Toshiba Laptop Docking Station E6581830 User Manual

E6581830  
TOSVERT VF-S15 series  
® option unit Function Manual  
CCL003Z  
NOTICE  
1. Read this manual before installing or operating. Keep this instruction manual on  
hand of the end user, and make use of this manual in maintenance and inspection.  
2. All information contained in this manual will be changed without notice. Please  
contact your Toshiba distributor to confirm the latest information.  
 
E658130  
Handling in general  
Warning  
Do not connect or disconnect a network cable while the drive power is on.  
It may lead to electric shocks or fire.  
Prohibited  
See the instruction manual attached with the option unit for cautions the handling.  
Otherwise, it may lead to electric shocks, fire, injuries or damage to product.  
Mandatory  
Network control  
Warning  
Do not send the value out of the valid range to objects and attributes.  
Otherwise, the motor may suddenly start/stop and that may result in injuries.  
Prohibited  
Mandatory  
Use an additional safety device with your system to prevent a serious accident due to the  
network malfunctions. Usage without an additional safety device may cause an accident.  
Caution  
Set up “Communication error trip function (see below)” to stop the drive when the option  
unit is deactivated by an unusual event such as tripping, an operating error, power  
outage, failure, etc.  
- Network Time-Out, drive operation at disconnection, Preset speed operation  
selection  
Deactivated the option module may cause an accident, if the “Communication error trip  
function” is not properly set up.  
Mandatory  
Make sure that the operation signals are STOP before resetting drive’s fault. The motor  
may suddenly start and that may result in injuries.  
Notes on operation  
Notes  
When the control power is shut off by the instantaneous power failure, communication  
will be unavailable for a while.  
The Life of EEPROM is approximately 100,000 times. Avoid writing a command more  
than 100,000 times to the same parameter of the drive and the option module.  
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E658130  
Table of Contents  
- 3 -  
 
