ABB Remote I/O RIO600 Installation And Commissioning Manual
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ABB Remote I/O RIO600 Installation And Commissioning Manual

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Summary of Contents for ABB Remote I/O RIO600

  • Page 1 — Remote I/O RIO600 Installation and Commissioning Manual...
  • Page 3 Document ID: 1MRS757488 Issued: 2019-12-16 Revision: H Product version: 1.8 © Copyright 2019 ABB. All rights reserved...
  • Page 4 Copyright This document and parts thereof must not be reproduced or copied without written permission from ABB, and the contents thereof must not be imparted to a third party, nor used for any unauthorized purpose. The software or hardware described in this document is furnished under a license and may be used, copied, or disclosed only in accordance with the terms of such license.
  • Page 5 Other than under explicit contractual commitments, in no event shall ABB be responsible or liable for any loss or damage resulting from the use of this manual or the application of the equipment. In case of discrepancies between the English and any other language version, the wording of the English version shall prevail.
  • Page 6 (EMC Directive 2014/30/EU) and concerning electrical equipment for use within specified voltage limits (Low-voltage directive 2014/35/EU). This conformity is the result of tests conducted by ABB in accordance with the product standard EN 60255-26 for the EMC directive, and with the product standards EN 60255-1 and EN 60255-27 for the low voltage directive.
  • Page 7 Safety information Dangerous voltages can occur on the connectors, even though the auxiliary voltage has been disconnected. Non-observance can result in death, personal injury or substantial property damage. Only a competent electrician is allowed to carry out the electrical installation. National and local electrical safety regulations must always be followed.

  • Page 9: Table Of Contents

    Table of contents Table of contents Section 1 Introduction...............7 This manual..................7 Intended audience................7 Product documentation...............7 Product documentation set............7 Document revision history............. 8 Related documentation..............8 Symbols and conventions..............8 Symbols..................8 Document conventions..............9 Section 2 General security deployment guidelines......11 General security................
  • Page 10 Table of contents Connecting binary input signals...........36 Connecting binary output signals..........38 Connecting RTD/mA signals............39 Connecting AOM4 signals............42 Connecting SIM8F sensor signals..........43 Connecting SIM4F sensor signals..........46 Connecting smart control module signals........48 Connecting RIO600 to a PC............. 54 Checking the connection to RIO600..........55 Section 6 Commissioning...............57 Parameter setting................
  • Page 11 Table of contents Functions available in SIM4F..........149 Measurement functions............149 Three-phase current fault detection........149 Earth-fault detection............. 150 Negative-sequence overcurrent indication NSPTOC... 150 Inrush detector INRPHAR............ 150 Fault passage indicator FPIPTOC ........150 Calibration................159 Operating parameter settings of SCM module......159 Functions available in SCM..........159 Three-position earthing switch or two-position earthing switch or two-position disconnector switch or circuit...
  • Page 12 Table of contents Control operations..............176 Control functions................176 Exception codes................ 177 System status register............... 177 Module information..............178 Modbus time synchronization............ 178 Parameter settings..............179 Module reserved channel concept..........181 RTD range information.............. 181 Reporting reserved addresses..........182 Function code and addressing region mapping......183 Modbus point list................184 SSR1 System status register (1) device health......
  • Page 13 Table of contents LD0.VMMXU voltage measurements........223 LD0.PEMMXU power measurements........227 LD0.RESCMMXU residual current measurement..... 230 LD0.RESVMMXU residual voltage measurement..... 231 LD0.CAVMMXU average current measurements .....232 LD0.RCAVMMXU average current measurements....233 LD0.CMAMMXU peak current measurements......234 LD0.VAVMMXU average voltage measurements..... 235 LD0.VMAMMXU peak voltage measurements......

  • Page 15: Section 1 Introduction

    Section 1 1MRS757488 H Introduction Section 1 Introduction This manual The installation and commissioning manual contains information on how to install and commission the device. The manual provides an introduction to engineering tasks and a description of the basic operations. Intended audience This manual addresses application engineers, who install and configure the device.

  • Page 16: Document Revision History

    RIO600 Communication Configuration Manual 1MRS757489 Specific Communication Service Mapping (SCSM) – Mappings to IEC 61850-8-1 MMS (ISO 9506-1 and ISO 9506-2) and to ISO/IEC 8802-3 Download the latest documents from the ABB Web site www.abb.com/mediumvoltage. Symbols and conventions 1.4.1 Symbols The caution icon indicates important information or warning related to the concept discussed in the text.

  • Page 17: Document Conventions

    Section 1 1MRS757488 H Introduction The tip icon indicates advice on, for example, how to design your project or how to use a certain function. Although warning hazards are related to personal injury, it is necessary to understand that under certain operational conditions, operation of damaged equipment may result in degraded process performance leading to personal injury or death.

  • Page 19: Section 2 General Security Deployment Guidelines

    A customer investing in new ABB technologies can rely on system solutions where reliability and security have the highest priority. At ABB, we are addressing cyber security requirements on a system level as well as on a product level to support cyber security standards or recommendations.
  • Page 20 Section 2 1MRS757488 H General security deployment guidelines protection and control relays. Protection and control relays are from the automation system perspective on the lowest level and closest to the actual primary process. It is important to apply defense-in- depth information assurance concept where each layer in the system is capable of protecting the automation system and therefore RIO600s are also part of this concept.

  • Page 21: Section 3 Rio600 Overview

    RIO600 overview Overview ® RIO600 is designed to expand the digital and analog I/O of ABB’s Relion protection and control relays and to provide I/O for the COM600 substation automation unit using the IEC 61850 and Modbus TCP communication. Both galvanic RJ-45 and optical LC connectors are supported for Ethernet station bus communication.
  • Page 22 This module is intended for grid automation applications where RIO600 enables accurate current and voltage measurements or only current measurement from a MV network using ABB's accurate and lightweight sensor technology. With this measurement module, RIO600 can be used as a stand-alone fault passage indicator unit.
  • Page 23 Section 3 1MRS757488 H RIO600 overview underground cables, regardless of the earth-fault type (continuous, transient or intermittent) or the fault resistance value (low or high ohmic). The FPI module incorporates the latest fault-detection algorithms used in the Relion family. With an easy-to-use multifrequency admittance-based (MFA) earth-fault detection algorithm, it accurately detects solid, resistive and intermittent earth faults.

  • Page 24: Product Version History

    Section 3 1MRS757488 H RIO600 overview • IEC 61850 connectivity with support of standard versions Edition 1 and Edition • IEC 61850 GOOSE for real-time information exchange on the Ethernet station • Modbus TCP/IP support for one client • Standard RJ-45 interface with 10/100 Mbits/s or 100 Mbit/s multimode fiber- optic LC Ethernet interface •...

  • Page 25: Module Configuration

    Section 3 1MRS757488 H RIO600 overview Product version Modules supported Product history MOD600ELECMIR New module support added to RIO600 Ver.1.5 MOD600ALECMFO • New version for communication module with MOD600ASCM8H IEC 61850 Edition 2 support and standalone MOD600ASCM8L functionality MOD600ASIM8F • LECMFO communication module with MOD600ARTD4 multimode fiber-optic LC interface...
  • Page 26 Section 3 1MRS757488 H RIO600 overview Module type Description I/O modules Digital input DIM8H High-voltage range, eight optically isolated binary inputs module with common return for two inputs DIM8L Low-voltage range, eight optically isolated binary inputs with common return for two inputs Digital DOM4 Four output contacts in each digital output module with...

  • Page 27: Web Hmi

    Section 3 1MRS757488 H RIO600 overview LECM with copper interface LECM with fiber interface Description Modules Channels Modules Channels Analog output modules SIM8F/SIM4F modules Smart control module (SCM8H/ SCM8L) Table 3: Maximum number of modules and channels available when two power supply modules are connected LECM with copper interface LECM with fiber interface...

  • Page 28: Pcm600 Tool

    Section 3 1MRS757488 H RIO600 overview GUID-1857CDEE-7790-47E7-ABDA-720D2A80DFF6 V6 EN Figure 3: General view of the RIO600 WHMI WHMI provides information about RIO600. • Module hardware version • Module software version • RIO600 modules and their statuses • Latest GOOSE transmitting and receiving information •...

  • Page 29: Pcm600 And Rio600 Connectivity Package Version

    ® RIO600 sends and receives binary and analog signals to or from the ABB Relion series protection relays and the COM600 station automation unit/RTU using the IEC 61850-8-1 GOOSE profile or Modbus TCP. Any RTU supporting these protocols can be used.

  • Page 30: Tcp/Ip-Based Protocols And Used Ip Ports

    Section 3 1MRS757488 H RIO600 overview 3.5.1 TCP/IP-based protocols and used IP ports The RIO600 device supports FTP, HTTP, Modbus TCP and the network time management protocols. Table 4: Supported ports in the RIO600 device Port number Type Default state Description 20, 21 Open...

