clip cab 2c/fig8 0.75mm2 pk200

General Accessories Cable Clip To Suit 0.75Mm², Flat Figure, 8 Flex, Box 200

Catalogue Number: 564/00
clip cab 2c/fig8 0.75mm2 pk200
Colour:
Colour: Per UOM Std.
  • 1 PCE

Specifications

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Product brand
Clipsal
Shape
rectangular
Material
plastic
EU RoHS Directive
Compliant
Mercury free
Yes
RoHS exemption information
Yes
China RoHS Regulation
Product out of China RoHS scope. Substance declaration for your information

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Frequently Asked Questions

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Is the 564/1J clip cable 3 core available in black

No, it is only available in white

What are the nine current settings on the Vigirex relay catalog number 56372 (56372TD), or RH99M?

Product Line:
Circuit Breakers

Environment:
Electrical Distribution Equipment

Resolution:
The settings are 30ma, 100ma, 300ma, 500ma, 1A, 3A, 5A, 10A, 30A.

568/20-WE Clipsal Grommet what is carton quantity?

 
   
 
 100 per carton 
 See attachment for more information 

Can I purchase the Clipsal 54800 series in New Zealand

No, you will need to contact Clipsal Australia as we do not support that product in New Zealand

What is the maximum frequency of a Vijeo Designer Periodic Action

The frequency range for a periodic action in Vijeo Designer version  6.2 is 0.1 seconds to 86400 seconds (24 hours)

PowerChute Network Shutdown remaining runtime threshold does not trigger OS shutdown when communicating with SURTD when NMC 1 is installed.

Issue:
PowerChute Network Shutdown remaining runtime threshold does not trigger OS shutdown when communicating with SURTD when NMC 1 (AP9617, AP9618, AP9619) is installed. The OS remains running until the UPS reaches low battery and then the OS is commanded to power down due to low battery. 

Product Line:
PowerChute Network Shutdown

Environment:
All supported OS

Cause:
SURTD reports the remaining runtime to PowerChute in seconds when PowerChute is expecting to receive the time in minutes. 

Solution:
PowerChute expects the threshold to be entered in seconds so to compensate for the difference in time multiply time by 60.

Shutdown Examples
Shut OS down when UPS fails below 25 minutes = 1500 seconds x 60 = 90000 seconds 
Shut OS down when UPS fails below 20 minutes = 1200 seconds x 60 = 72000 seconds
Shut OS down when UPS fails below 15 minutes = 900 seconds x 60 = 54000 seconds
Shut OS down when UPS fails below 10 minutes = 600 seconds x 60 = 36000 seconds

Another option is to replace the NMC with AP9630 or AP9631. The AP9630 and AP9631 do not exhibit the issue. 

How do I scale 0 - 4095 to 6400 - 32000 using 984 Ladder Logic?

The following network scales data from 0-4095 to 6400 - 32,000 when 4-20ma (6400 = 4 mA, 32,000 = 20 mA) outputs are required
but a 0-20ma analog output is used. .





Register 400001 and 400002 are used together in the top node of the EMTH Block, where 400001 is
always 0000 data and 400002 is the variable data, 0-4095, to be scaled. Register 400003, displayed in data
format float, is a fixed floating point value that the user enters as 6.25153 (note that two registers are
used to create the floating point value, 400003 & 400004 in this example). Register 400005 (and 400006)
is the floating point result of the integer and floating point multiplication (EMTH block).





The FTOI (Floating Point TO Integer) block converts the floating point result of registers 400005
and 400006 to an integer value in a single register 400007.

The AD16 block adds the top node register 400007 to the middle node constant 6400 and places
the result in register 400009. This register will then map to one of the analog outputs.

The following data screens shows the input values of 0 and 4095 and there corresponding results.





How do you setup the ATV21 and ATV212 drives for Modbus?

Issue:
ATV21/ATV212 programmed for Modbus.

Product Line:
ATV21 and ATV212

Environment:
All

Cause:
Modbus setup for the ATV21 and ATV212 drives

Resolution:

Monitor only set up example:

CNOD=0  terminal control
FNOD= 2 for VIB

THr = FLA of motor name plate

F----  enter
F108= 48  Force to local mode
F802= 1  modbus address
F803= 10  Time out for modbus
F807= 1  screw terminals for modbus  or 0 for RJ45 (ATV212 only)

F800= 1 19200  RJ45 port only (must be same as customers controller)
F801= 1 Even Parity RJ45 port only (must be same as customers controller)


F820= 1 19200 baud speed (must be same as customers controller)
F821=  1  Even Parity (must be same as customers controller)
F829=  1  modbus RTU (must be same as customers controller)

(note F807, F820, F821 and F829  is ATV212 only)

 Controlling speed and start stop via modbus change

CNOD=2 modbus control start and stop
FNOD= 4 for modbus speed reference

F108= 0  turn off force to local

 Indirect set up vs Direct setup:

 Indirect set up:  program in the drive F---- codes.