E658130  
1.Overview  
The option allows the VF-S15 drive to be connected into a CC-Link network. CC-Link supports a  
maximum of 42 nodes, allowing for the Master and this option is based on CC-Link V1.1 and V2.0.  
The CCL-003Z is able to operate RUN/STOP, monitor the status of the drive, set the drive’s parameter  
and etc. by the CC-Link master through installing the VF-S15. And it can use various applications.  
2.Basic specifications  
<Environmental specification>  
Item  
Specification  
Operating  
environment  
Indoors, an altitude of 3,000m or less, where the product will not be exposed  
to direct sunlight, corrosive or explosive gasses, vapor, coarse particulates  
including dust and where there is no grinding fluid or grinding oil nearby.  
0 to + 60 degreeC  
Ambient  
temperature  
Storage  
-25 to +65 degreeC  
temperature  
Related  
20 to 93% (no condensation and absence of vapor)  
5.9 m/s2 (0.6G) or less (10 – 55Hz)  
temperature  
Vibration  
<CC-Link communication and option specification>  
Item Specification  
Number of units 42 units max. (1 station occupied by 1 unit). May be used with other  
corrected  
equipment.  
Baud rate  
156k, 625k, 2.5M, 5M, 10Mbps  
Supplied from SBP009Z  
Remote device station  
Power supply  
Station type  
Number of stations Ver.1: occupies one station, V2: occupies one station (selectable from among  
occupied  
double, quadruple and octuple)  
Connect cable  
CC-Link dedicated cable,  
CC-Link V1.10 compatible CC-Link dedicated cable  
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E658130  
2.1. CC-Link Version  
2.1.1. CC-Link Ver. 1.10  
The conventional CC-Link products, whose inter-station cable lengths have equally been  
changed to 20cm (7.87 inch) or more to improve the inter-station cable length restriction,  
are defined as CC-Link Ver. 1.10. In comparison the conventional products are defined  
as CC-link Ver. 1.00.  
Refer to the CC-link Master Module Manual for the maximum overall cable lengths and  
inter-station cable lengths of CC-Link Ver. 1.00 and Ver. 1.10  
CC-Link Ver. 1.10 compatibility conditions  
1) All modules that comprise a CC-Link system should be compatible with CC-Link Ver.  
1.10.  
2) All data link cables should be CC-Link Ver. 1.10 compatible, CC-Link dedicated cables.  
(CC-Link Ver.1.10 compatible cables have a logo or Ver. 1.10 indication.)  
*In a system that uses the CC-Link Ver. 1.00 and Ver. 1.10 modules and cables together,  
the maximum overall cable length and inter-station cable length are as specified for  
CC-Link Ver. 1.00.  
2.1.2. CC-Link Ver. 2  
The CCL003Z is compatible with CC-Link Ver.2.  
When using the CC-Link Ver.2 setting with the CCL003Z, the master station needs to be  
compatible with the CC-Link Ver.2.  
For CC-Link Ver.2, double, quadruple and octuple settings can be used to increase  
remote register (RWw/r) point.  
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E658130  
3.Names and functions  
The drawing below shows names and functions of main parts.  
3.1. Outline  
Connector to the inverter  
Release tab  
LED indicator  
(See 4.5)  
CC-Link Connector  
DA  
DB  
DG  
SLD  
FG  
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E658130  
4.Installation on inverter  
Refer to VF-S15 option adapter instruction manual (E6581838) for the installation on the  
inverter.  
The following steps must be performed before installing.  
1. Shut off all input power.  
2. Wait at least 15 minutes and check to make sure that the charge lamp is no longer lit.  
Mandatory  
4.1. Connection cable  
In the CC-Link system, use CC-Link dedicated cables.  
If the cable used is other than the CC-Link dedicated cable, the performance of the  
CC-Link system is not guaranteed.  
For the specifications of the CC-Link dedicated cable, refer to the website of the CC-Link  
Partner Association.  
Strip off the sheath of the CC-Link dedicated cable and wind wires to use. If the length of  
the sheath pealed is too long, a short circuit may occur among neighboring wires. If the  
length is too short, wires might come off.  
Recommended screwdriverSmall flat-blade screwdriver  
(Tip thickness: 0.4mm /tip width: 2.5mm)  
Recommented tightening Torque0.22Nm to 0.25Nm  
Cable stripping sizeAbout 7mm  
7mm  
*Fix a cable so that a communication connector may be not taken the weight of wire.  
When the cable is not connected easily, the use of the following bar terminal is  
recommended.  
Phoenix Contact Co. Ltd.  
Bar terminal model: AI-TWIN2x0,5-8 WH  
Length of bar terminal: 8mm  
4.2. Terminating resistor  
Connect the terminating resistor of 110or 130(CC-Link Ver.1.00 dedicated high  
performance cable.) between terminals at the end.  
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E658130  
4.3. Connection of CC-Link master unit and inverter  
The example of the connection of the CC-Link master unit and the inverter is shown.。  
Motor  
R/L1  
S/L2  
T/L3  
U/T1  
V/T2  
W/T3  
Inverter  
VF-S15  
I M  
DA  
DB  
DA  
DB  
CC-Link  
Master  
CCL003Z  
DG  
DG  
SLD  
FG  
Unit  
SLD  
FG  
*Connection of Several Inverters  
Factory Automation can be applied to several inverters which share a link system as  
CC-Link remote device stations and are controlled and monitored by PLC user programs.  
DA,DB  
Shield twisted cable  
DG  
SLD / FG  
Connect the shielded wire of the dedicated CC-Link cable to the “SLD” of each  
module, and ground both ends of the shielded wire using type-D grounding (class 3  
grounding) via “FG.”  
(The ground resistance is 100or less.)  
Terminal resistor  
Connect the terminal resistor of 110.  
(130is a resistance value for the CC-Link Ver.1.00 dedicated high performance cable.)  
Inverter  
Mater unit  
Inverter  
DA  
DA  
DA  
Terminal  
resistor  
Terminal  
resistor  
DB  
DG  
SLD  
FG  
DB  
DG  
DB  
DG  
SLD  
FG  
1101/2W  
(1301/2W)  
1101/2W  
(1301/2W)  
SLD  
FG  
Shield twisted cable  
Shield twisted cable  
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E658130  
4.4. The maximum connection number of units  
1. Maximum number of units connected to one master station (CC-Link Ver.1.10)  
42 units (when only inverters are connected)  
If any other units are included, the number of stations occupied depends on the unit and  
therefore the following conditions must be satisfied:  
{(1 × a) + (2 × b) + (3 × c) + (4 × d)} 64  
a: Number of units occupying 1 station  
b: Number of units occupying 2 stations  
c: Number of units occupying 3 stations  
d: Number of units occupying 4 stations  
{(16 × A) + (54 × B) + (88 × C)} 2304  
A: Number of remote I/O stations 64  
B: Number of remote device stations 42  
C: Number of local, standby master and intelligent device stations 26  
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E658130  
2. Maximum number of units connected to one master station (CC-Link Ver.2.00)  
42 units (when connections are inverter only)  
If any other units are included, the number of stations occupied depends on the unit and  
therefore the following conditions must be satisfied:  
{(a + a2 + a4 + a8) + (b + b2 + b4 + b8) × 2 + (c + c2 + c4 + c8) × 3  
+ (d + d2 + d4 + d8) × 4} 64  
{(a × 32 + a2 × 32 + a4 × 64 + a8 × 128) + (b × 64 + b2 × 96 + b4 × 192 + b8 × 384)  
+ (c × 96 + c2 × 160 + c4 × 320 + c8 × 640) + (d × 128 + d2 × 224 + d4 × 448 + d8 × 896)}  
8192  
{(a × 4 + a2 × 8 + a4 × 16 + a8 × 32) + (b × 8 + b2 × 16 + b4 × 32 + b8 × 64)  
+ (c × 12 + c2 × 24 + c4 × 48 + c8 × 96) + (d × 16 + d2 × 32 + d4 × 64 + d8 × 128)} ≦  
2048  
a: Number of single setting devices occupying one station  
b: Number of single setting devices occupying two stations  
c: Number of single setting devices occupying three stations  
d: Number of single setting devices occupying four stations  
a2: Number of double setting devices occupying one station  
b2: Number of double setting devices occupying two stations  
c2: Number of double setting devices occupying three stations  
d2: Number of double setting devices occupying four stations  
a4: Number of quadruple setting devices occupying one station  
b4: Number of quadruple setting devices occupying two stations  
c4: Number of quadruple setting devices occupying three stations  
d4: Number of quadruple setting devices occupying four stations  
a8: Number of octuple setting devices occupying one station  
b8: Number of octuple setting devices occupying two stations  
c8: Number of octuple setting devices occupying three stations  
d8: Number of octuple setting devices occupying four stations  
16 × A + 54 × B + 88 × C 2304  
A: Numbers of remote I/O 64  
B: Number of remote device stations 42  
C: Number of local and intelligent device stations 26  
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E658130  
4.5. LED indicator  
The LEDs shows the present status of the network and module  
L.RUN  
L.ERR  
SD  
RD  
Layout of LED  
L.RUN Light on during communication.  
SD  
RD  
Light on during send the data of CC-Link.  
Light on during receive the data of CC-Link.  
L.ERR Light on during communication error.  
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E658130  
5. Functions  
This option is a communication interface unit that allows the PLC program to operate, monitor  
and set the parameter of the inverter as a remote station of CC-Link. It is able to communicate  
with a maximum speed of 10Mbps not only transmitting bit data but also by word data.  
Moreover, more data transmissions are possible by the use of CC-Link V2.0.  
5.1. Initial setting  
Set the following parameters of the inverter.  
Factory  
setting  
CC-Link  
setting  
Title  
Function  
Description  
0: Terminal board  
1: Panel keypad (including remote keypad)  
2: RS485 communication  
3: CANopen communication  
4: Communcation option  
0: Setting dial 1 (save even if power is off)  
1: Terminal board VIA  
2: Terminal board VIB  
3: Setting dial 2 (press in center to save)  
4: RS485 communication  
5: UP/DOWN from external logic input  
6: CANopen communication  
7: Communication option  
8: Terminal board VIC  
9, 10: -  
cmod  
Command mode  
selection  
1
4
Frequency  
setting  
fmod  
0
7
mode selection 1  
11: Pulse train input  
12, 13: -  
14: sro  
1: 2 poles  
2: 4 poles  
3: 6 poles  
4: 8 poles  
5: 10 poles  
6: 12 poles  
Number of motor  
pole for  
communication  
f856  
f899  
2
0
*
-
7: 14 poles  
8: 16 poles  
Communication  
function reset  
0: -  
1: Reset (after execution: 0)  
*Set parameter according to number of motor pole used.  
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E658130  
5.2. Communication parameters for CCL003Z  
Title  
Function  
Communication error detection  
delay time  
Description  
c100  
0.0 - 100.0 sec.  
0: Stop and controlled by cmod, fmod  
1: Operation continue  
c101  
Inverter operation at the  
2: Deceleration stop  
communication loss action  
3: Coast stop  
4: Network error stop (err8trip)  
5: Preset speed operation (by c102setting)  
0: None  
1 to 15: Preset speed  
0: Disconnection detection  
1: When communication mode enable (Both cmod and  
fmodare set CANopen or communication option) only  
2: 1 + Driving operation  
Preset speed  
operation selection  
c102  
c103  
Communication time-out  
condition selection  
CC-Link station number  
selection  
*
1 to 64  
c120  
Set the number of stations of inverters (Remote device  
station).  
CC-Link baud rate selection  
*
0: 156kbps  
c121  
1: 625kbps  
2: 2.5Mbps  
3: 5Mbps  
4: 10Mbps  
Set the baud rate for CC-LINK network  
0: Occupies one station (V1.10)  
1: Occupies one station double (V2.0)  
2: Occupies one station quadruple (V2.0)  
3: Occupies one station octuple (V2.0)  
The function of remote registers can be enhanced.  
CC-Link extended selection  
*
c122  
* Set parameters according to the CC-Link network system.  
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E658130  
5.3. CC-Link function setting  
5.3.1. Station number setting  
Use parameter c120to set station number of the inverter.  
Set this parameter within the range of 1 to 64.  
Title  
Function  
CC-Link station  
number selection  
Description  
1 to 64  
c120  
*Use different station numbers for different devices. (If different devices have the same station  
number, the communication cannot be performed properly.)  
Set consecutive numbers for the station numbers. (Do not skip a number in sequence  
like "station number 1 - station number 2 - station number 4".)  
The station number does not have to match with the physical connection sequence.  
(There is no problem with having the physical connection sequence like "station  
number 1 - station number 3 - station number 4 - station number 2".)  
One inverter occupies one station. (One remote device station)  
"L.ERR" LED flickers if the setting is changed. When power is switched on again,  
reset by parameter (f899= 1) or the RES signal is turned on, the setting value is  
reflected and the LED turns off.  
5.3.2. Baud rate setting  
Set the transmission speed. (Refer to the manual for the CC-Link master module for  
details of transmission speed.)  
Title  
Function  
Description  
CC-Link baud rate selection  
0: 156kbps  
1: 625kbps  
2: 2.5Mbps  
3: 5Mbps  
c121  
4: 10Mbps  
"L.ERR" LED flickers if the setting is changed. When power is switched on again,  
reset by parameter (f899= 1) or the RES signal is turned on, the setting value is  
reflected and the LED turns off.  
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E658130  
5.3.3. CC-Link extended setting  
Remote register function can be extended.  
Title  
Function  
Description  
CC-Link extended selection  
*
0: Occupies one station (V1.10)  
1: Occupies one station double (V2.0)  
c122  
2: Occupies one station quadruple (V2.0)  
3: Occupies one station octuple (V2.0)  
When using double, quadruple and octuple settings of the CC-Link Ver.2, station data  
of the master station must be set to double, quadruple and octuple also.  
(If the master station is CC-Link Ver.1 compatible station, the above setting can not be  
made.)  
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E658130  
5.4. Basic functions  
This clause shows the basic function of this CC-Link option using by CC-Link communication.  
5.4.1. Run and frequency operation command  
The PLC program can operate the inverter to run, stop, set the operation frequency and  
change the parameters.  
If the PLC controls these operations, select the command mode and the frequency setting  
mode.  
The parameter setting of the inverter  
Command mode selection  
cmod  
: 4[Communication option] (Factory setting: 1)  
Frequency setting mode selection  
fmod  
: 7[Communication option] (Factory setting: 0)  
* The frequency setting and command can be made CC-Link priority by RYnA and RYnB.  
("n" is depend on the station number.)  
5.4.2. Monitor  
It is able to monitor the status of the inverter.  
Set a monitor code to RWw n and turn RYnC on.  
The data is stored in the buffer memory of the PLC.  
* "n" is depend on the station number.  
The monitor value is updated while RynC has been turned on.  
5.4.3. Writing and reading the parameter  
The PLC can read, write the inverter parameters and reset the inverter.  
Set the command code to RWw(n+2) (set the write data to RWw(n+3) if necessary) and  
turn RYnF (instruction code execution request) on.  
The inverter performs processing corresponding to the command code, return the response  
data, read out data and RXnF (instruction code execution completion).  
Refer to 5.5.8 for detail.  
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E658130  
5.5. I/O signal list  
5.5.1. One station is occupied (CC-Link Ver.1) (c122=0)  
This option occupies one station area of the buffer memory of the PLC.  
In the case of c122= 0, there are remote I/O (RX, RY both 32 bits) and the remote register  
(RWw, RWr both 4 word) in the communication data for one station area.  
Remote I/O (Default value = 0)  
Inverter (Slave) PLC (Master)  
PLC (Master) Inverter (Slave)  
Device No.  
RXn0  
Signal  
Forward running  
Reverse running  
Output terminal 1 (RY-RC)  
Output terminal 2 (OUT)  
Output terminal 3 (FL)  
Failure FL  
Device No.  
Signal  
RYn0  
RYn1  
RYn2  
RYn3  
RYn4  
RYn5  
RYn6  
Forward rotation command  
Reverse rotation command  
Input terminal 3 (S1)  
Input terminal 4 (S2)  
Input terminal 5 (S3)  
RXn1  
RXn2  
RXn3  
RXn4  
RXn5  
RXn6  
Input terminal 6 (S4)  
Input terminal 7 (PIOFF)  
PI control OFF  
Acceleration/deceleration  
pattern selection (1 or 2)  
Emergency stop  
RXn7  
RXn8  
RXn9  
RYn7  
RYn8  
RYn9  
Input terminal 8 (AD1)  
Input terminal 9 (ESTP)  
Intercept output to inverter  
(Coast stop)  
Coast stop (ST = OFF)  
RXnA  
RXnB  
RXnC  
Alarm  
Reserved*  
Monitoring  
RYnA  
RYnB  
RYnC  
Frequency priority CC-Link  
Command priority CC-Link  
Monitor command  
Frequency setting completion  
(RAM)  
Frequency setting command  
(RAM)  
RXnD  
RXnE  
RXnF  
RYnD  
RYnE  
RYnF  
Reserved*  
Reserved**  
Instruction code execution  
completion  
Instruction code execution request  
RX(n+1)0  
to  
RY(n+1)0  
to  
Reserved*  
Reserved**  
RX(n+1)9  
RY(n+1)9  
Error reset request flag  
(A reset request is during switched  
ON)  
RX(n+1)A  
Error status flag  
Remote station ready  
Reserved*  
RY(n+1)A  
RX(n+1)B  
RX(n+1)C  
to  
RY(n+1)B  
RY(n+1)C  
to  
Reserved**  
Reserved**  
RX(n+1)F  
RY(n+1)F  
"n" is depend on the station number.  
The bit described " Reserved " is unstable. Don't use the “Reserved " bit for the judgment.  
*
** Set OFF (“0”) to reserved bit.  
Remote register (Default value = 0)  
RWr  
Inverter PLC  
Signal  
Monitor value 1  
RWw  
PLC Inverter  
Signal  
Monitor code (1 and 2)  
Set frequency  
Address  
RWr n  
Address  
RWw n  
Monitor value 2  
(output frequency)  
Reply code  
RWw n+1  
RWr n+1  
RWr n+2  
RWr n+3  
RWw n+2  
RWw n+3  
Instruction code  
Write data  
Read data  
"n" is depend on the station number.  
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E658130  
5.5.2. Double setting is selected (CC-Link Ver.2) (c122=1)  
This option occupies one station area of the buffer memory of the PLC.  
In the case of c122 = 1, there are remote I/O (RX, RY both 32 bits(same as CC-LINK  
Ver.1)) and the remote register (RWw, RWr both 8 word) in the communication data for one  
station area.  
* Default value of RY and RX is 0.  
Remote register (Default value = 0)  
RWr  
Inverter PLC  
Signal  
Monitor value 1  
RWw  
PLC Inverter  
Signal  
Monitor code (1 and 2)  
Set frequency  
Address  
RWr n  
Address  
RWw n  
Monitor value 2  
(output frequency)  
Reply code  
RWw n+1  
RWr n+1  
RWr n+2  
RWr n+3  
RWr n+4  
RWr n+5  
RWr n+6  
RWr n+7  
RWw n+2  
RWw n+3  
RWw n+4  
RWw n+5  
RWw n+6  
RWw n+7  
Instruction code  
Write data  
Monitor code 3  
Monitor code 4  
Monitor code 5  
Monitor code 6  
Read data  
Monitor value 3  
Monitor value 4  
Monitor value 5  
Monitor value 6  
"n" is depend on the station number.  
5.5.3. Quadruple setting is selected (CC-Link Ver.2) (c122=2)  
This option occupies one station area of the buffer memory of the PLC.  
In the case of c122= 2, there are remote I/O (RX, RY both 32 bits(same as CC-LINK  
Ver.1)) and the remote register (RWw, RWr both 16 word) in the communication data for one  
station area.  
* Default value of RY and RX is 0.  
Remote register (Default value = 0)  
RWr  
Inverter PLC  
Signal  
Monitor value 1  
RWw  
PLC Inverter  
Signal  
Monitor code (1 and 2)  
Set frequency  
Address  
RWr n  
Address  
RWw n  
Monitor value 2  
(output frequency)  
Reply code  
RWw n+1  
RWr n+1  
RWr n+2  
RWr n+3  
RWr n+4  
RWr n+5  
RWr n+6  
RWr n+7  
RWw n+2  
RWw n+3  
RWw n+4  
RWw n+5  
RWw n+6  
RWw n+7  
Instruction code  
Write data  
Read data  
Monitor value 3  
Monitor value 4  
Monitor value 5  
Monitor value 6  
Upper 8  
Monitor code 3  
Monitor code 4  
Monitor code 5  
Monitor code 6  
Upper 8  
Trip history No.  
Trip history No.  
Reserved**  
Bits  
Bits  
RWr n+8  
RWw n+8  
Lower 8  
Bits  
Lower 8  
Trip code  
Bits  
RWr n+9  
RWr n+A  
RWr n+B  
RWr n+C  
RWr n+D  
RWr n+E  
RWr n+F  
Trip information (output frequency)  
Trip information (output current)  
Trip information (output voltage)  
Trip information (energization time)  
Reserved*  
RWw n+9  
RWw n+A  
RWw n+B  
RWw n+C  
RWw n+D  
RWw n+E  
RWw n+F  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Reserved*  
Reserved*  
"n" is depend on the station number.  
The bit described " Reserved " is unstable. Don't use the “Reserved " bit for the judgment.  
** Do not use it.  
*
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E658130  
5.5.4. Octuple setting is selected (CC-Link Ver.2) (c122=3)  
This option occupies one station area of the buffer memory of the PLC.  
In the case of c122= 3, there are remote I/O (RX, RY both 32 bits(same as CC-LINK  
Ver.1)) and the remote register (RWw, RWr both 32 word) in the communication data for one  
station area.  
* Default value of RY and RX is 0.  
Remote register (Default value = 0)  
RWr  
Inverter PLC  
Signal  
Monitor value 1  
RWw  
PLC Inverter  
Signal  
Monitor code (1 and 2)  
Set frequency  
Address  
RWr n  
Address  
RWw n  
Monitor value 2  
(output frequency)  
Reply code  
RWw n+1  
RWr n+1  
RWr n+2  
RWr n+3  
RWr n+4  
RWr n+5  
RWr n+6  
RWr n+7  
RWw n+2  
RWw n+3  
RWw n+4  
RWw n+5  
RWw n+6  
RWw n+7  
Instruction code  
Write data  
Read data  
Monitor value 3  
Monitor value 4  
Monitor value 5  
Monitor value 6  
Upper 8  
Monitor code 3  
Monitor code 4  
Monitor code 5  
Monitor code 6  
Upper 8  
Trip history No.  
Trip history No..  
Reserved**  
Bits  
Bits  
RWr n+8  
RWw n+8  
Lower 8  
Bits  
Lower 8  
Trip code  
Bits  
RWr n+9  
RWr n+A  
RWr n+B  
RWr n+C  
RWr n+D  
RWr n+E  
RWr n+F  
RWr n+10  
RWr n+11  
RWr n+12  
RWr n+13  
RWr n+14  
RWr n+15  
RWr n+16  
RWr n+17  
RWr n+18  
RWr n+19  
RWr n+1A  
RWr n+1B  
RWr n+1C  
RWr n+1D  
RWr n+1E  
RWr n+1F  
Trip information (output frequency)  
Trip information (output current)  
Trip information (output voltage)  
Trip information (energization time)  
Reserved*  
Reserved*  
Reserved*  
Reply code 2  
Read data 2  
Reply code 3  
Read data 3  
Reply code 4  
Read data 4  
Reply code 5  
Read data 5  
Reply code 6  
Read data 6  
RWw n+9  
RWw n+A  
RWw n+B  
RWw n+C  
RWw n+D  
RWw n+E  
RWw n+F  
RWw n+10  
RWw n+11  
RWw n+12  
RWw n+13  
RWw n+14  
RWw n+15  
RWw n+16  
RWw n+17  
RWw n+18  
RWw n+19  
RWw n+1A  
RWw n+1B  
RWw n+1C  
RWw n+1D  
RWw n+1E  
RWw n+1F  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Instruction code 2  
Write data 2  
Instruction code 3  
Write data 3  
Instruction code 4  
Write data 4  
Instruction code 5  
Write data 5  
Instruction code 6  
Write data 6  
Reserved**  
Reserved*  
Reserved*  
Reserved*  
Reserved*  
Reserved*  
Reserved*  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
Reserved**  
"n" is depend on the station number.  
The bit described " Reserved " is unstable. Don't use the “Reserved " bit for the judgment.  
** Do not use it.  
*
- 19 -  
 