  • Page 31: Section 4 Unpacking, Inspecting And Storing

    The product requires careful handling before installation on site. • Check the product to see if any damage occurred during transportation. If the product has damaged during transportation, make a claim against the transport contractor and notify the local ABB representative. RIO600 Installation and Commissioning Manual...

  • Page 32: Returning A Product Damaged In Transportation

    Returning a product damaged in transportation If damage has occurred during transportation, appropriate actions must be taken against the latest carrier. Inform the nearest ABB office or representative. ABB should be notified immediately if there are any discrepancies in relation to the delivery documents. Storing If the product is stored before installation, it must be done in the original transport packaging in a dry and dust-free place.

  • Page 33: Section 5 Installing

    Section 5 1MRS757488 H Installing Section 5 Installing Mounting modules RIO600 is designed to be mounted on the standard DIN rail. The modules can be easily stacked and removed. Mount the modules on the DIN rail. • The modules can be stacked in the DIN rail as per configuration and in a predefined order depending on the module type.
  • Page 34 Section 5 1MRS757488 H Installing GUID-A4E84E36-31F1-4FC3-89F9-4CC50E25779D V2 EN Figure 4: Dimension and mounting details of the PSMH/PSMLDIM8H/DIM8L/ RTD4/AOM4/SCM8H/SCM8L modules A 46 mm B 4.5 mm C 51 mm D 81 mm E 146 mm 99 mm RIO600 Installation and Commissioning Manual...
  • Page 35 Section 5 1MRS757488 H Installing GUID-3C54DC2F-92F6-4B6C-A457-2F1F0403D871 V4 EN Figure 5: Dimension and mounting details of the digital output module DOM4 A 27.5 mm B 4.5 mm C 33 mm D 81 mm E 146 mm 99 mm RIO600 Installation and Commissioning Manual...
  • Page 36 Section 5 1MRS757488 H Installing GUID-7770857A-8B26-4B64-95E4-5ADDB579D4C8 V4 EN Figure 6: Dimension and mounting details of the communication module LECM A 27.5 mm B 4.5 mm C 33 mm D 81 mm E 146 mm 81 mm RIO600 Installation and Commissioning Manual...
  • Page 37 Section 5 1MRS757488 H Installing GUID-BDCD600B-B07A-4FBF-90F3-45027360FE62 V3 EN Figure 7: Dimension and mounting details of the SIM8F module A 46 mm B 4.25 mm C 51 mm D 81 mm E 145.5 mm 85 mm RIO600 Installation and Commissioning Manual...
  • Page 38 Section 5 1MRS757488 H Installing Ready Inrush Fault Pass Non Dir OC Neg Seq OC Non Dir EF SIM4F GUID-7421D7B8-A320-4124-9004-226170751AFE V1 EN Figure 8: Dimension and mounting details of the SIM4F module A 46 mm B 4.25 mm C 51 mm D 81 mm E 145.5 mm 85 mm...

  • Page 39: Configuration Examples

    Section 5 1MRS757488 H Installing GUID-57402DEF-96C5-4555-9254-BD644C9D5B40 V2 EN Figure 9: Assembly drawings of the RIO600 modules 1 Rubber cap 2 End clamp 3 PSM module 4 LECM module 5 DIM8H, DIM8L, DOM4, RTD4, AOM4, SIM8F, SIM4F, SCM8H, or SCM8L module 6 DIN rail Disconnect the power supply to the module stack before any configuration update, position change or during the addition or...
  • Page 40 Section 5 1MRS757488 H Installing RIO600 Ready Ready Ready Ready Rx/Tx 10M/100M PSMH LECM DIM8H DOM4 GUID-231E0B53-C035-4236-A203-FE168287C5EB V1 EN Figure 10: RIO600 configuration with 12 channels with 8 DI and 4 DO (1 × DIM8H + 1 × DOM4) RIO600 Ready Ready Ready...

  • Page 41: Connecting Wires

    Section 5 1MRS757488 H Installing RIO600 Ready Ready Ready Ready Ready Ready LF Fwd / Rv Inrush THD / TDD Fault Pass Non Dir OC Non Dir OC OC Fwd / Rv Neg Seq OC Rx/Tx Non Dir EF Non Dir EF 10M/100M EF Fwd / Rv Volt Presence...
  • Page 42 Section 5 1MRS757488 H Installing PSMH GUID-2869AC16-8422-418E-9E6B-714EC1BF8540 V2 EN Figure 15: PSMH terminals Table 6: PSMH screw terminal of power connection Terminal Description Power earth Not connected Line/positive Neutral/negative Not connected Power earth RIO600 Installation and Commissioning Manual...
  • Page 43 Section 5 1MRS757488 H Installing PSML GUID-7A81D05F-B05A-4409-819A-AA2483566560 V3 EN Figure 16: PSML terminals Table 7: PSML screw terminal of power connection Terminal Description Power earth Positive Positive Negative Negative Power earth + terminals of the PSML module are internally shorted. - terminals of the PSML module are internally shorted.

  • Page 44: Connecting Ethernet Cable

    Section 5 1MRS757488 H Installing 5.2.2 Connecting Ethernet cable Check that the proper power supply and LECM modules are mounted on the DIN rail. The LECM module is supplied with two end caps and end clamps which must be mounted at both ends of the RIO600 stack. The communication module works as a RIO600 main module and communicates with different digital I/O modules over backplane for achieving functionality based on the output activation commands received through the communication services.
  • Page 45 Section 5 1MRS757488 H Installing DIM8H module has two sets of connectors. Each set of connectors accept four binary input connections with two isolated pairs of inputs per connection. The voltage range for DIM8H binary input connection is 110...250 V DC (±20%). The threshold is 78 V DIM8L module has two sets of connectors.

  • Page 46: Connecting Binary Output Signals

    Section 5 1MRS757488 H Installing 5.2.4 Connecting binary output signals Check that the proper power supply and LECM modules are mounted on the DIN rail. The DOM4 module has four signaling outputs with a common return for a pair of two outputs.

  • Page 47: Connecting Rtd/Ma Signals

    Section 5 1MRS757488 H Installing Binary output terminal Description Isolated output pair 2 5.2.5 Connecting RTD/mA signals Use a shielded cable for the connection of RTD/mA signals. Connect the shield of the cable to the DIN rail through an earthing clamp, for example, Weidmuller Earthing Clamp: 1252520000 (KLBUE 4-13.5 FM4).
  • Page 48 Section 5 1MRS757488 H Installing RTD4 Resistor sensor RTD1 Resistor sensor RTD2 Resistor sensor RTD3 Resistor sensor RTD4 Earth Clamp (mounted on DIN Rail) GUID-F9DE43D9-89EA-4C64-A58A-3C7D77E9FDA3 V2 EN Figure 20: 3-wire RTD RIO600 Installation and Commissioning Manual...
  • Page 49 Section 5 1MRS757488 H Installing GUID-74279678-A852-4309-8E64-1648505072ED V2 EN Figure 21: mA input connection The recommended connection method is 3-wire RTD as it allows compensation of connection lead (connection wire) resistance and the results are more accurate. Table 11: Screw terminal of RTD/mA connection RTD/mA input Description RTD/mA input...

  • Page 50: Connecting Aom4 Signals

    Section 5 1MRS757488 H Installing RTD/mA input Description RTD/mA input Description terminal terminal compensation compensation Ch4 return Ch2 return path (negative path (negative terminal) terminal) Ch4 positive Ch2 positive terminal terminal 5.2.6 Connecting AOM4 signals Use a shielded cable for the connection of RTD/mA signals. Connect the shield of the cable to the DIN rail through an earthing clamp, for example, Weidmuller Earthing Clamp: 1252520000 (KLBUE 4-13.5 FM4).

  • Page 51: Connecting Sim8F Sensor Signals

    Section 5 1MRS757488 H Installing AOM4 Earth Clamp (mounted on DIN Rail) GUID-8154292B-5CC0-40E1-891F-8B1BFB71B143 V2 EN Figure 22: mA output connection Table 12: Screw terminal of AOM4 connection AOM output Description AOM output Description terminal terminal Ch3 out Ch1 out Ch3 return Ch1 return path (negative path (negative...
  • Page 52 • Connect both current and voltage signals to the sensor input for proper operation. Preferred ABB combined sensor for RIO600 is KEVCY 24 RE1, KEVCY 36 RE1, KEVCY 40.5 RE1 or KEVCD A. Preferred combination of ABB current sensors is KECA 80 C85 and ABB voltage sensor KEVA 24 C10, 24 C21, 24 C22, 24 C23, 17.5 B20, 17.5 B21, 24 B20, or 24...
  • Page 53 Section 5 1MRS757488 H Installing SIM8F PIN 4 PIN 5 IL1/UL1 PIN 4 PIN 5 PIN 7 PIN 8 IL2/UL2 PIN 4 PIN 5 PIN 7 PIN 8 IL3/UL3 PIN 4 PIN 5 PIN 7 PIN 8 GUID-74722F5D-DCF0-4B35-B0DD-FA5D378124A9 V1 EN Figure 24: SIM8F terminals Table 13:...

