Overview
Introduction
- The SA380TX can monitor 1 x Bender type IRDH265 / 365 insulation monitor.
- In addition to the isometer, volt-free contact outputs from Bender fault-evaluator devices (such as the SMO480) may also be connected the SA380TX general purpose digital inputs.
- If a 4-20mA output converters such as the RK170 is utilised, this can be connected to the SA380TX general purpose analogue inputs, although RS485 connection is preferred.
- Other models of Bender isometer may be supported over RS485 - check the Bender documentation to see if the RS485 protocol matches
- Please be aware that 1 x SA380TX can only monitor 1 x Bender Isometer. This is a limitation of the Bender protocol, not the SA380TX.
Data Available
Parameter | Units | RS485 | 4-20mA | Digital VFC | Notes |
---|---|---|---|---|---|
Instantaneous Resistance to Earth | k Ohm | This is the last reading of Resistance-to-Earth taken by the isometer | |||
Alert Levels | k Ohm | The isometer permits two configurable alert thresholds. These levels are both reported | |||
Alarm Status | Digital | Reports if either alarm level has been breached | |||
Fault Repeat Relay Status | Digital | Reports if output fault relay has been energised. Essentially mirrors alarm status | |||
Connection Error | Digital | Set to UP or TRUE is not RS485 data has been received from the isometer for 7 minutes. | |||
AC, DC+, DC- Fault | Digital | For DC Systems, Indicates which leg is experiencing the worst fault. For AC systems, only the AC flag will be asserted. | |||
Fault Evaluator Output | Digital | Where a fault evaluator is provided and a single isometer monitors a multiple-feeder arrangement, a digital volt-free-contact output is provided for each feeder. The feeder experiencing the worst fault will have its contact closed. |
These parameters can be continuously monitored to perform long-term trend analysis of cable condition, to alert maintainers of faults that require intervention, and to aid diagnosis of the fault type and location.
Wiring
RS485
Configure the network as shown below using twisted pair cable. Note the use of termination resistors at each end of the link. These are only strictly required for very long cable runs exceeding 1 km in length.
Note that if the isometer is built into a Network Rail style cubicle arrangement, the RS485 connection are brought-out at the base of the cubicle through the terminal block positions 18 and 19
If connecting directly to the isometer. Connect straight to terminals B and A.
4-20mA Analogue Interface
Use of the 4-20mA output is not recommended, but the interface could be employed to connect multiple isometer units to a single SA380TX by utilising spare analogue inputs.
Be aware that the insulation resistance reading will be prone to error due to the unusual equation used by the 4-20mA signal converter:
COMING SOON - THE EQUATION USED BY BENDER
The SA380TX supports quadratic scaling of input vectors, and as such the above equation has to be approximated on an SA380TX using the following quadratic equation:
COMING SOON - THE EQUATION USED BY THE SA380TX
The equations has been formulated to provide a good fit below 150 k Ohm. The error plot is shown below:
COMING SOON - 4-20mA ERROR PLOT
This plot also assumes the RK170 4-20mA output device is correctly calibrated.
The detailed set-up of the 4-20mA is described below
Digtial Volt-Free-Contact Interface
Where a fault repeater exists, up to 12 digital outputs may be provided to indicate which sub-feeder is experiencing the worst insulation resistance. These are wired as per standard digital inputs:
The diagram on the left shows direct connection. Please consult the Bender user guide for exact terminations.
Note that if the isometer is built into a Network Rail style cubicle arrangement, the "common" VFC connection is brought-out at the base of the cubicle through the terminal block position 37. The 12 individual feeder alarm signals are presented on terminal 38 (Feeder 1) through to 49 (Feeder 12). This is shown on the right
Configuration & Comissioning
Setting up the Channels
Rs485
Set the RS485 owner to "Bender"
TOUCHSCREEN - CONFIG TOOL
Create a "Bender" slave unit
TOUCHSCREEN - CONFIG TOOL
This will "Create" slave analogue and digital channels
WEB CONFIG OF CHANNELS
Check that device is active:
MAIN SCREEN
REALTIME DIGITAL
REALTIME ANALOGUE
4-20 mA
Wire the input circuit as a "loop powered" 4-20mA input as shown below
4-20MA CONNECTION
You will need to apply a polynomial mapping to translate the 4-20mA output into a resistance
Please ensure you enter the values below EXACTLY
This curve fit is designed to minimise error below 150 k Ohm
Digital
Simply Rename the Digital Channels to match the feeder same (e.g UP, DOWN, BRANCH etc)
Setting the Acquisition
This requires connection via laptop
The touchscreen interface is not sophisticated enough to set this up
Alarm Levels
Use a simple acquire on Change:
TOUCHSCREEN - CONFIG TOOL
Digital Channels
Simply select push-to-server for all physical and RS485 channels
Live Insualtion Resistance
Standard acquire-on-change will grab incoming data based on on absolute change.
This is not desirable when taking insulation resistance readings, as an absolute change of 10 k Ohm from 1 M Ohm to 990 k Ohm will happen very frequently, due to wet weather for instance, and not warrant any corrective actions, where a change from 55 k Ohm to 45 k Ohm would cross an alert boundary and warrant immediate corrective action.
Setting a small threshold will cause a large amount of not very useful data to be captured, whereas setting a large threshold would cause low data volumes, but reduce sensitivity to genuine fault conditions.
To counter this, the "relative" acquire on change must be set on the logger. To do this requires the use of the "Rail Event" feature of the SA380TX
CREATE NEW RAIL EVENT
SET START TRIGGER
SET ACQUISITION
SET END TRIGGER
Set the config