 
E658130  
5.5.5. Trip history  
When “Quadruple setting” or “Octuple setting” of CC-LINK V.2 is selected, the past trip  
information can be referred to by the following methods.  
Upper 8  
Trip history No.  
Bits  
Upper 8  
Bits  
Trip history No..  
Reserved  
RWr n+8  
RWw n+8  
Lower 8  
Trip code  
Bits  
Lower 8  
Bits  
RWr n+9  
RWr n+A  
RWr n+B  
RWr n+C  
Trip information (output frequency)  
Trip information (output current)  
Trip information (output voltage)  
Trip information (energization time)  
RWw n+9  
RWw n+A  
RWw n+B  
RWw n+C  
Reserved  
Reserved  
Reserved  
Reserved  
1. Set the past trip history No. to upper 8 bits of "RWw n+8."  
2. The following information is stored to registers.  
Trip history No. : Upper 8 bits of "RWr n+8."  
Trip code  
: Lower 8 bits of "RWr n+8."  
Output frequency : “RWr n+9”  
Output current : “RWr n+A”  
Output voltage : “RWr n+B”  
Energization time : “RWr n+C”  
- 20 -  
 
 
E658130  
5.5.6. Detail of input and output signals  
1. Output signals (Master -> Inverter)  
The output signals from the master unit are indicated. (Input signals to inverter)  
Device No.  
RYn0  
RYn1  
RYn2  
RYn3  
RYn4  
RYn5  
RYn6  
RYn7  
RYn8  
Signal  
Description  
Forward run command  
OFF: Stop command ON: Forward run command***  
OFF: Stop command ON: Reverse run command***  
Reverse run command  
Input terminal function 3(S1)  
Input terminal function 4(S2)  
Input terminal function 5(S3)  
Input terminal function 6(S4)  
Input terminal function (PIOFF)  
Input terminal function 8(AD1)  
Input terminal function 9(ESTP)  
Intercept output to inverter  
(Coast stop)  
The function depends on input terminal selection 3 (c142) *  
The function depends on input terminal selection 4 (c143) *  
The function depends on input terminal selection 5 (c144) *  
The function depends on input terminal selection 6 (c145) *  
The function depends on input terminal selection 7 (c146) *  
The function depends on input terminal selection 8 (c147) *  
The function depends on input terminal selection 9 (c148) *  
Stop the output of the inverter when turned on this signal.  
(Stop the output in the secondary circuit)  
RYn9  
Frequency priority CC-Link  
Command priority CC-Link  
RYnA  
RYnB  
Speed commands are entered from the CC-Link.  
Signals from the CC-Link are used to start and stop operation  
When the monitor command (RYnC) is switched on, each  
monitored values are set to remote registers RWrn, RWrn+1,  
RWrn+4 to RWrn+7 and monitoring flag (RXnC) switches on.  
While the monitor command (RYnC) is on, the monitored  
value is always updated.  
Monitor command  
RYnC  
When the frequency setting command (RYnD) is switched  
on, the set frequency RWwn+1 is written to the inverter.  
After the writing completion, frequency setting completion flag  
(RXnD) switches on.  
Frequency setting command  
(RAM)  
RYnD  
RYnE  
When the frequency setting command (RYnD) is ON, the set  
frequency is always updated.  
Reserved**  
Reserved**  
When the instruction code execution request (RYnF) is  
switched on, processes corresponding to the instruction codes  
are set to RWwn+2, RWwn+10, RWwn+12, RWwn+14,  
RWwn+16 and RWwn+18 are executed.  
After completion of instruction code execution, instruction code  
execution completion flag (RXnF) switches on.  
RYnF  
Instruction code execution request When an instruction code execution error occurs, a value other  
than 0 is set to the reply code (RWrn+2, RWrn+10, RWrn+12,  
RWrn+14, RWrn+16 and RWrn+18)  
The instruction code execution request is effective only when  
this signal changes from OFF to ON.  
Special monitor (72H) is chosen by the instruction code, and  
this signal always updates a monitor value during ON.  
RY(n+1)0  
to Y(n+1)9  
Reserved**  
Reserved**  
If the error reset request (RY(n+1)A) is switched on only  
when an inverter fault occurs, the inverter is reset and the  
error status flag (RX(n+1)A) switches off.  
RY(n+1)A Error reset request  
RY(n+1)B  
Reserved**  
to RY(n+1)F  
Reserved**  
"n" is depend on the station number.  
*
The input terminal function can be changed by the input terminal function selections(c142to c148).  
(But there are functional restrictions. Refer to the following page.)  
** Set OFF (“0”) to reserved bit.  
***When RYn0 and RYn1 are ON simultaneously, the rotation is followed a parameter f105(default = stop).  
- 21 -  
 