Writing commands to drive

F870 = 1 for CMD command word

F871= 3 for freq ref

 Reading commands from drive:

F875= 1 for ETA status (FD01) you must assign min 2 registers to read.

F876=  2 for output freq (FD00) you must assign min 2 registers to read.

F877= 3 for output current (FE03) optional read
F878= 4 for output voltage (FE05) optional read

F879= 5 for alarm code (FC91) optional read

 Assuming no offset the starting read register for status is address 1875 thru 1879.

Assuming no offset the starting write register for command and speed is address 1870 thru 1871.

 Start FWD the drive write a hex value 400 (or dec 1024) to address 1870 and  speed ref write a dec 6000 for 60 Hz to address 1871.  Works if fnod and cnod is 2 and 4.

Start REV write hex 600 or (dec 1536) to CMD

Stop write a 0 to CMD

Freq ref write a 6000 to  address 1871.

 Note 1: If fnod and cnod is 2 and 0 they can write C400 hex to cmd and it will override terminals control and start the drive.

 

Note 2: If you have a offset you will need to add 1 to each address you read and write to.

Example: with offset you write to address 1871 and send speed to 1872.

Direct configuration means you can write direct to words

No need to set up F870 thru 879 it’s only for indirect configuration

 Writing the command to start and stop the drive:

Starting drive in direct mode CMD word is Hex FA00 or Dec 64000 (write a Dec 1024 or hex 400 to CMD to start the drive.)
Stopping drive in direct mode CMD word is Hex FA00 or Dec 64000 (write a Dec or Hex 0 to the CMD to stop the drive)

Freq reference is hex FA01 or Dec 64001 (write a 6000 in dec for 60 Hz speed reference).

 Reading

ETA status word is Hex FD01 or Dec 64769

Output frequency in Hz is Hex FD00 or Dec 64768

Output current is Hex FE01 or Dec 65027

 Note if you are offset by one you will need to add 1 to each value. 

Example: writing to 64001 for CMD and speed will be 64002 for freq reference.

There is an application with Altivar 38 with pump switching card where the auxiliary pump is driven by an Altistart 48.There is also Modbus connection...

Goals and Symptoms

There is an application with Altivar 38 with pump switching card where the auxiliary pump is driven by an Altistart 48.There is also Modbus connection where the master is a Twido PLC and the slaves are the ATV38 and the ATS 48. The problem is that en error ERR 7 (erreur LS) is appeared at the ATV38 display.What kind of error is that and what can we do about it?

Facts and Changes

ATV38 with Modbus connection

Causes and Fixes

Product trips transiently to "Err3" or "Err7" fault. Both faults type are generated by the display module.
This one communicates with the microprocessor of control card .
When incorrect messages occur during the communication and after some repetition of exchanges , the display module shows to "ErrX".
This is a very difficult fault to reproduce because depending of environment ( lenght of wire between display module and control board , motor running, disrupted site ) and the combination between display module and control board.

Origin of problem :

Insufficient immunity of communication facing the various disturbances.
The communication frames managing is made by integrated components called "drivers". One is located on control board, the same is inside display module. This fault is the result of wrong interpretation of display module of logic level between two communication frames.
This technical conceived problem is appeared from August 2000.

Corrective action:

This failure has been resolved by a modification of two values of resistors inside the display module.
The revision levels become:
· A20, B20 for the ATV58 display modules.
· A02 for the ATV58Fdisplay modules.

This evolution is applied from the week 47/2000 on all manufactured PRODUCTS and all VW3A58101 spare parts.


Information for internal use:

We have noticed that anyway neither control board nor display module have never been directly to the fault origin . Fault "Err X" is always due to the association of two items.

On no account this failure cannot to disrupted the motor running but she can to disturb only the programming of product.

If during the programming, a customer encounters to " Err3 " or " Err7 " with a product manufactured from the week 31/00 to 46/00 , it is advised to exchange only the VW3A58101 display module.

This problem can also appear if the baudrate of internal communication was modified ( subD 9 pins ) and there is a difference between the keypad and internal modbus.

A solution is to reset the inverter with the 50/60 Hz switch to return the baudrate in factory setting, don't forget to accord the Twido PLC.


Legacy KB System (APS) Data: RESL156317 V3.0, Originally authored by on , Last Edited by on
Related ranges: Altivar 38