  • Page 54: Connecting Sim4F Sensor Signals

    Use the cable connector type RJ-45 for connecting the sensors with SIM4F. • Connect current signals to the sensor input for proper operation. Preferred ABB current sensor is KECA 80 C85. RIO600 supports also split-core current sensor type for retro-fit purposes. Preferred split-core sensor is KECA 80 D85.
  • Page 55 Section 5 1MRS757488 H Installing SIM4F PIN 4 PIN 5 PIN 4 PIN 5 PIN 7 PIN 8 PIN 4 PIN 5 PIN 7 PIN 8 PIN 4 PIN 5 PIN 7 PIN 8 GUID-36CA879C-6BF8-477D-B62E-77C2BDF4DF4E V1 EN Figure 26: SIM4F terminals Table 14: SIM4F connection terminal Sensor terminal...

  • Page 56: Connecting Smart Control Module Signals

    Section 5 1MRS757488 H Installing 5.2.9 Connecting smart control module signals Smart control module supports different switchgear application types such as managing two-position or three-position switches or managing circuit breaker trip commands or generic four binary inputs and four fast power outputs. Check that the proper power supply and LECM modules are mounted on the DIN rail.
  • Page 57 Section 5 1MRS757488 H Installing SCM8H / SCM8L COM for DI1 and DI2 DI 1 Earthing switch CLOSE DI 2 Earthing switch OPEN Disconnector CLOSE DI 3 Disconnector OPEN DI 4 COM for DI3 and DI4 GUID-732CEDBB-5677-4C61-9598-ED1BB4A28C01 V2 EN Figure 27: Connection diagram for three-position switch application (rod type with DC motor) Table 15:...
  • Page 58 Section 5 1MRS757488 H Installing SCM8H / SCM8L COM for DI1 and DI2 DI 1 Earthing switch CLOSE DI 2 Earthing switch OPEN DI 3 DI 4 GUID-D8265D66-FEE0-459D-80B4-B90EBA669A29 V2 EN Figure 28: Connection diagram for two-position earthing switch application (rod type with DC motor) Table 16: SCM connection for two-position earthing switch application...
  • Page 59 Section 5 1MRS757488 H Installing SCM8H / SCM8L DI 1 DI 2 Disconnector CLOSE DI 3 Disconnector OPEN DI 4 COM for DI3 and DI4 GUID-B93E3F33-5A6E-42D1-9240-B9E860B0E4F0 V2 EN Figure 29: Connection diagram for two-position disconnector switch application (rod type with DC motor) Table 17: SCM connection for two-position disconnector switch application Connector...
  • Page 60 Section 5 1MRS757488 H Installing SCM8H / SCM8L COM for DI1 and DI2 CB OPEN CB CLOSE CB READY COM for DI3 and DI4 relay compartment circuit breaker compartment close control OPEN COIL CLOSE COIL GUID-B1267BF8-65D3-404B-A22B-35BAC79B7F18 V3 EN Figure 30: Connection diagram for circuit breaker application with trip circuit supervision (direct tripping - double pole) Table 18:...
  • Page 61 Section 5 1MRS757488 H Installing Connector Description Connector Description inputs outputs CB READY CB OPEN Trip status coil Digital input 4 CB CLOSE coil Common AUX. DC return for DI3 voltage L+ and DI4 SCM8H / SCM8L COM for DI1 and DI2 DI 1 DIGITAL INPUT 1 DI 2...

  • Page 62: Connecting Rio600 To A Pc

    Section 5 1MRS757488 H Installing GUID-4890CF9E-29E8-45EC-9381-A5039EC17297 V1 EN Figure 32: 4I4O connection HS3 and HS4 need to be connected as the negative terminal of the voltage source. Table 19: SCM connection for generic four inputs and four high-speed power outputs Connector Description Connector...

  • Page 63: Checking The Connection To Rio600

    Section 5 1MRS757488 H Installing The default IP address of the LECM module is 192.168.2.10. 5.3.1 Checking the connection to RIO600 The connection to RIO600 can be checked either with ICMP Ping messages or by connecting to RIO600 via a Web browser. To check the connection between the PC and RIO600 with ICMP Ping messages, open the Run dialog box.

  • Page 65: Section 6 Commissioning

    Section 6 1MRS757488 H Commissioning Section 6 Commissioning Parameter setting The operating parameters of the LECM, DIM8H, DIM8L,DOM4, RTD4, AOM4, SIM8F and SIM4F modules. 6.1.1 Operating parameter settings LECM Table 20: Operating parameter settings for LECM Parameter name Range Unit Default value Description General Parameters...

  • Page 66: Standalone Configuration

    Section 6 1MRS757488 H Commissioning Parameter name Range Unit Default value Description IP SNTP Secondary 192.168.2.165 IP address for SNTP server 2 If the second SNTP server is not required, configure this field with the value "0.0.0.0" to disable the server. Physical MAC Address Disabled/Enabled Disabled...

  • Page 67: Binary Input Debounce Time (Filter Time)

    Section 6 1MRS757488 H Commissioning Table 21: Operating parameter settings for DIM8H and DIM8L Parameter name Range Unit Default value Description Debounce Time 5...4095 This parameter is the debounce time for the DIM8 module in ms. Oscillation Upper Limit 2...63 Counts This parameter is the oscillation suppression upper limit.

  • Page 68: Binary Input Inversion

    Section 6 1MRS757488 H Commissioning GUID-13DA5833-D263-4E23-B666-CF38B1011A4B V1 EN Figure 35: Binary input filtering Input signal Filtered input signal Filter time At the beginning, the input signal is at the high state, the short low state is filtered and no input state change is detected. The low state starts when the time t exceeds the filter time, which means that the change in the input state is detected and the time tag attached to the input change is t...

  • Page 69: Operating Parameter Settings Dom4

    Section 6 1MRS757488 H Commissioning The binary input is regarded as non-oscillating if the number of valid state changes during configured time period is less than the set oscillation level value minus the set oscillation hysteresis value. The oscillation hysteresis must be set lower than the oscillation level to enable the input to be restored from oscillation.

  • Page 70: Operating Parameter Settings Of Rtd/Ma Module

    Section 6 1MRS757488 H Commissioning Certain parameters, for example, signal type, inversion and disabling, are not applicable to the channel that is configured for the IRF operation. OR logic function should not be used with the contact used for IRF operation. 6.1.4 Operating parameter settings of RTD/mA module Table 24:...

  • Page 71: Selection Of Output Value Format

    Section 6 1MRS757488 H Commissioning Parameter name Range Unit Default value Description Value Unit Degree Celsius, Value unit is based on type of configuration. Dimensionless, mA Value Max Degree Celsius: Upper limit of range -40...+200 Dimensionless: -10000...+10000 mA: 0...20 Value Min Degree Celsius: Lower limit of range -40...+200...

  • Page 72: Linear Input Scaling

    Section 6 1MRS757488 H Commissioning scaling of the input range, the Value unit parameter must be set to “Dimensionless”, where the input range can be scaled linearly with the parameters Input minimum and Input maximum to Value minimum and Value maximum. 6.1.4.2 Linear input scaling Each channel can be scaled linearly when the Input Mode parameter is set to “0…20...

  • Page 73: Calibration

    Section 6 1MRS757488 H Commissioning is set to zero and the quality bit is set to invalid after the supervision filter time has elapsed. Also, the IRF LED on the module flashes a warning and WHMI shows "Ext HW fault". If the mA input cable is damaged or broken, the channel value in GOOSE is set to zero and the quality remains good.

  • Page 74: Deadband Supervision

    Section 6 1MRS757488 H Commissioning GUID-FA37DCA8-623A-4AFE-943F-F9E2968B7080 V1 EN Figure 37: Limit value supervision Table 26: Settings for RTD/mA input limit value supervision Function Settings for limit value supervision RTD/mA input Out of range Value maximum High-high limit Val high-high limit High limit Val high limit Low limit...

  • Page 75: Operating Parameter Settings Of Aom4

    Section 6 1MRS757488 H Commissioning Otherwise, the last reported measurement value is continued to be made available for the application. Deadband formula: [ABS (new value – last reported value) > (% of Deadband value × Measured range)] The measured range is the difference between the parameters Input Max value and Input Min value.

  • Page 76: Calibration

    Section 6 1MRS757488 H Commissioning At power-up, AOM4 channel drives the minimum configured mA value. If setting Value Unit is in mA, settings Value Min and Value Max are not relevant. 6.1.5.1 Calibration The calibration of the mA output channels and read-back channels is done at the factory.

  • Page 77: Operating Parameter Settings Of Sim8F Module

    Section 6 1MRS757488 H Commissioning 6.1.6 Operating parameter settings of SIM8F module Table 28: Operating parameter settings of SIM8F module Parameter name Range Unit Step Default Description Frequency 50 Hz Rated system frequency Nominal current 80…630 Nominal phase current Nominal voltage 500…48000 15000 Nominal phase-...
  • Page 78 Section 6 1MRS757488 H Commissioning Parameter name Range Unit Step Default Description Phase C Current 0.7000…1.3000 0.0001 1.0000 Amplitude Amplitude correction factor for current sensor, phase C Current Phase -3.0000… 0.00025 0.000 Phase correction +3.0000 factor for current sensor, phase C Voltage 0.7000…1.3000 0.0001...