 
E658130  
Input function selection from the CC-Link.  
The function numbers selection of the RYn2 to RYn8 function valid from the command of the CC-Link are following  
boldface numbers.  
Positive logic Negative logic  
Function  
No function is assigned  
Forward run command  
Reverse run command  
Standby  
Speed control PM control  
V/f  
0
2
1
3
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
4
6
5
7
8
9
Reset command  
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
32  
36  
46  
48  
50  
52  
54  
56  
58  
60  
62  
64  
74  
76  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
33  
37  
47  
49  
51  
53  
55  
57  
59  
61  
63  
65  
75  
77  
Preset speed command 1  
Preset speed command 2  
Preset speed command 3  
Preset speed command 4  
Jog run mode  
Emergency stop by external signal *  
DC braking command  
2nd acceleration/deceleration  
3rd acceleration/deceleration  
2nd V/F control mode switching  
2nd stall prevention level  
PID control prohibition  
External thermal error input  
Forced local from communication  
Operation hold (hold of 3-wire operation)  
PID integral/differential clear  
PID characteristics switching  
Forced run operation  
Fire speed operation  
Acceleration/deceleration suspend signal  
Power failure synchronized signal  
My function-S trigger signal  
Integrating wattmeter(kWh) display clear  
Trace back trigger signal  
Light-load high-speed operation  
prohibitive signal  
78  
79  
/●  
80  
82  
88  
90  
92  
96  
98  
100  
104  
106  
108  
110  
120  
122  
134  
81  
83  
89  
91  
93  
97  
99  
101  
105  
107  
109  
111  
121  
123  
135  
Holding of RY-RC terminal output  
Holding of OUT terminal output  
Frequency UP  
Frequency DOWN  
Clear frequency UP/DOWN  
Coast stop command  
Forward/reverse selection  
Run/Stop command  
Frequency setting mode forced switching  
Frequency setting mode terminal block  
Command mode terminal block  
Parameter editing permission  
Fast stop command 1  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
/●  
Fast stop command 2  
Traverse permission signal  
136  
140  
142  
144  
146  
137  
141  
143  
145  
147  
Low voltage operation signal  
Forward deceleration  
Forward stop  
Reverse deceleration  
Reverse stop  
/●  
/●  
/●  
/●  
/●  
No.2 motor switching  
(AD2 + VF2 + OCS2)  
152  
153  
/●  
200  
202  
201  
203  
Parameter editing prohibition  
Parameter reading prohibition  
/●  
/●  
* This function is not dependent on cmod.  
- 22 -  
 
E658130  
2. Input signal (Inverter -> Master)  
The following shows input signals to the master unit. (The output signals for the inverter.)  
Signal Description  
OFF: Other than forward running  
(during stop or reverse rotation)  
ON : Forward running  
Device No..  
RXn0  
Forward running  
OFF: Other than reverse running  
(during stop or forward rotation)  
ON : Reverse running  
RXn1  
Reverse running  
Output terminal function 1  
(RY-RC)  
The function depends on output terminal function selection 1  
(f130).  
RXn2  
RXn3  
RXn4  
RXn5  
RXn6  
The function depends on output terminal function selection 2  
(f131).  
Output terminal function 2 (OUT)  
Output terminal function 3 (FL)  
Failure FL  
The function depends on output terminal function selection 3  
(f132).  
OFF : No failure  
ON : Failure  
OFF : PI control permitted  
ON : PI control prohibited  
PI control OFF  
Acceleration/ deceleration  
pattern selection (1 or 2)  
Emergency stop  
OFF: Acceleration/deceleration pattern 1 (AD1)  
ON : Acceleration/deceleration pattern 2 (AD2)  
ON : Emergency stop  
RXn7  
RXn8  
RXn9  
OFF : ST = ON  
Coast stop (ST = OFF)  
ON : ST = OFF  
OFF: No alarm  
RXnA  
RXnB  
Alarm  
ON : Alarm issued  
Reserved*  
Reserved*  
Switched on when the monitored values are set to RWrn,  
RWrn+1, RWrn+4 to RWrn+7 by the monitor command  
(RYnC) switching on. Switched off when the monitor  
command (RYnC) is switched off.  
Switched on when the set frequency is written to the inverter  
RXnC  
Monitoring flag  
Frequency setting completion flag by the frequency setting command (RYnD) switching on.  
RXnD  
RXnE  
(RAM)  
Switched off when the frequency setting command (RYnD)  
is switched off.  
Reserved*  
Reserved*  
Switched on completion of the processing corresponding to  
the instruction code (RWw+2) which is executed when the  
instruction code execution request (RYnF) switches on.  
Switched off when the instruction code execution completion  
flag (RXnF) is switched off.  
Instruction code execution  
completion flag  
RXnF  
RX(n+1)0  
Reserved*  
Reserved*  
to RX(n+1)9  
Switched on when occurred an inverter error or option error  
(watchdog error, CPU error, ROM error or RAM error).  
It is not switched on besides that.  
RX(n+1)A  
RX(n+1)B  
Error status flag  
Switched on when the inverter goes into the ready status on  
completion of initial setting after power-on or hardware reset.  
(Used as an interlock for read/write from/to the master.)  
Switched off when an inverter error occurs (protective  
function is activated).  
Remote station ready  
Reserved*  
RX(n+1)C  
Reserved*  
to RX(n+1)F  
"n" is depend on the station number.  
* The bit described " Reserved " is unstable. Don't use the “Reserved " bit for the judgment.  
- 23 -  
 
E658130  
5.5.7. Remote Register Assignment  
Divide the monitor code (RWw n) into half and select the monitor value 1 (RWr n) from the  
lower 8 bits and the monitor value 2 (RWr n) from the higher 8 bits.  
For example: When output voltage is selected for the monitor value 1 and output torque is  
selected for the monitor value 2. -> The monitor code is 0703H.  
* The hexadecimal value attaches and expresses "H" to the end of a number.  
1. Remote register (Master -> inverter)  
RWw  
Address  
Signal  
Description  
Set the monitor code to be referenced. By switching on the (RYnC) signal  
after setting, the specified monitored data is set to (RWr n).  
The monitor value 1 (RWr n): RWw n Setting of the lower 8 bits of monitor  
code.  
Monitor code  
(1 and 2)  
RWw n  
The monitor value 2 (RWr n+1): RWw n Setting of the upper 8 bits of  
monitor code.  
Set the set frequency. After setting the register, a frequency is written  
after turning on (RynD). When the writing of the frequency is completed,  
(RXnD) turns on, depending on the input command.  
Unit: 0.01Hz  
RWwn+1  
RWwn+2  
Set frequency  
Set the command code for actions such as operation mode switching,  
parameter read, write, error reference, error clear, etc. The command will  
be executed by turning (RynF) on after the register setting is completed.  
When the command execution is completed, (RXnF) turns on.  
Command code 1  
Set data specified by the above-mentioned command code  
(if necessary).  
RWwn+3  
Write data 1  
If no data needs to be written, the value shall be zero.  
(RynF) is turned on after setting the above-mentioned command code  
and this register.  
Set the monitor code to be monitored. By setting "ON” in (RYC) after  
setting, the specified monitored data is stored in RWr n+4.  
Set the monitor code to be monitored. By setting "ON” in (RYC) after  
setting, the specified monitored data is stored in RWr n+5.  
Set the monitor code to be monitored. By setting "ON” in (RYC) after  
setting, the specified monitored data is stored in RWr n+6.  
Set the monitor code to be monitored. By setting "ON” in (RYC) after  
setting, the specified monitored data is stored in RWr n+7.  
Set how many fault records in past to be read.  
RWwn+4  
RWwn+5  
RWwn+6  
RWwn+7  
Monitor code 3  
Monitor code 4  
Monitor code 5  
Monitor code 6  
Upper 8 bits: H00 (latest fault) to H07 (eight faults in past)  
Lower 8 bits: H00  
RWwn+8  
Trip history No.  
Reserved  
RWwn+9  
to  
Reserved  
RWwn+F  
- 24 -  
 
