
CC-Link unit”, invalidate the CC-Link
during independent controller
unit and try operating the robot
operation, then the controller is
separately with the controller.
probably defective, so replace the
controller.
140
CHAPTER2 CC-Link Unit
2-16
Specifications
Spec. Item
Model
CC-Link Unit
Controller models
SRCP/SRCD/ERCX/SRCX/DRCX series controllers
CC-Link version
Ver. 1.10
Remote station type
Remote device station
Stations used
2 fixed stations
Station No. setting
1 to 63 (set from HPB)
Communication speed setting
10M/5M/2.5/625K/156Kbps (set from HPB)
General-purpose inputs 32 points
General-purpose outputs 32 points
CC-Link I/O points *1
Custom inputs 16 points
Custom outputs 16 points
Input register 8 words (not currently used)
Output register 8 words (not currently used)
Parallel external I/O
All points usable as parallel external I/O for controller
Each point controllable from master station sequencer (PLC)
by emulated serialization, regardless of robot program.
Minimum length between stations *2
0.2m or more
100m (10Mbps)
160m (5Mbps)
Overall length *2
400m (2.5Mbps)
900m (625Kbps)
1200m (156Kbps)
Monitor LED *3
RUN, ERR, SD, RD
*1. Controller I/O rewrite period is every 10ms.
*2. When using cable for CC-Link Ver. 1.10
*3. The upper lid of the controller must be removed in order to monitor the LED.
NOTE: The product external appearance and specifications are subject to change
without prior notice for purposes of improvement or other factors.
141
Revision record
Manual version Issue date
Description
Ver. 5.00
Oct. 2009
Addition of I/O assignment function. Addition of customize
function for END output timing in execution of dedicated I/O
command. Caution was added to "2-6 Sequencer (master station)
settings". Clerical error corrections, etc.
Ver. 5.01
Jun. 2011
The description regarding "Warranty" was changed.
Ver. 5.02
Jul. 2012
The description regarding "Warranty" was changed.
User's Manual
SRCD/SRCP
ERCX/SRCX/DRCX
Single-axis/Dual-axis
Robot Controllers
Jul. 2012
Ver. 5.02
CC-Link
network board
This manual is based on Ver. 5.02 of Japanese manual.
YAMAHA MOTOR CO., LTD. IM Operations
All rights reserved. No part of this publication may be reproduced in
any form without the permission of YAMAHA MOTOR CO., LTD.
Information furnished by YAMAHA in this manual is believed to be
reliable. However, no responsibility is assumed for possible
inaccuracies or omissions. If you find any part unclear in this manual,
please contact your distributor.