  • Page 79: Functions Available In Sim8F

    Section 6 1MRS757488 H Commissioning Parameter name Range Unit Step Default Description Fault Indication Reset Method Self Reset Definite Time Self Reset Method, Method: Flashing Definite Time, protection Voltage indication LED is Presence, reset DT or Voltage immediately Presence once the fault is cleared.

  • Page 80: Measurement Functions

    Section 6 1MRS757488 H Commissioning Function IEC 61850 IEC 60617 IEC-ANSI Edition 1 Edition 2 Residual voltage measurement RESVMMXU RESVMMXU Three-phase power and energy PEMMXU PEMMXU measurement Three-phase power direction PWRRDIR PWRRDIR Energy monitoring EMMTR EMMTR Current, voltage and power CMSTA CAVMMXU average and peak...
  • Page 81 Section 6 1MRS757488 H Commissioning Function block CMMXU A.phsA cVal.mag.f A.phsA cVal.ang.f A.phsB cVal.mag.f A.phsB cVal.ang.f A.phsC cVal.mag.f A.phsC cVal.ang.f GUID-14189B71-1C14-48B6-8E71-320B3109F8A3 V1 EN Figure 38: Function block Signals Table 30: CMMXU Input signals Name Type Default Description SIGNAL Phase A current SIGNAL Phase B current SIGNAL...
  • Page 82 Section 6 1MRS757488 H Commissioning Function block VMMXU PhV.phsA cVal.mag.f PhV.phsA cVal.ang.f PhV.phsA cVal.mag.f PhV.phsB cVal.ang.f PhV.phsA cVal.mag.f PhV.phsC cVal.ang.f PPV.phsAB cVal.mag.f PPV.phsAB cVal.ang.f PPV.phsBC cVal.mag.f PPV.phsBC cVal.ang.f PPV.phsCA cVal.mag.f PPV.phsCA cVal.ang.f GUID-7D535565-E2C0-4A61-842F-10EEFB537FEA V1 EN Figure 39: Function block Signals Table 33: VMMXU Input signals Name...
  • Page 83 Section 6 1MRS757488 H Commissioning Name Type Description PPV.phsBC cVal.ang.f REAL Voltage phase angle, for Phase B and C PPV.phsCA cVal.mag.f REAL Phase to ground voltage amplitude, for phase C and A PPV.phsCA cVal.ang.f REAL Voltage phase angle, for Phase C and A Table 35: VMMXU Technical data...
  • Page 84 Section 6 1MRS757488 H Commissioning Table 37: RESCMMXU Output signals Name Type Description A.res cVal.mag.f REAL Residual current RMS, magnitude of reported value A.res cVal.ang.f REAL Residual current angle Table 38: RESCMMXU Technical data Characteristic Value Operation accuracy At frequency f = f ±5.0% (when all three phase currents are in the range of 80...630 A) Suppression of harmonics...
  • Page 85 Section 6 1MRS757488 H Commissioning Table 40: RESVMMXU Output signals Name Type Description PhV.res cVal.mag.f REAL Calculated magnitude of residual voltage PhV.res cVal.ang.f REAL Calculated residual voltage angle Table 41: RESVMMXU Technical data Characteristic Value Operation accuracy At frequency f = f ±5.0% (when all three voltages are in the range of 9.6...14.4 kV or 19.2...28.8 kV) Suppression of harmonics...
  • Page 86 Section 6 1MRS757488 H Commissioning → Re S (Equation 1) GUID-04FA4523-A4A3-4092-AFEE-1D1E47FD494F V1 EN → Im S (Equation 2) GUID-C34703B2-A129-4638-A6AA-FEC60635A112 V1 EN → (Equation 3) GUID-6E14F86F-AAB3-4816-9736-30C0D6EF4153 V1 EN The calculated power values are presented in units of kVA/kW/kVAr. cos φ = (Equation 4) GUID-7F06701C-A71D-46D2-9344-87912681BF9D V1 EN Fwd reactive energy...
  • Page 87 Section 6 1MRS757488 H Commissioning Signals Table 43: PEMMXU Input signals Name Type Default Description SIGNAL Phase A current SIGNAL Phase B current SIGNAL Phase C current SIGNAL Phase to earth voltage SIGNAL Phase to earth voltage SIGNAL Phase to earth voltage Table 44: PEMMXU Output signals Name...
  • Page 88 Section 6 1MRS757488 H Commissioning Three-phase power direction PWRRDIR Identification Function description IEC 61850 IEC 60617 ANSI/IEEE C37.2 identification identification device number Three-phase power direction PWRRDIR Function block PWRRDIR P_INST_A Dir General P_INST_B P_INST_C GUID-3618AA01-29F3-479A-A264-8242B8E7CC2C V1 EN Figure 44: Function block Signals Table 46: PWRRDIR Input signals...
  • Page 89 Section 6 1MRS757488 H Commissioning Function block EMMTR P_INST DmdWh SupWh Q_INST DmdVArh Reset Energy counter SupVArh GUID-67B36517-DB15-44C9-A15C-486400E6A9E5 V1 EN Figure 45: Function block Functionality The energy monitoring function EMMTR is used to calculate the active and reactive energy from the respective power inputs P and Q. Operation principle The operation of EMMTR can be described using a module diagram.
  • Page 90 Section 6 1MRS757488 H Commissioning Table 49: EMMTR Output signals Name Type Description DmdWh REAL Accumulated forward active energy value in kWh SupWh REAL Accumulated reverse active energy value in kWh DmdVArh REAL Accumulated forward reactive energy value in kVArh SupVArh REAL Accumulated reverse reactive...
  • Page 91 Section 6 1MRS757488 H Commissioning Function block CMSTA, VMSTA, PEMSTA AvAmpsA MaxAmpsA AvAmpsB MaxAmpsB AvAmpsC MaxAmpsC MaxW BLOCK AvVAr MaxVAr AvVA MaxVA GUID-7128BA48-98A5-4CF2-9774-E5ED6614A387 V1 EN Figure 47: Function block Functionality The current, voltage and power average and peak measurement functions CMSTA, VMSTA and PEMSTA are used to calculate the average and peak value of current, voltage and power.
  • Page 92 Section 6 1MRS757488 H Commissioning Table 52: CMSTA, VMSTA & PEMSTA Output signals Name Type Description AvAmpsA REAL Phase A average current MaxAmpsA REAL Phase A peak current AvVoltsA REAL Phase to earth voltage A - average value MaxVoltsA REAL Phase to earth voltage A - peak value AvAmpsB...

  • Page 93: Power Quality Measurement Functions (Harmonics)

    Section 6 1MRS757488 H Commissioning The measured quantities provided by the function blocks are updated every 500 ms. 6.1.6.3 Power quality measurement functions (harmonics) Current total demand distortion monitoring CMHAI Identification Function description IEC 61850 IEC 60617 ANSI/IEEE C37.2 identification identification device number Current total demand distortion...
  • Page 94 Section 6 1MRS757488 H Commissioning Distortion measurement The distortion measurement module measures harmonics up to the 8 harmonic. The total demand distortion (TDD) is calculated from the measured harmonic components with the formula. ∑ (Equation 5) GUID-FC55400F-5773-492C-88EF-123A07556471 V1 EN Nominal current amplitude The nominal current amplitude is available from the Nominal Current setting under the SIM8F operation parameter.
  • Page 95 Section 6 1MRS757488 H Commissioning CMHAI provides a method for monitoring the power quality by means of the current waveform distortion. Signals Table 54: CMHAI Input signals Name Type Default Description SIGNAL Phase A current SIGNAL Phase B current SIGNAL Phase C current BLOCK Block through settings...
  • Page 96 Section 6 1MRS757488 H Commissioning Function block VMHAI HiAThd BLOCK GUID-DC5C6BCF-D48D-48D5-9B33-7F14CE94F7BC V1 EN Figure 50: Function block Functionality The distortion monitoring function VMHAI is used for monitoring the voltage total harmonic distortion THD. Operation principle The function can be enabled and disabled with the Operation setting. The corresponding parameter values are "On"...