 
E658130  
Address  
Signal  
Description  
Set the command code for actions such as operation mode switching,  
parameter read, write, error reference, error clear, etc. The command will  
be executed by turning (RynF) on after the register setting is completed.  
When the command execution is completed, (RXnF) turns on.  
RWwn+10  
Instruction code 2  
Set data specified by the above-mentioned command code 2  
(if necessary). If no data needs to be written, the value shall be zero.  
(RynF) is turned on after setting the above-mentioned command code  
and this register.  
RWwn+11  
RWwn+12  
RWwn+13  
RWwn+14  
RWwn+15  
RWwn+16  
RWwn+17  
RWwn+18  
RWwn+19  
Write data 2  
Instruction code 3  
Write data 3  
It is the same as instruction code 1 and 2.  
Set data specified by the above-mentioned command code 3  
(if necessary). If no data needs to be written, the value shall be zero.  
(RynF) is turned on after setting the above-mentioned command code  
and this register.  
Instruction code 4  
Write data 4  
It is the same as instruction code 1 and 2.  
Set data specified by the above-mentioned command code 4  
(if necessary). If no data needs to be written, the value shall be zero.  
(RynF) is turned on after setting the above-mentioned command code  
and this register.  
Instruction code 5  
Write data 5  
It is the same as instruction code 1 and 2.  
Set data specified by the above-mentioned command code 5  
(if necessary). If no data needs to be written, the value shall be zero.  
(RynF) is turned on after setting the above-mentioned command code  
and this register.  
Instruction code 6  
Write data 6  
It is the same as instruction code 1 and 2.  
Set data specified by the above-mentioned command code 6  
(if necessary). If no data needs to be written, the value shall be zero.  
(RynF) is turned on after setting the above-mentioned command code  
and this register.  
RWwn+1A  
to  
Reserved  
Reserved  
RWwn+1F  
"n" is depend on the station number.  
- 25 -  
 
E658130  
2. Remote register (Inverter -> Master)  
RWr  
Address  
Signal  
Description  
When (RYnC) is on, the monitored value specified to the lower 8 bits of  
the monitor code (RWwn) is set.  
RWr n  
Monitor value 1  
When "0" is set to the higher 8 bits of the monitor code (RWwn), the  
current output frequency is always set. When other than "0" is set to the  
upper 8 bits of the monitor code (RWwn) and (RYnC) is on, the  
monitored value specified to the higher 8 bits of the monitor code  
(RWwn) is set.  
Monitor value 2  
RWrn+1  
RWrn+2  
(output frequency)  
When (RYnF) is on, the response code correspond to the instruction  
code of (RWwn+2) is set. The value "0" is set for a normal reply and  
other than "0" is set for data fault, mode error, etc.  
For a normal reply, the reply data to the instruction specified by the  
instruction code is set.  
Response code 1  
RWrn+3  
RWrn+4  
RWrn+5  
RWrn+6  
RWrn+7  
Read data 1  
Monitor value 3  
Monitor value 4  
Monitor value 5  
Monitor value 6  
When (RYnC) is on, the monitored value specified to the monitor code  
(RWw n+4) is set.  
When (RYnC) is on, the monitored value specified to the monitor code  
(RWw n+5) is set.  
When (RYnC) is on, the monitored value specified to the monitor code  
(RWw n+6) is set.  
When (RYnC) is on, the monitored value specified to the monitor code  
(RWw n+7) is set.  
The fault data of the trip history No. specified by (RWw n+8) is stored in  
the lower 8bits.  
Trip information  
(Trip code)  
RWrn+8  
The trip history No. specified is echo backed to the upper 8bits.  
Output frequency of the trip history No. specified in (RWw n+8) is  
stored.  
Trip information  
(output frequency)  
Trip information  
(output current)  
Trip information  
(output voltage)  
Trip information  
(energization time)  
RWrn+9  
RWrn+A  
RWrn+B  
RWrn+C  
Output current of the trip history No. specified in (RWw n+8) is stored.  
Output voltage of the trip history No. specified in (RWw n+8) is stored.  
Energization time of the trip history No. specified in (RWw n+8) is  
stored.  
RWrn+D  
to  
Do not use it.  
Reserved  
RWrn+F  
When (RYnF) is on, the response code correspond to the instruction  
code of (RWw n+10) is set. The value "0" is set for a normal reply and  
other than "0" is set for data fault, mode error, etc.  
RWrn+10  
RWrn+11  
RWrn+12  
Reply code 2  
Read data 2  
Reply code 3  
For a normal reply, the reply data to the instruction specified by the  
instruction code is set.  
When (RYnF) is on, the response code correspond to the instruction  
code of (RWw n+12) is set. The value "0" is set for a normal reply and  
other than "0" is set for data fault, mode error, etc.  
- 26 -  
 
E658130  
Address  
Signal  
Description  
For a normal reply, the reply data to the instruction specified by the  
instruction code is set.  
RWrn+13  
Read data 3  
When (RYnF) is on, the response code correspond to the instruction  
code of (RWw n+14) is set. The value "0" is set for a normal reply and  
other than "0" is set for data fault, mode error, etc.  
For a normal reply, the reply data to the instruction specified by the  
instruction code is set.  
RWrn+14  
RWrn+15  
RWrn+16  
RWrn+17  
RWrn+18  
RWrn+19  
Reply code 4  
Read data 4  
Reply code 5  
Read data 5  
Reply code 6  
Read data 6  
Reserved  
When (RYnF) is on, the response code correspond to the instruction  
code of (RWw n+16) is set. The value "0" is set for a normal reply and  
other than "0" is set for data fault, mode error, etc.  
For a normal reply, the reply data to the instruction specified by the  
instruction code is set.  
When (RYnF) is on, the response code correspond to the instruction  
code of (RWw n+18) is set. The value "0" is set for a normal reply and  
other than "0" is set for data fault, mode error, etc.  
For a normal reply, the reply data to the instruction specified by the  
instruction code is set.  
RWrn+1A  
to  
Do not use it.  
RWrn+1F  
"n" is depend on the station number.  
- 27 -  
 
E658130  
5.5.8. Instruction Codes  
Code No.  
1003H  
Item  
Description  
0: Terminal block  
Command mode selection  
read  
1: Panel keypad (including extension panel)  
2: RS485 communication  
3: No function  
Command mode selection  
write  
2003H  
1004H  
4: Communication option  
0: Setting dial 1(save even if power is off)  
1: Terminal VIA  
Frequency setting mode  
selection read  
2: Terminal VIB  
3: Setting dial 2(press in center to save)  
4: RS485 communication  
5: UP/DOWN from external logic input  
6: No function  
7: Communication option  
8: Terminal VIC  
Frequency setting mode  
selection write  
2004H  
9, 10: -  
11: Pulse train input  
12, 13: -  
14: sro  
0000H to FFFFH:  
0072H  
Special monitor  
Monitor value selected after choosing instruction code 00F3H.  
Read the content that was monitored by special monitor.  
Special monitor code read  
read 0073H  
Special monitor selection  
Trip history No.1, No.2 read  
Trip history No.3, No.4 read  
Trip history No.5, No.6 read  
Trip history No.7, No.8 read  
Frequency command value  
(RAM) read  
Select the monitor code of special monitor.  
Read the No.1 and No.2 of trip information.  
Read the No.3 and No.4 of trip information.  
Read the No.5 and No.6 of trip information.  
Read the No.7 and No.8 of trip information.  
write 00F3H  
0074H  
0075H  
0076H  
0077H  
006DH  
Read the frequency command value (RAM).  
Option frequency command  
value (EEPROM&RAM) write*  
Trip history clear  
00EDH  
00F4H  
00FCH  
00FDH  
Write the option frequency command value (EEPROM &RAM).  
9696H: Clear all trip histories.  
9696H: Clear all parameters. (Parameters other than  
proofreading values are made into factory default settings.)  
9696H: Reset the inverter.  
Parameter all clear  
Inverter reset  
To read parameters f000to f984, add the triple figures  
that follow Fxxx to 1000H.  
1000H to 1999H  
(1000H to  
(Ex: f984-> 984 + 1000 = 1984)  
Read parameters (RAM)  
1F99H)  
No error occurs when you select 1A00 to 1F99.  
Because these parameters are for maintenance.  
Write parameters  
To write parameters f000to f984, add the triple figures  
2000H to 2999H  
that follow Fxxx to 2000H.  
(EEPROM&RAM) *  
- 28 -  
 
 
E658130  
Code No.  
Item  
Description  
To read parameters a900to c999, 6000H is subtracted  
from the parameter number.  
4900H to 6999H Read parameters (RAM)  
(Ex: A900 A900H – 6000H = 4900H,  
C123 -> C123H – 6000H = 6123H)  
To write parameters a900to c999, the parameter  
number doesn't change.  
Write parameters  
A900H to  
C999H  
(EEPROM&RAM) *  
(Ex: A900 -> A900H, C123 -> C123H)  
* The Life of EEPROM is approximately 100,000 times. Avoid writing a command more than 100,000 times  
to  
the same parameter of the drive and the option module.  
- 29 -  
 
E658130  
5.5.9. The details of an error code  
The following data are stored as fault history data when the inverter trip occurred.  
Error code  
Description  
Decimal Hexadecimal  
Trip display  
No.  
No.  
0
00H  
No error  
nerr  
oc1  
oc2  
oc3  
ocl  
1
2
3
4
01H  
02H  
03H  
04H  
Overcurrent during acceleration  
Overcurrent during deceleration  
Overcurrent during constant speed operation  
Overcurrent  
(An overcurrent on the load side at start-up)  
Overcurrent at start-up  
Input phase failure  
5
05H  
08H  
09H  
0AH  
0BH  
0CH  
0DH  
OEH  
0FH  
10H  
11H  
12H  
13H  
14H  
15H  
16H  
17H  
18H  
1AH  
1BH  
1CH  
1DH  
1EH  
20H  
22H  
28H  
29H  
2DH  
oca  
ephi  
epho  
op1  
8
9
Output phase failure  
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
20  
21  
22  
23  
24  
26  
27  
28  
29  
30  
32  
34  
40  
41  
45  
Overvoltage during acceleration  
Overvoltage during deceleration  
Overvoltage during constant-speed operation  
Inverter overload  
op2  
op3  
ol1  
Motor overload  
ol2  
Dynamic braking resistor overload trip  
Overheat  
olr  
oh  
Emergency stop  
e
EEPROM fault 1  
eep1  
eep2  
eep3  
err2  
err3  
err4  
err5  
err7  
err8  
err9  
uc  
EEPROM fault 2  
EEPROM fault 3  
Main unit RAM fault  
Main unit ROM fault  
CPU fault 1  
Communication error  
Current detector fault  
Optional unit fault 1  
Remote keypad disconnection fault  
Low-current operation fault  
Undervoltage fault (main circuit)  
Over-torque trip 1  
up1  
ot  
Ground fault  
ef2  
Auto-tuning error  
etn  
Inverter type error  
etyp  
e-13  
Over speed fault  
Thermal fault stop command from external  
device  
46  
47  
2EH  
2FH  
oh2  
Step-out (for PM motor drive only)  
sout  
- 30 -  
 
 
E658130  
Error code  
Description  
Decimal Hexadecimal  
Trip display  
No.  
50  
51  
52  
53  
55  
58  
62  
64  
65  
69  
71  
72  
73  
84  
85  
86  
No.  
Analog input break detection fault  
CPU communications error  
Over torque boost fault  
CPU fault 2  
32H  
33H  
34H  
35H  
37H  
3AH  
3EH  
40H  
41H  
45H  
47H  
48H  
49H  
54H  
55H  
56H  
e-18  
e-19  
e-20  
e-21  
e-23  
e-26  
ol3  
Optional unit fault 2  
CPU fault 3  
Main module overload  
PTC fault  
e-32  
ot2  
Over-torque trip 2  
Servo lock fault  
e-37  
e-39  
otc3  
utc3  
etn1  
etn2  
etn3  
Auto-tuning error (PM motor)  
Over-torque / Overcurrent fault  
Small-torque / Small -current fault  
Auto-tuning error  
Auto-tuning error  
Auto-tuning error  
Fault record display example  
(instruction code H74)  
For read data: 011BH  
b15  
0
b8 b7  
b0  
0
0
0
0
0
0
0
1
1
0
0
0
0
0
1
1
0
1
1
Fault record 2  
(01H: oc1)  
Fault record 1  
(1BH: err8)  
(instruction code H74)  
For read data021CH  
b15  
0
b8 b7  
b0  
0
0
0
0
0
0
1
1
1
0
0
Fault record 4  
Fault record 3  
(02H: oc2)  
(1CH: err9)  
- 31 -  
 
E658130  
5.5.10.  
Description of reply code  
When executing the frequency setting (RYnD) or instruction code execution (RYnF), check the  
reply code (RWr (n+2), (n+10), (n+14), (n+16), (n+18)) in the remote register after execution.  
Reply code  
Data  
Item  
Description  
(Hexadecimal No.)  
Normal completion of instruction code  
execution.  
0000H  
Normal (No error)  
Parameter write was attempted during operation  
other than a stop.  
0001H  
Write mode error  
Parameter selection  
error  
0002H  
0003H  
Unregistered code number was set.  
Setting range error  
Set data is outside the setting data range.  
- 32 -  
 
 
E658130  
5.5.11.  
Description of monitor code  
Divide the monitor code (RWw n) into half and select the monitor value 1 (RWr n) from the  
lower 8 bits and the monitor value 2 (RWr n) from the upper 8 bits.  
For Example: When output voltage is selected for the monitor value 1 and output torque is  
selected for the monitor value 2. -> The monitor code is 0703H.  
Address  
RWw n  
Upper 8 bits  
Lower 8 bits  
Monitor value 1  
Monitor value 3  
Monitor value 4  
Monitor value 5  
Monitor value 6  
Monitor value 2  
RWw n+4  
RWw n+5  
RWw n+6  
RWw n+7  
-
-
-
-
Monitor code (When an invalid monitor code is set up, monitor value fixes to 0.)  
Second Monitor Description  
(upper 8 bits)  
Output frequency  
First Monitor Description  
Code Number  
00H  
Unit  
(lower 8 bits)  
None monitor (Monitor value is 0)  
0.01Hz  
(Only the second monitor )  
01H  
02H  
03H  
Output frequency  
Output current  
Output voltage  
Output frequency  
Output current  
Output voltage  
0.01Hz  
0.01A  
0.1V  
04H  
05H  
06H  
07H  
None monitor (Monitor value is 0)  
Frequency command value  
Output speed  
Output torque (With sign)  
DC voltage  
None monitor (Monitor value is 0)  
Frequency command value  
Output speed  
Output torque (With sign)  
DC voltage  
0.01Hz  
1min-1  
0.1%  
0.1V  
08H  
09H  
0AH  
0BH0CH  
0DH  
0EH  
PBR load factor  
PBR load factor  
0.1%  
0.1%  
Motor overload factor  
None monitor (Monitor value is 0)  
Input power  
Output power  
Input terminal information  
Motor overload factor  
None monitor (Monitor value is 0)  
Input power  
Output power  
Input terminal information  
0.01kW  
0.01kW  
0FH  
10H  
11H  
12H  
13H  
14H  
Output terminal information  
Output current  
Exciting current  
None monitor (Monitor value is 0)  
Cumulative operation time  
None monitor (Monitor value is 0)  
Accumulation power supply ON time  
Motor overload factor  
Output terminal information  
Output current  
Exciting current  
None monitor (Monitor value is 0)  
Cumulative operation time  
None monitor (Monitor value is 0)  
Accumulation power supply ON time  
Motor overload factor  
0.1%  
0.01A  
1h  
15H16H  
17H  
1h  
0.1%  
18H  
19H  
Integral input power  
Integral input power  
1kWh  
1AH  
1BH  
1CH  
Integral output power  
Analog input(VIA)  
Analog input(VIB) (With sign)  
Analog input(VIC)  
None monitor (Monitor value is 0)  
Torque current (With sign)  
None monitor (Monitor value is 0)  
Factory specific monitor  
PID feedback value  
Integral output power  
Analog input(VIA)  
Analog input(VIB) (With sign)  
Analog input(VIC)  
None monitor (Monitor value is 0)  
Torque current (With sign)  
None monitor (Monitor value is 0)  
Factory specific monitor  
PID feedback value  
1kWh  
0.01%  
0.01%  
0.01%  
1DH  
1EH1FH  
21H  
0.1%  
22H  
23H  
24H  
0.01Hz  
- 33 -  
 
 
E658130  
5.5.12.  
Description of input terminal information  
Data composition of input terminal information (Code No. = 0FH).  
Bit  
0
Terminal name  
F
Function (parameter name)  
0
1
Input terminal function selection  
1A(f111)  
/
1B(f151)  
/
/
1C(f155)  
1
R
Input terminal function selection  
2A(f112)  
/
2B(f152)  
2C(f156)  
2
RES  
S1  
Input terminal function selection  
3A(f113) / 3B(f153)  
Input terminal function selection  
4A(f114) / 4B(f154)  
Input terminal function selection  
5(f115)  
3
OFF  
ON  
4
S2  
5
S3  
Input terminal function selection  
6(f116)  
6
7
VIB  
VIA  
Input terminal function selection  
7(f117)  
Input terminal function selection  
8(f118)  
8 to 15  
5.5.13.  
Description of output terminal information  
Data composition of input terminal information (Code No. = 10H).  
Bit  
0
Terminal name  
RY-RC  
Function (parameter name)  
0
1
Output terminal function selection  
1A(f130) / 1B(f137)  
Output terminal function selection  
2A(f131) / 2B(f138)  
Output terminal function selection  
3(f132)  
1
2
OUT  
FL  
OFF  
ON  
3 to 15  
- 34 -  
 
   
E658130  
6. Programming examples  
This chapter provides programming examples which control the inverter with the PLC.  
Item  
Programming Example  
Refer to Page  
Reading the inverter status from the buffer  
memory of the master station.  
Reading the inverter status  
Setting the command mode  
Command mode from CC-Link is confirmed.  
Commanding the forward rotation.  
Setting to 50.00Hz.  
Setting the operation commands  
Setting the reference frequency  
Setting the monitoring function  
Monitoring the output frequency.  
Setting the f311[Reverse-run prohibition  
selection] to [1 : Prohibit reverse run].  
Reading the parameter f311.  
Reading the fault record  
Writing a parameter value  
Reading a parameter value  
Reading the the fault record  
Inverter reset  
Resetting the inverter.  
System configuration for programming example  
Master unit  
Station 2  
Inverter  
Station 1  
Inverter  
PS  
Q02  
QJ61  
BT11N  
Input  
Unit  
Output  
Unit  
Unit CPU  
(X/Y00  
to 1F)  
(X20  
to X2F)  
(Y30  
to 3F)  
X0020  
Y30  
CC-Link communication cable  
The example of CC-Link communication network composition  
CPU  
Mitsubishi Electric Corp.  
Mitsubishi Electric Corp.  
Mitsubishi Electric Corp.  
Mitsubishi Electric Corp.  
Kuramo Electric Corp.  
Toshiba  
Q02CPU  
Master unit  
QJ61BT11N  
QX40  
Input module  
Output module  
CC-Link dedicated cable  
Inveter  
QY40P  
FANC-110SBH  
TOSVERT VF-S15(2 uints)  
One station is occupied  
CCL003Z(2 units)  
CC-Link option  
Toshiba  
- 35 -  
 
 
E658130  
2. Network parameter setting of the master station  
Network parameters are set as below.  
Item  
Setting Conditions  
Item  
Setting Conditions  
Start I/O No.  
Operation Data link alarm  
0000  
Remote register (RWw)  
Special relay (SB)  
Special resister (SW)  
Retry count  
W100  
SB0  
SW0  
3
Input clear  
settings  
station setting  
Setting at CPU  
stop  
Refresh  
Automatic reconnection  
station count  
1
Type  
Master  
Remote net  
Ver.1 mode  
2
Mode  
CPU down select  
Scan mode settings  
Stop  
Asynchronous  
Remote device  
station  
All connect count  
Station  
Station  
type  
Remote input (RX)  
Remote output (RY)  
Remote register (RWr)  
X1000  
Y1000  
W0  
information  
- 36 -  
 