  • Page 97: Three-Phase Current Fault Detection

    Section 6 1MRS757488 H Commissioning Application VMHAI provides a method for monitoring the power quality by means of the voltage waveform distortion. Signals Table 57: VMHAI Input signals Name Type Default Description SIGNAL Phase to earth voltage SIGNAL Phase to earth voltage SIGNAL Phase to earth voltage BLOCK...
  • Page 98 Section 6 1MRS757488 H Commissioning Functionality The three-phase non-directional overcurrent fault detection function PHPTOC is used as one-phase, two-phase or three-phase non-directional overcurrent and short circuit fault detection. The function starts when the current exceeds the set limit. PHPTOC operates with definite time characteristic, that is, the function operates after a predefined operate time and resets immediately when the fault current disappears.
  • Page 99 Section 6 1MRS757488 H Commissioning The OP GENERAL output is available at LED 5 of the SIM8F module. The phase segregated as well as general start and operate outputs STR GENERAL, STR PHSA, STR PHSB, STR PHSC, OP GENERAL, OP PHSA, OP PHSB and OP PHSC are available over communication.
  • Page 100 Section 6 1MRS757488 H Commissioning Three-phase directional overcurrent fault detection DPHPTOC Identification Function description IEC 61850 IEC 60617 ANSI/IEEE C37.2 identification identification device number Three-phase directional overcurrent DPHPTOC 3I>-> fault detection Functionality The three-phase directional overcurrent fault detection function DPHPTOC is used as one-phase, two-phase or three-phase directional overcurrent and short circuit fault detection.
  • Page 101 Section 6 1MRS757488 H Commissioning direction are seen in the non-operating zone. The value of Characteristic angle depends on the network configuration. Reliable operation requires both the operating and polarizing quantities to be above certain minimum amplitude levels. The minimum amplitude level for the operating quantity (current) is fixed to 50 A.
  • Page 102 Section 6 1MRS757488 H Commissioning The phase selection logic also provides the information about the phase specific fault directions. The STR DIRPHSA, STR DIRPHSB and STR DIRPHSC outputs indicates the direction of the fault in phase A, B and C respectively. The general fault direction information is provided by the STR DIRGENERAL output.
  • Page 103 Section 6 1MRS757488 H Commissioning Relay characteristic angle (RCA) is set to positive if the operating current lags the polarizing quantity and negative if the operating current leads the polarizing quantity. RCA = + 60 deg Min forward angle Max reverse angle Reverse Forward...
  • Page 104 Section 6 1MRS757488 H Commissioning Table 64: Phase combined fault direction value Criterion for combined fault direction information Value for fault direction FAULT_DIR The fault direction information for all phases is 0 = unknown unknown The fault direction information for at least one 1 = forward phase is forward, no phase in reverse The fault direction information for at least one...
  • Page 105 Section 6 1MRS757488 H Commissioning 90° GUID-6DA409C2-E9BE-4A53-A5D3-38342B0D2352 V1 EN Figure 55: Single-phase earth-fault of phase A Figure 55 shows phasors in single-phase earth-fault, where the faulted phase is phase A. The angle difference between the polarizing quantity U and operating quantity is marked as ϕ.
  • Page 106 Section 6 1MRS757488 H Commissioning 90° GUID-ECD1B430-99C9-42AC-9B42-2F5A7DCB21BD V1 EN Figure 56: Two-phase short circuit and short circuit between phase B and C Signals Table 66: DPHPTOC Output signals Name Type Description Op general Boolean General operate signal Op phsA Boolean Operate signal for phase A Op phsB Boolean...
  • Page 107 Section 6 1MRS757488 H Commissioning Name Type Description OpRev Boolean Operate signal indicating fault in reverse direction when Directional mode is set to “Non Directional”. Str general Boolean General start signal Str phsA Boolean Start signal for phase A Str phsB Boolean Start signal for phase B Str phsC...