E658130  
3. The relation between the device of the  
programmable controller CPU and remote I/O  
(RX,RY) of the remote device station is as follows:  
The devices used actually are indicated in shaded  
regions.  
4. The relation between the device of the  
programmable controller CPU and remote register  
(RWw, RWr) of the remote device station is as  
follows:  
The devices used actually are indicated in shaded  
regions.  
Remote device station  
CPU of PLC  
For writing  
W100  
Remote device station  
(station 1)  
RWw0  
CPU of PLC  
X1000 to X100F  
X1010 to X101F  
X1020 to X102F  
X1030 to X103F  
X1040 to X104F  
X1050 to X105F  
(station 1)  
RX00 to RX0F  
RX10 to RX1F  
W101  
RWw1  
W102  
RWw2  
RY00 to RY0F  
RY10 to RY1F  
W103  
RWw3  
W104  
W105  
RWr0  
RWr1  
RWr2  
RWr3  
Remote device station  
(station 2)  
W106  
Y1000 to Y100F  
Y1010 to Y101F  
Y1020 to Y102F  
Y1030 to Y103F  
Y1040 to Y104F  
Y1050 to Y105F  
W107  
RX20 to RX2F  
RX30 to RX3F  
W109  
W10A  
For reading  
W000  
W001  
W002  
W003  
W004  
W005  
W006  
W007  
W008  
W009  
W00A  
Remote device station  
(station 2)  
RWw4  
RY20 to RY2F  
RY30 to RY3F  
RWw5  
RWw6  
RWw7  
RWr4  
RWr5  
RWr6  
RWr7  
- 37 -  
 
E658130  
6.1. Program example for reading the inverter status  
Example 1 shows a ladder logic to read the inverter status.  
Y30 of the output unit is turned on when inverter of station 2 is forward running  
X0  
SW80.1  
X0F  
X1  
( M0 )  
Check the ready of the station 2  
M0  
X1020  
Turn on the relay of output  
unit (Y30)  
( Y30 )  
[END]  
Example  
Remote input  
b15  
0
b8 b7  
b0  
0
0
0
*
0
0
0
0
0
0
0
0
0
0
RX0 to RXF  
Station1  
Station 2  
1
RX10 to RX1F  
RX20 to RX2F  
RX30 to RX3F  
[Inverter  
Inverter status  
b0: Forward running  
b1: Reverse running  
b2: Output terminal 1  
b3: Output terminal 2  
b4: Output terminal 3  
b5: Failure FL  
X0:  
Module error  
X1:  
Host data link status  
Module ready  
b6: PI control OFF  
X0F:  
SW80.1: Station 2 ready  
b7: Acceleration/deceleration pattern selection (1 or 2)  
b8: Emergency stop  
b9: Coast stop  
b10: Alarm  
- 38 -  
 
 
E658130  
6.2. Program example for setting the operation mode  
Example 2 shows a ladder logic to write data in the inverter.  
The operation mode of station 1 inverter can be changed to network operation.  
Operation mode writing code number: 2003H (hexadecimal)  
Network operation set data: 0004H (hexadecimal)  
The reply code at the time of instruction code execution is set to D2.  
X0  
SW80.0  
X0F  
X20  
X1  
( M0)  
[ PLS M300]  
Check the ready of the station 1  
M0  
M300  
M301  
[ SET M301]  
X100F  
Write operation mode write code  
(2003H) to RWw2 and set data  
(0004H) to RWw3.  
[ MOV H2003 W102]  
[ MOV H0004 W103]  
[ SET Y100F]  
Turn on the instruction code  
execution  
[ RST M301]  
[ SET M302]  
Read reply code (RWr2) to D2 when the  
Instruction code execution completion  
flag  
M302  
X100F  
[ MOV W2 D2]  
[ RST Y100F]  
Turn off the instruction code  
execution  
[ RST M302]  
[ END]  
Example  
- 39 -  
 
 
E658130  
6.3. Program example for setting the operation commands  
Example 3 shows a ladder logic to give a forward command to station 2 inverter.  
X0  
X0F  
X20  
SW80.1  
X1  
Check the ready of the Station 2  
( M0)  
M0  
Forward rotation command (RY20)  
(Y1020)  
Example 3  
6.4. Program example for setting the running frequency  
Example 4 shows a ladder logic to chang the running frequency of station 1 inverter to  
50.00Hz  
Set frequency: 5000 (decimal)  
X0  
SW80.0  
X0F  
X20  
X1  
( M0)  
Check the ready of the station 1  
M0  
[ PLS M300]  
[ SET M301]  
M300  
M301  
X100D  
[ MOV K5000 W101]  
Write set frequency to  
Turn off the frequency setting  
command RAM (RY0D)  
[ SET Y100D]  
[ RST M301]  
[ SET M302]  
Turn off instruction frequency writing  
(RY0D), when instruction frequency  
writing completion flag (RX0D) is  
turned on.  
M302  
X100D  
[ RST Y100D]  
[ RST M302]  
[ END]  
Example  
- 40 -  
 
   
E658130  
6.5. Program example for monitoring the output frequency  
Example 5 shows a ladder logic to read the output frequency of station 1 inveter to D1.  
Output frequency reading code number: 0001H (hexadecimal)  
When the output frequency is 50Hz, D1 is 1388H (5000) (unit: 0.01Hz).  
X0  
SW80.0  
X0F  
X20  
X1  
( M0)  
[ MOV H1 W100]  
( Y100C)  
Check the ready of the station 1  
M0  
Set monitor code (H0001) of output  
frequency to RWw0.  
Turn on the monitor command (RY0C)  
X100C  
[ MOV W1 D1]  
[ END]  
Read output frequency (RWr0) to D1  
when the monitoring flag (RX0C) turns on.  
Example 5  
- 41 -  
 
 
E658130  
6.6. Program example for parameter writing  
Example 6 shows a ladder logic to chang the setting of f311of station 1 inverter to 1  
f311: Reverse-run prohibition reading code number: 2311H (hexadecimal)  
Reverse-run prohibition set data: 1 (decimal)  
X0  
SW80.0  
X0F  
X20  
X1  
( M0)  
Check the ready of the Station 1  
M0  
[ PLS M300]  
[ SET M301]  
M300  
M301  
X100F  
[ MOV H2311 W102]  
Write f311write code (2311H) to  
RWw2 and reverse-run prohibition  
setting  
[ MOV K1 W103]  
[ SET Y100F]  
[ RST M301]  
Turn on the instruction code  
execution  
[ SET M302]  
Read reply code (RWr2) to D2 when the  
Instruction code execution completion  
flag  
M302  
X100F  
[ MOV W2 D2]  
[ RST Y100F]  
[ RST M302]  
Turn off the instruction code  
execution  
[ END]  
Example  
- 42 -  
 
   
E658130  
6.7. Program example for parameter reading  
Example 7 shows a ladder logic to read parameter f311of station 1 inverter to D2.  
f311: Reverse-run prohibition reading code number: 1311H (hexadecimal)  
The reply code at the time of instruction code execution is set to D1.  
X0  
SW80.0  
X0F  
X20  
X1  
( M0)  
Check the ready of the station 1  
M0  
[ PLS M300]  
[ SET M301]  
M300  
M301  
Write f311 read code (1311H)  
X100F  
to  
[ MOV H1311 W102]  
[ SET Y100F]  
Turn on the instruction code  
execution  
[ RST M301]  
[ SET M302]  
M302  
X100F  
Read reverse-run prohibition (RWr3) and  
reply code (RWr2) to D2 and D1 when  
[ MOV W2 D1]  
the  
instruction  
code  
execution  
completion  
[ MOV W3 D2]  
[ RST Y100F]  
[ RST M302]  
[ END]  
Turn off the instruction code  
execution  
Example 7  
- 43 -  
 
   
E658130  
6.8. Program example for trip information reading  
Example 8 shows a ladder logic to read the trip information of station 1 inverter to D1.  
Trip history No. 1, No. 2 reading code number: 74H (hexadecimal)  
The reply code at the time of instruction code execution is set to D2.  
X0  
SW80.0  
X0F  
X20  
X1  
( M0)  
Check the ready of the Station 1  
M0  
[ PLS M300]  
[ SET M301]  
M300  
M301  
X100F  
Write trip history No.1, No.2 read  
code (H74) to RWw2.  
[ MOV H74 W102]  
[ SET Y100F]  
Turn on the instruction code execution  
request (RY0F)  
[ RST M301]  
[ SET M302]  
M302  
X100F  
[ MOV W2 D1]  
Read alarm data (RWr3) and reply code  
(RWr2) to D1 and D2 when the  
instruction code execution completion  
flag (RX0F) turns on.  
[ MOV W3 D2]  
Turn off the instruction code execution  
request (RY0F)  
[ RST Y100F]  
[ RST M302]  
[ END]  
Example  
For example of trip information  
Read dara: 2D0EH  
b15  
b8 b7  
b0  
0
0
1
0
1
1
0
1
0
0
0
0
1
1
1
0
(2DH)  
Past trip code  
(0EH)  
Current trip code  
e-13(Error code: 2DH)  
ol2(Error code: 0EH)  
" Over speed fault "  
" Motor overload "  
Refer to 5.5.9 for detail.  
}
- 44 -  
 
 
E658130  
6.9. Program example for resetting the inverter at inverter error  
Example 9 shows a ladder logic to reset the station 2 inverter.  
X0F  
SW80.1  
X1  
X2  
X0  
M
[ M0  
[Y103A]  
[ END  
Check the ready of the station 2  
X103  
Turn on the error reset request flag  
(RY3A). Then, turn off the error  
reset  
request flag (RY3A) when the error  
Example  
The above inverter reset using RY3A may be made only when an inverter error occurs.  
Also, inverter reset can be made independently of the operation mode.  
- 45 -  
 
 
E658130  
6.10. Instructions  
1.Programming instructions  
1.1 Since the buffer memory data of the master station is kept transferred (refreshed)  
to/from the inverters, the TO instruction need not be executed every scan in  
response  
to data write or read requests.  
The execution of the TO instruction every scan does not pose any problem.  
1.2 If the FROM/TO instruction is executed frequently, data may not be written reliably.  
When transferring data between the inverter and sequence program via the buffer  
memory, perform the handshake to confirm that data has been written without error.  
2. Operating and handling instructions  
2.1 Command only from the programmable controller can be accepted during operation  
from CC-Link communication.  
The run command from external and parameter unit is ignored.  
2.2 If the station number of two or more inverters is the same, wrong data will be  
transferred and normal communication cannot be made.  
2.3 If a network error (controller fault , an open CC-LINK dedicated cable, etc)  
continues past the time set in c100during CC-Link operation, it is recognized  
as a communication error and the operation of the inverter follows the setting  
of c101.  
2.4 When the programable controller (master) is reset or the power supply of the  
programable controller (master) is turned off during CC-Link operation,  
data communication stops and an inverter follows the setting of c101.  
- 46 -  
 
 
E658130  
7. Unusual diagnosis  
7.1. Option error  
The error message is displayed when there is hardware error, software error or lose of  
connection of wire.  
Display of trip information  
e-23(Optional unit fault 2 : 0037H) : Option error  
7.2. Disconnection error of network cable  
Display of trip information  
err8(Optional unit fault 1: 001BH): Network error stop  
*If a network error occurs when c101is set to "4", it is displayed.  
Related parameter  
Title  
Function  
Setting range  
Description  
The waiting time from when a network error occurs  
can be adjusted. If a network error continues past the  
time set in c100, it is recognized as a  
communication error and the operation of the inverter  
follows the setting of c101.  
Communication error  
detection delay time  
When normal communication returns during the  
setting time, a communication error is not displayed  
and operation is continued.  
c100  
0.0 to100.0 sec  
* Time-out time = CC-Link network time out  
+ c100  
(communication error detection delay time) [0.1s]  
The operation of the drive when the communication  
fault occurs can be specified.  
The operation frequency of the drive when the  
communication fault occurs can be specified. (Only  
when c101is set to 5)  
Inverter operation at the  
communications loss action  
c101  
c102  
c103  
0 to 5  
0 to 15  
0 to 2  
Preset speed operation  
selection  
Communication time-out  
condition selection  
Select the communication time-out condition.  
- 47 -  
 
     
E658130  
7.3. How to check the error using the LEDs  
The following example explains the causes of fault which may be judged from the LED  
status of the CC-Link unit (CCL003Z) of the inverter.  
1. When One Inverter Is Connected  
The following example indicates the causes of faults which may be judged from the LED status  
of the CC-Link unit (CCL003Z) of the inverter under the condition that the SW, M/S and PRM  
LEDs of the master unit are off (the master unit setting is correct) in the system configuration  
where one inverter is connected.  
P
S
Station  
1
Master  
Unit  
CPU  
inverter  
PS:  
Power  
supply  
LED Status  
Cause  
Corrective Action  
L.RUN  
SD  
RD  
L.ERR  
Normal communication is  
made but CRC error has  
occurred due to noise.  
Check that the communication cable is  
connected to SLD.  
Also wire it as far away as possible from  
the power lines.(200mm or more)  
After correcting the baud rate and/ir  
station number setting, switch power on  
again.  
Baud rate or station number  
was changed during  
operation.  
Normal communication  
-
Cannot answer due to CRC  
error of receive data.  
Check that the communication cable is  
connected to SLD.  
Also wire it as far away as possible from  
the power lines.(200mm or more)  
Check the network transmission setting  
and the sequence program on the PLC  
side.  
Data sent to the host station  
does not reach destination.  
Hardware fault  
(There is a possibility of the  
instability of the  
Check for contact fault, break in the cable,  
etc.  
communication by the  
disconnection.)  
Polling response is made but Check that the communication cable is  
refresh receive is in CRC  
error.  
connected to SLD.  
Also wire it as far away as possible from  
the power lines.(200mm or more)  
Check that the communication cable is  
connected to SLD.  
Also wire it as far away as possible from  
the power lines.(200mm or more)  
Data sent to the host station  
is in CRC error.  
There is no data sent to the Check that the communication cable is  
host station, or data sent to connected to SLD.  
the host station cannot be Also wire it as far away as possible from  
received due to noise.  
Cannot receive data due to  
break in the cable, etc.  
WDT error occurrence  
(hardware fault), power off,  
power supply failure  
the power lines.(200mm or more)  
Check for contact fault, break in the cable,  
etc.  
Check that CCL003Z is fitted properly.  
:On, ○:OFF, :Flicker, : Any of on, flicker or off.  
- 48 -  
 
 
E658130  
2.When two or more inverters are connected  
The following example explains the causes and corrective actions for fault which may be  
judged from the LED status of the CC-Link units (CCL003Z) of the inverters under the  
condition that the SW, M/S and PRM LEDs of the master unit are off (the master unit setting is  
proper) in the system configuration shown below:  
P
S
Master  
Unit  
Station  
1
Station  
2
Station  
3
CPU  
Inverter  
Inverter  
Inverter  
PS:  
Power  
supply  
LED Status  
Cause  
Corrective Action  
CCL003Z  
Station 2  
Master  
Station 1  
L.RUN  
SD  
Station 3  
L.RUN  
SD  
RD  
L.ERR  
L.RUN  
SD  
Normal  
L.RUN  
SD  
RD  
-
TIME○  
LINE○  
or  
TIME●  
LINE○  
RD  
L.ERR  
L.RUN  
SD  
L.ERR  
L.RUN  
SD  
Poor contact of the  
CCL003Z with the  
Inverter or the power  
supply is not supplied.  
Plug the CCL003Z  
securely.  
Check the connector.  
RD  
RD  
RD  
L.ERR  
L.RUN  
SD  
RD  
L.ERR  
L.ERR  
L.RUN  
SD  
L.ERR  
L.RUN  
SD  
RD  
L.ERR  
Since the L.RUN LEDs  
of station 2 and later are  
off, the communication  
cable between the unit 1 repair.  
and 2 is open or  
Referring to the LED  
"on" condition, search  
for an open point and  
RD  
L.ERR  
disconnected from the  
terminal block.  
The communication  
cable is shorted.  
TIME●  
LINE●  
or  
TIME○  
LINE●  
Among the three wires  
L.RUN  
SD  
RD  
L.RUN  
SD  
RD  
L.RUN  
SD  
RD  
of the communication  
cable, search for  
shorted wire and  
repair.  
L.ERR  
L.ERR  
L.ERR  
The communication  
cable is wired improperly. CCL003Z terminal  
block and correct the  
Check the wiring on  
L.RUN  
SD  
RD  
L.RUN  
SD  
RD  
L.RUN  
SD  
RD  
improper wiring point.  
L.ERR  
L.ERR  
L.ERR  
:On, ○:OFF, :Flicker, *: Any of on, flicker or off.  
- 49 -  
 
E658130  
3. Communication stops during operation  
Check that the CC-Link units and the CC-Link dedicated cable are connected properly.  
(Check for contact fault, break in the cable, etc.)  
Check that the PLC program is executed properly.  
Check that data communication has not stopped due to an instantaneous power failure, etc.  
LED Status  
Cause  
Corrective Action  
CCL003Z  
Station 2  
Master  
Station 1  
L.RUN  
SD  
Station 3  
L.RUN  
SD  
The station numbers of After correcting the  
station 1 and 3 are  
duplicated.  
L.RUN  
repeated station  
numbers of the inverters,  
switch power on again.  
SD  
RD  
RD  
RD  
L.ERR  
L.RUN  
SD  
L.ERR  
L.RUN  
SD  
L.ERR  
L.RUN  
SD  
TIME○  
LINE○  
or  
TIME●  
LINE○  
The baud rate setting of After correcting the Baud  
station 2 is different  
from master unit.  
rate setting, switch  
power on again.  
RD  
RD  
RD  
L.ERR  
L.RUN  
SD  
L.ERR  
L.RUN  
SD  
L.ERR  
L.RUN  
SD  
The setting data of  
station 3 was changed  
during normal  
After returning the setting  
switch to the correct  
position, power on the  
inverter again.  
RD  
RD  
RD  
operation.  
L.ERR  
L.RUN  
SD  
RD  
L.ERR  
L.ERR  
L.RUN  
SD  
L.ERR  
L.RUN  
SD  
RD  
L.ERR  
Station 2 is affected by  
noise. (L.RUN may put  
out the light.)  
Securely connection FG  
of each inverter and  
master to ground.  
RD  
L.ERR  
the communication  
cable between the  
inverters of stations 2  
and 3 are affected by  
noise. (L.RUN may put  
out the light.)  
Check that the  
communication cable is  
connected to SLD.  
L.RUN  
SD  
L.RUN  
SD  
L.RUN  
SD  
TIME●  
LINE●  
or  
TIME○  
LINE●  
Also wire it as far away  
RD  
RD  
RD  
as  
possible from the  
power lines.(200mm or  
more)  
L.ERR  
L.ERR  
L.ERR  
Check that the terminal  
resistors are connected.  
L.RUN  
SD  
RD  
L.RUN  
SD  
RD  
L.RUN  
SD  
RD  
Terminal resistors are  
left un-connected.  
(L.RUN may put out  
the light.)  
L.ERR  
L.ERR  
L.ERR  
:On, ○:OFF, :Flicker, *: Any of on, flicker or off.  
- 50E -  
 

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