  • Page 108: Earth-Fault Fault Detection

    Section 6 1MRS757488 H Commissioning Name Values (Range) Unit Step Default Description Min Operate Voltage Minimum operating voltage to allow directional criteria Voltage Mem Time Voltage memory time Abs Hyst Oper Qty 0.0…100.0 Absolute hysteresis for operating quantity Abs Hyst Pol Qty 0…2500 Absolute hysteresis for polarizing...
  • Page 109 Section 6 1MRS757488 H Commissioning Timer Op general Level detector Str general GUID-E64EB1AC-DA5B-4340-8250-1958E5A8BB8C V1 EN Figure 57: Functional module diagram Level detector The fundamental component of residual currents is compared with the Start value setting. If the measured value exceeds the Start value setting, the Level detector sends an enable signal to the timer module.
  • Page 110 Section 6 1MRS757488 H Commissioning Settings Table 70: EFPTOC Settings Name Values (Range) Unit Step Default Description Operation Operation Off/On Start Value 4…200 Start value for earth- 200…1000 fault detection Operate Delay Time 40..60000 Operate delay time Absolute Hysteresis 0.0…50.0 Absolute hysteresis for current Table 71:...
  • Page 111 Section 6 1MRS757488 H Commissioning Timer Op general Level detector Str general Directional Str dirGeneral calculation GUID-0D426ECF-B058-45BB-8B5D-CF16C170BEB4 V1 EN Figure 58: Functional module diagram Level detector The magnitude of the operating quantity is compared with the Start value setting and the magnitude of the polarizing quantity is compared with the Voltage start value.
  • Page 112 Section 6 1MRS757488 H Commissioning Table 72: Operation modes Operation mode Description Phase angle The operating sectors for forward and reverse are Min forward angle , Max defined with the settings forward angle , Min reverse angle and Max reverse angle .
  • Page 113 Section 6 1MRS757488 H Commissioning the network where overcurrent fault detection supports the directional overcurrent principle. To determine the direction of fault, directional earth-fault requires a reference, known as polarizing quantity against which residual current can be compared. This polarizing quantity can be either a zero sequence voltage or negative sequence voltage, depending on the network.
  • Page 114 Section 6 1MRS757488 H Commissioning If the "Phase angle" mode is selected, the solidly earthed network (ϕ = +60°) and Characteristic angle = +60°. -Uo (Polarizing quantity) Characteristic angle = +60° Maximum torque line Min forward angle Min operate current Io (Operating quantity) Max reverse angle Max forward angle...
  • Page 115 Section 6 1MRS757488 H Commissioning -Uo (Polarizing quantity) Characteristic angle = -90° Backward Forward operating zone operating zone Max forward angle Min reverse angle Maximum torque line (Operating quantity) Min forward angle Max reverse angle Min operate current Zero torque line GUID-E829A47B-A6C1-46AD-99B8-5F3E9D234B70 V1 EN Figure 61: Definition of the relay characteristic angle, RCA = -90°...
  • Page 116 Section 6 1MRS757488 H Commissioning ΣI ΣI ΣI GUID-10A31995-3BC8-4F02-9384-5AD774869A66 V1 EN Figure 62: Earth-fault in an isolated network Directional earth-fault detection in a compensated network In compensated networks, the capacitive fault current and the inductive resonance coil current compensate each other. The fault detection cannot be based on the reactive current measurement, since the current of the compensation coil would disturb the operation of the relays.
  • Page 117 Section 6 1MRS757488 H Commissioning ΣI ΣI ΣI ΣI GUID-F26BC54D-46C8-4D94-8A49-EC101D51664C V1 EN Figure 63: Earth-fault in a compensated network Directional earth-fault characteristic Phase angle characteristic The operation criterion phase angle is selected with the Operation mode setting using the value "Phase angle". The forward and reverse sectors are defined separately.
  • Page 118 Section 6 1MRS757488 H Commissioning = 0 deg Forward operating zone Min forward angle Max forward angle Non-operating zone Max reverse angle Min reverse angle Backward operating zone Min operate current GUID-2AD845F7-2F52-49A1-94DD-E04FAD186750 V1 EN Figure 64: Configurable operating sectors in phase angle characteristic Table 73: Fault direction indication Fault direction...
  • Page 119 Section 6 1MRS757488 H Commissioning A modern approach to directional fault detection is the active or reactive current measurement. The operating characteristic of the directional operation depends on the earthing principle of the network. The Iosin(ϕ) criterion is used in an isolated network, measuring the reactive component of the fault current caused by the earth capacitance.
  • Page 120 Section 6 1MRS757488 H Commissioning Backward Correction operating zone angle = -90 deg Iosin(j) Min operating current Forward operating zone GUID-A3DF269C-7583-4B1E-A115-6D9A764A607F V1 EN Figure 65: Operating characteristic Iosin(ϕ) in forward fault Example 2 If Iosin(ϕ) criterion is selected in reverse-type fault, the STR DIRGENERAL = 2. RIO600 Installation and Commissioning Manual...
  • Page 121 Section 6 1MRS757488 H Commissioning Correction angle = -90 deg Iosin(j) Min operating current Forward Backward operating zone operating zone GUID-96BE89A7-8DF9-49D2-9048-DB3382B199B3 V1 EN Figure 66: Operating characteristic Iosin(ϕ) in reverse fault Example 3 If Iocos(ϕ) criterion is selected in forward-type fault, the STR DIRGENERAL = 1. RIO600 Installation and Commissioning Manual...
  • Page 122 Section 6 1MRS757488 H Commissioning = 0 deg Forward operating zone Iocos(j) Correction angle non-operating zone Min operating current Backward operating zone GUID-242F9571-55D2-405C-A483-68846ABEA899 V1 EN Figure 67: Operating characteristic Iocos(ϕ) in forward fault Example 4 If Iocos(ϕ) criterion is selected in reverse-type fault, the STR DIRGENERAL = 2. RIO600 Installation and Commissioning Manual...
  • Page 123 Section 6 1MRS757488 H Commissioning = 0 deg Forward operating zone Min operating current non-operating zone Correction angle Backward Iocos(j) operating zone GUID-1DBF7058-725A-4558-AC64-7E4C1EE04187 V1 EN Figure 68: Operating characteristic Iocos(ϕ) in reverse fault Signals Table 74: DEFPTOC Output signals Name Type Description Op general...
  • Page 124 Section 6 1MRS757488 H Commissioning Settings Table 75: DEFPTOC Settings Name Values (Range) Unit Step Default Description Operation Operation Off/On Start Value 4…200 Start value for earth- 200…1000 fault detection Voltage Start Value 500..1000 Voltage start value Operate Delay Time 40…60000 Operate delay time Enable Voltage Limit...
  • Page 125 Section 6 1MRS757488 H Commissioning Table 76: DEFPTOC Technical data Characteristic Value Operation accuracy Depending on the frequency of the current measured: f = f Current: ±10% of the set value in the range of 4...25 A ±1.5% of the set value in the range of 26...1000 A Voltage: ±1.5% of the set value Phase angle: ±3°...
  • Page 126 Section 6 1MRS757488 H Commissioning Operation principle The Operation setting is used to enable or disable the function. The corresponding parameter values are “On” and “Off”. The operation of MFAPSDE can be described using a module diagram. All modules in the diagram are explained in the next sections. MFAPSDE_InEF Transient detector...
  • Page 127 Section 6 1MRS757488 H Commissioning taking into consideration the possible network topology changes, compensation coil and parallel resistor switching status and compensation degree variations. Multi-frequency admittance calculation Multi-frequency admittance calculation module calculates neutral admittances utilizing fundamental frequency and the 2nd, 3rd, 5th, 7th and 9th harmonic components of residual current and zero-sequence voltage.
  • Page 128 Section 6 1MRS757488 H Commissioning   ⋅   = ⋅     −     (Equation 9) GUID-E96136FA-674F-4028-B209-7C9C6CD924A4 V1 EN nth harmonic frequency neutral admittance phasor nth harmonic frequency zero-sequence current phasor nth harmonic frequency zero-sequence voltage phasor nth harmonic frequency susceptance, 2, 3, 5, 7 and 9 For fault direction determination, the fundamental frequency admittance and...
  • Page 129 Section 6 1MRS757488 H Commissioning osum CPS osum osum (Equation 12) GUID-1067FA7D-089C-434E-BC37-51C550F270A5 V1 EN osum CPS osum osum osum (Equation 13) GUID-76F70A50-2558-496C-B22E-E7235F2373A1 V1 EN osum CPS osum osum osum osum (Equation 14) GUID-116F1B28-3898-4607-B3E8-E571497296DB V1 EN t ( ) osum CPS osum osum osum...
  • Page 130 Section 6 1MRS757488 H Commissioning defined with setting Tilt angle to compensate the measurement errors of residual current and voltage measurement. +90 deg Im(Yo) +45 deg  os um_CPS REVERSE FORWARD 0 deg Re(Yo) os um_CPS  REVERSE FORWARD os um_CPS os um_CPS ...
  • Page 131 Section 6 1MRS757488 H Commissioning harmonic components are present in the fault quantities, they turn the phasor align to the negative Im( ) axis. • Phasor 2 depicts the direction of accumulated sum admittance phasor in case of an earth fault inside the protected feeder when the network is unearthed. The result is also valid in compensated networks when there are harmonic components present in the fault quantities (typically low ohmic permanent or intermittent fault).
  • Page 132 Section 6 1MRS757488 H Commissioning ⋅     + ⋅ osta ostab stab stab stab     − (Equation 16) GUID-213A397D-2A9F-493E-A0FC-F7242CF11F8C V1 EN Stabilized fundamental frequency admittance estimate, which is result from fundamental frequency admittance calculation utilizing the Cumulative Phasor Summing (CPS) technique stab Fundamental frequency zero-sequence current phasor calculated utilizing the Cumulative Phasor Summing (CPS) technique...
  • Page 133 Section 6 1MRS757488 H Commissioning Setting Operating Quantity defines whether the current magnitude supervision is based on the "Adaptive", "Amplitude", or "Resistive" methods. When Operating Quantity is set to "Adaptive", the method adapts the principle of current magnitude supervision to the system earthing condition. This is done by monitoring the phase angle of the accumulated sum admittance phasor.
  • Page 134 Section 6 1MRS757488 H Commissioning Setting Operating Quantity should be set to "Adaptive" in resonant earthed systems, except when protected feeders are overcompensated by distributed coils. In such a case, Operating Quantity should be set to "Resistive". Setting Operating Quantity to "Adaptive" enables secure and dependable directional determination in compensated networks, which is also valid when the compensation coil is switched off and the network becomes unearthed.
  • Page 135 Section 6 1MRS757488 H Commissioning +90 deg Im(Ȳo) +45 deg ❷ Ȳ osum_CPS FORWARD REVERSE 0 deg Ȳ Re(Ȳo) osum_CPS ❸ REVERSE FORWARD Ȳ osum_CPS ❹ Ȳ osum_CPS ❶ Tilt angle -90 deg GUID-CAFA60CF-AD7B-4EAB-848A-B565A5CEBF20 V1 EN Figure 73: Illustration of amplitude and resistive current sectors when directional mode is set to "Forward"...
  • Page 136 Section 6 1MRS757488 H Commissioning When Operating Quantity is set to "Amplitude", settings Min Forward Operate Current and Min Reverse Operate Current are compared to the amplitude of stab the whole defined operate sector (see Figure 74). This selection can be used in unearthed networks.
  • Page 137 Section 6 1MRS757488 H Commissioning value, which is lower than the total resistive earth-fault current to enable dependable operation. For example, if the resistive current of the parallel resistor is 10 A (at primary voltage level), then a value of 0.5 ⋅ 10 A = 5 A could be used. If Operating Quantity is set to "Adaptive", the same setting value is also applicable if the coil is disconnected and the network becomes unearthed.
  • Page 138 Section 6 1MRS757488 H Commissioning Peak Detection GFC release Operate Delay Timer Reset Delay Timer MFAPSDE_InEF MFAPSDE_St MFAPSDE_Oper Reset delay time Operate delay time GUID-1631DBC0-4C26-4E47-B1E2-1A930445DA8F V1 EN Figure 75: Example of operation of Transient detector: indication of detected detection of intermittent earth fault by MFAPSDE_InEF output (setting Peak Counter Limit = “3”) Operation logic Operation of MFAPSDE is applicable to all kinds of earth faults in unearthed and...
  • Page 139 Section 6 1MRS757488 H Commissioning and reverse direction Min Reverse Operate Current), which is applied in current magnitude threshold supervision, and which is further defined with setting Operating Quantity. Available options are "Adaptive", "Amplitude" and "Resistive". When the above four conditions are satisfied, the MFAPSDE_St output is activated once Start Delay Time has elapsed.
  • Page 140 Section 6 1MRS757488 H Commissioning Sl.No PCM600 Fault ACT outputs SIM8F WHMI Remarks setting direction panel Start Operate OpFwd OpRev Start Operate Direction eous value since Str and Op latched. Reverse Forward Unknown Reverse Reverse Forward Latched Forward WHMI with (Flashing) since a direction...
  • Page 141 Section 6 1MRS757488 H Commissioning GFC release Operate Delay Timer Reset Delay Timer MFAPSDE_ST MFAPSDE_Oper Reset delay time Operate delay time Start delay time Start delay time GUID-C9DD9B74-E46F-4FFB-A7C7-F022F9648430 V1 EN Figure 76: Operation of function Timer If the detected fault direction is opposite to the set directional mode and GFC release is active, MFAPSDE_ReEF output is activated once Start delay time has elapsed.
  • Page 142 Section 6 1MRS757488 H Commissioning GFC release Reset Delay Timer MFAPSDE_ReEF Reset delay time Reset delay time Start delay time Start delay time GUID-F869A49F-5EB5-42BE-AD50-F42C3F34E99F V1 EN Figure 77: Activation of MFAPSDE_EF output (indication that the fault is located opposite to set operate direction) Signals Table 78: MFAPSDE Output signals...

  • Page 143: Voltage Presence Indication

    Section 6 1MRS757488 H Commissioning Settings Table 79: MFAPSDE Settings Name Values (Range) Unit Step Default Description Operation Operation Off/On Power direction logic Disable Enable Power direction logic Enable Peak Counter Limit 3...20 Peak counter limit for intermittent (restriking) EF detection Operating Quantity Adaptive...
  • Page 144 Section 6 1MRS757488 H Commissioning Functionality The voltage presence indication function PHSVPR supervises the voltage presence status. The function is used for indicating the voltage presence status of a load break switch or a circuit breaker. Operation principle The Operation setting is used to enable or disable the function. The corresponding parameter values are “On”...

  • Page 145: Negative-Sequence Overcurrent Indication Nsptoc

    Section 6 1MRS757488 H Commissioning Signals Table 81: PHSVPR Output signals Name Type Description PHSVPR_ULive Boolean Indicating voltage presence PHSVPR_UDead Boolean Indicating voltage absence Settings Table 82: PHSVPR Settings Name Values (Range) Unit Step Default Description Operation Operation Off/On Alive Phase 1 out of 3 1 out of 3 Number of phases...
  • Page 146 Section 6 1MRS757488 H Commissioning NSPTOC can also be used to detect broken conductors. The operating time characteristic is according to the definite time (DT). Operation principle The Operation setting is used to enable or disable the function. The corresponding parameter values are "On"...

  • Page 147: Fuse Failure Supervision Seqspvc

    Section 6 1MRS757488 H Commissioning Settings Table 86: NSPTOC Settings Name Values (Range) Unit Step Default Description Operation Operation Off/On Start Value 4...1000 Start value Reset Delay Time 0...60000 Reset delay time Operate Delay Time 40…200000 Operate delay time Table 87: NSPTOC Technical data Characteristic Value...
  • Page 148 Section 6 1MRS757488 H Commissioning The operation of SEQSPVC can be described with a module diagram. All modules in the diagram are explained in the next sections. Negative phase sequence criterion Voltage check Decision FUSEF_U logic Current voltage delta criterion FF_CBCLOSED FF_DISCONOPEN GUID-DB3E41D9-8F30-4C44-B944-E12A2889C28C V1 EN...
  • Page 149 Section 6 1MRS757488 H Commissioning circuit breaker is closed. Information about the circuit breaker position is connected to the FF_CBCLOSED input. There are two conditions for activating the current and voltage delta function. • The magnitude of dU/dt exceeds the corresponding value of the Voltage Change Rate setting and the magnitude of dI/dt is below the value of the Current Change Rate setting in any phase at the same time due to the closure of the circuit breaker (FF_CBCLOSED = TRUE).
  • Page 150 Section 6 1MRS757488 H Commissioning Table 88: Fuse failure output control Fuse failure detection criterion Conditions and function response Negative-sequence criterion If a fuse is detected based on the negative- sequence criterion, the FUSEF_U output is activated. The FUSEF_U output signal is also activated if all Seal in Voltage the phase voltages are above the setting for more than 60 seconds and at the same...
  • Page 151 Section 6 1MRS757488 H Commissioning Table 90: SEQSPV Output signals Name Type Description FUSEF_U BOOLEAN General start of function Settings Table 91: SEQSPVC Settings Name Values (Range) Unit Step Default Description Operation Operation Off/On Neg Seq Current 4…1000 Operate level of neg seq undercurrent element Neg Seq Voltage...

  • Page 152: Inrush Detector Inrphar

    Section 6 1MRS757488 H Commissioning 6.1.6.9 Inrush detector INRPHAR Identification IEC 61850 IEC 60617 ANSI/IEEE C37.2 Description identification identification device number Three-phase inrush detector INRPHAR 3I2f> Functionality The three-phase inrush detector function INRPHAR is used to coordinate transformer inrush situations in distribution networks. Transformer inrush detection is based on the following principle: the output signal BLK2H is activated once the numerically derived ratio of second harmonic current I_2H and the fundamental frequency current I_1H exceeds the set value.
  • Page 153 Section 6 1MRS757488 H Commissioning I_2H/I_1H This module calculates the ratio of the second harmonic (I_2H) and fundamental frequency (I_1H) phase currents. The calculated value is compared to the set Start Value. If the calculated value exceeds the set Start Value, the module output is activated.

  • Page 154: Ups Power Failure Monitoring

    Section 6 1MRS757488 H Commissioning Settings Table 95: INRPHAR Settings Name Values (Range) Unit Step Default Description Operation Operation Off/On Start Value 5...100 Start value Reset Delay Time 0...60000 Reset delay time Operate Delay Time 20…60000 Operate delay time Table 96: INRPHAR Technical data Characteristic Value...

  • Page 155: Calibration

    Section 6 1MRS757488 H Commissioning GUID-0D76E7F2-D359-42D6-B774-D1E8D37EF4D6 V1 EN Figure 82: Configuring the UPS power failure input channel 6.1.6.11 Calibration The SIM8F module is factory calibrated. 6.1.7 Operating parameter settings of SIM4F module Table 97: Operating parameter settings of SIM4F module Parameter name Range Unit...
  • Page 156 Section 6 1MRS757488 H Commissioning Parameter name Range Unit Step Default Description Phase A Current 0.7000…1.3000 0.0001 Amplitude Amplitude correction factor for current sensor, phase A Current Phase -3.0000… 0.0003 Phase correction +3.0000 factor for current sensor, phase A Phase B Current 0.7000…1.3000 0.0001...

  • Page 157: Functions Available In Sim4F

    Section 6 1MRS757488 H Commissioning Rated Sensor Current set as 80 A refers to 150 mV at 50 Hz and 180 mV at 60 Hz when 80 A is injected. Similarly, Rated sensor current set as 250 A refers to 150 mV at 50 Hz and 180 mV at 60 Hz when 250 A is injected.

  • Page 158: Earth-Fault Detection

    Section 6 1MRS757488 H Commissioning 6.1.7.4 Earth-fault detection Three-phase non-directional overcurrent fault detection EPTOC Three-phase non-directional overcurrent fault detection EPTOC. 6.1.7.5 Negative-sequence overcurrent indication NSPTOC Negative-sequence overcurrent indication NSPTOC. 6.1.7.6 Inrush detector INRPHAR Inrush detector INRPHAR. 6.1.7.7 Fault passage indicator FPIPTOC Identification IEC 61850 IEC 60617...
  • Page 159 Section 6 1MRS757488 H Commissioning FPIPTOC_Oper General Faulted Fault fault phase passage criterion selection indicator FPIPTOC_Start GUID-8F92E063-8E83-48B1-B2DD-DCF6A21E6395 V1 EN Figure 83: Functional module diagram General fault criterion (GFC) The General fault criterion (GFC) module monitors the presence of earth fault in the network.
  • Page 160 Section 6 1MRS757488 H Commissioning Setting EF Start Cur must be set above the highest threefold negative- sequence current value measured during the healthy state. In order to provide reliable and selective earth-fault detection, the previously described earth-fault detection conditions, Equation 18 Equation 19, must be...
  • Page 161 Section 6 1MRS757488 H Commissioning earth-fault ignition moment. Therefore, setting Revert Time should have sufficient big value, at least 300 ms. Faulted phase selection The Faulted phase selection module provides information about the faulted phase (A, B or C) during a single-phase earth fault. The faulted phase is identified by evaluation of the following equations: ...
  • Page 162 Section 6 1MRS757488 H Commissioning GUID-201C1336-9482-4D26-B04B-6A04CBF73AF3 V1 EN Figure 84: Principle of CPS Cumulative phasor sum is the result of adding the values of the measured current phasors together in phasor format in chronological order during the fault. Using the discrete current phasors in different time instants (t1...t5), the corresponding accumulated current phasor is calculated: ΔI...
  • Page 163 Section 6 1MRS757488 H Commissioning First condition for detection of fault passage is based on evaluation simultaneously the phase angles of three ratios of changes in phase current phasors (fundamental frequency) due to the earth fault:   ∆ FPI_AtoB = ...
  • Page 164 Section 6 1MRS757488 H Commissioning GUID-50908C66-1C3B-4D1F-A7FC-B9429ACC9120 V1 EN Figure 85: Stable phase C-to-earth fault current flowing through the measuring point of FPIPTOC in a compensated network Figure 85, the fault occurs at time 0.2 sec. On the right-hand side, the result of faulted phase selection (Equations 20 - 22) and fault passage indication (phase angles...
  • Page 165 Section 6 1MRS757488 H Commissioning Typical setting for Angle Sector is 15…30 deg. Typical setting for Angle Offset Sector is 45…65 deg. Second condition for detection of fault passage is based on evaluation simultaneously ratio of change due to earth fault in earth-fault current to residual current (fundamental frequency): ...
  • Page 166 Section 6 1MRS757488 H Commissioning Signals Table 99: FPIPTOC Input signals Name Type Default Description SIGNAL Phase A current, IA SIGNAL Phase B current, IB SIGNAL Phase C current, IC Table 100: FPIPTOC Output signals Name Type Description FPIPTOC_Oper BOOLEAN Fault passage indication function is started.

  • Page 167: Calibration

    Section 6 1MRS757488 H Commissioning Table 102: FPIPTOC Technical data Characteristic Value Operation accuracy Depending on the frequency of the current measured: f = f ±1.5% of the set value Start time accuracy ±1.0% of the set value or ±70 ms ±1.0% of the set value or ±30 ms Operate time accuracy 1) f...
  • Page 168 Section 6 1MRS757488 H Commissioning Table 104: Operation parameters for three-position earthing switch, two-position earthing switch, two-position disconnector switch or circuit breaker control application Parameter name Range Unit Default value Description Motor Parameters Motor start time out 0...32000 Maximum time from Starting motor to definitely leave defined Start position...
  • Page 169 Section 6 1MRS757488 H Commissioning Parameter name Range Unit Default value Description Oscillation Time 0...4095 4095 This parameter is the oscillation suppression time limit. The parameter value acts as the time window for the oscillation detection in ms. 0 means that no oscillation suppression is active.
  • Page 170 Section 6 1MRS757488 H Commissioning Table 105: Interlocking rules for motor driven switches Operation Position of switch Command allowed If Earthing switch is between Open earthing switch OPEN and CLOSE positions (intermediate position) and the disconnector is in OPEN position If Disconnector is between Open disconnector OPEN and CLOSE positions...
  • Page 171 Section 6 1MRS757488 H Commissioning GUID-13DA5833-D263-4E23-B666-CF38B1011A4B V1 EN Figure 87: Binary input filtering Input signal Filtered input signal Filter time At the beginning, the input signal is at the high state, the short low state is filtered and no input state change is detected. The low state starts when the time t exceeds the filter time, which means that the change in the input state is detected and the time tag attached to the input change is t...

  • Page 172: Generic Four Inputs And Four High Speed Power Outputs

    Section 6 1MRS757488 H Commissioning oscillation level to enable the input to be restored from oscillation. When the input returns to a non-oscillating state, the binary input is deblocked (the status is valid) and an event is generated. 6.1.8.3 Generic four inputs and four high speed power outputs Smart control module has four inputs with common return for a pair and four power outputs with common return for a pair.

  • Page 173: Trip Circuit Supervision Tcshscbr/Tcslscbr

    Section 6 1MRS757488 H Commissioning Parameter name Range Unit Default value Description Pulse length 10 to 65535 The integer value in this parameter indicates the pulse length for the output channels in ms. Signal type Static/Pulse Static Output signal type: static/ pulse Output Channel 1 Enabled/Disabled...
  • Page 174 Section 6 1MRS757488 H Commissioning Timer TCS status TCSLSCBR_ALR (input 4) GUID-4E6CD401-5CA9-4801-8AFA-90F3EBEC2E9B V1 EN Figure 88: Functional module diagram TCS status This module receives the trip circuit status from binary input 4. A detected failure in trip circuit activates the timer. Timer Once activated, the timer runs until the set value of Operate Delay Time has elapsed.

  • Page 175: Test Mode Handling

    Section 6 1MRS757488 H Commissioning Table 111: TCSHSCBR/TCSLSCBR Technical data Characteristic Value Operate time accuracy ±1.0% of the set value or ±20 ms Test mode handling Use PCM600 to set the device in test mode. In the test mode, RIO600 publishes GOOSE messages with the test bit activated (bit 11 of quality byte, as per IEC 61850‐8‐1) in the quality data attribute of the corresponding data object.

  • Page 176: Local/Remote Mode

    Section 6 1MRS757488 H Commissioning For Analog Output Module (AOM4), in case of failsafe condition, the module continues to drive the old value. In case of power-off condition, the module drives 0 mA current. Local/Remote mode RIO600 can be set to Local/Remote mode using any of the binary input signals, GOOSE signal or through a Modbus command.

  • Page 177: Sntp Time Synchronization

    Section 6 1MRS757488 H Commissioning 6.5.1 SNTP time synchronization RIO600 supports up to two SNTP servers (primary SNTP server and secondary SNTP server) for time synchronization. RIO600 uses only one of the SNTP servers at a time. The primary server is used mainly, whereas the secondary server is used (when configured) if the primary server cannot be reached.

  • Page 178: Goose Performance

    Section 6 1MRS757488 H Commissioning GOOSE performance RIO600 meets the horizontal communication performance criteria for protection purposes defined by IEC61850-5, device-to-device communication under 10 ms. RIO600 also supports sending and receiving analog values using GOOSE messaging. In case of an mA/RTD input, transferring the event via GOOSE requires 250 ms. It takes 50 ms to drive the mA ouput signal in AOM after receiving the GOOSE command.

  • Page 179: Section 7 Modbus Tcp Communication

    Section 7 1MRS757488 H Modbus TCP communication Section 7 Modbus TCP communication Modbus TCP/IP Modbus is a communication protocol developed by Modicon Company in 1970s. It was used originally for communication in PLCs and RTU devices but later the Modbus protocol has been used in a variety of different device applications. The Ethernet based Modbus TCP/IP communication in this IED follows the specifications maintained by Modbus Organization.

  • Page 180: Modbus Tcp/Ip Diagnostic Counters Over Web Hmi

    Section 7 1MRS757488 H Modbus TCP communication 7.1.4 Modbus TCP/IP diagnostic counters over Web HMI Modbus TCP/IP diagnostic counters can be viewed via the WHMI. These counters show the sent and received Modbus protocol link frames and Modbus errors. Table 115: TCP/IP diagnostic counters Counter Description...

  • Page 181: Modbus Data Implementation

    Section 7 1MRS757488 H Modbus TCP communication Table 118: Exception codes supported by RIO600 Function code Name Description Illegal function The slave does not support the requested function. Illegal data address The slave does not support the data address or the number of items in the query if incorrect.

  • Page 182: Data Mapping Principles

    Section 7 1MRS757488 H Modbus TCP communication 7.1.11 Data mapping principles Modbus data is organized sequentially. This is the most efficient organization method since the master normally scans the Modbus data in blocks. 7.1.12 Default data organization The available Modbus data in RIO600 is always mapped to a Modbus location. The Modbus points that are pre-mapped are only cached from the application by the stack when there is a read poll for the corresponding data point.

  • Page 183: Measurand Registers

    Section 7 1MRS757488 H Modbus TCP communication Modbus query for a Binary Data point X Is the mode Instantaneous Latched Latched or Instantaneous? Was there a change in the value of the Binary data point X since the last poll made by the Modbus master for this data point?

  • Page 184: Primary Values

    Section 7 1MRS757488 H Modbus TCP communication 7.1.18 Primary values Measurands originating from sensor measurements can be obtained from RIO600 in only one way. They can be viewed as primary values. The primary values are represented internally as decimal numbers. The primary units are [A] for current and [kV] for voltage.

  • Page 185: Exception Codes

    Section 7 1MRS757488 H Modbus TCP communication structure is used for the control operation. Analog output of RIO600 can be written only by using the write single register function. 7.1.22 Exception codes Only a few exception code alternatives exist for the write coil and write register requests in Modbus.

  • Page 186: Module Information

    Section 7 1MRS757488 H Modbus TCP communication SSR2 The device alive counter SSR2 register is located at 3X/4X address 01. SSR2 counts upwards from 0 to 65535 and starts over. The meaning of this register is to assure that the device is actually operating. 7.1.24 Module information The 3X/4X Modbus address range 16...26 is reserved for providing the module...

  • Page 187: Parameter Settings

    Section 7 1MRS757488 H Modbus TCP communication • If any of the time element has not been updated, the time synch warning is turned on and the time synch status in WHMI indicates “Bad”. • If the value written in a time element is out of the acceptable value range for the corresponding time element, the particular time element’s value is not updated and an exception code 4 is sent to the Modbus client.
  • Page 188 Section 7 1MRS757488 H Modbus TCP communication Parameter name Range Unit Default value Description Binary Output Write Allowed Not allowed Binary output should be allowed to be operated irrespective of the GOOSE communication. Not allowed Analog Output Write Allowed Not allowed Analog output should be allowed to be operated irrespective of the GOOSE communication.

  • Page 189: Module Reserved Channel Concept

    Section 7 1MRS757488 H Modbus TCP communication the binary input readable points, that is points mentioned in the point list, of the SIM8F/SIM4F module and the SCM module of 4I4O application type. • If the binary input read method is set to “Latched”, the RIO600 Modbus slave responds with the first status change value between the polls for a Modbus poll that requests the status of binary input channels of the DIM8 H or DIM8 L module and the binary input readable points of the SIM8F/SIM4F module and the SCM...

  • Page 190: Reporting Reserved Addresses

    Section 7 1MRS757488 H Modbus TCP communication 7.1.29 Reporting reserved addresses Considering RIO600 expansion, the Modbus point list depicts several addresses reserved for future use. In the current implementation, if a 3X/4X read poll is made for a Modbus address which is reserved for future use, the value “0” is reported to the Modbus master.

  • Page 191: Function Code And Addressing Region Mapping

    Section 7 1MRS757488 H Modbus TCP communication Module Data type name Module Unsigned informatio 16 bit informatio Time Unsigned Synchroni 16 bit zation informatio Supervisio Unsigned n Data 16 bit informatio 7.1.30 Function code and addressing region mapping Table 125: Correlation between the function code and address range Module name Data type...

  • Page 192: Modbus Point List

    Section 7 1MRS757488 H Modbus TCP communication Modbus point list Modbus data points and structures available in RIO600 modules are described here. Some of the addresses are reserved and unused, that is, data points always return value “0” when they are read. There are two alternatives for Modbus addressing.

  • Page 193: Ssr2 System Status Register (2) Device Alive Register

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values 0.06 Module 5 Health 0 = Ok, 1 = Warning or error 0.07 Module 6 Health 0 = Ok, 1 = Warning or error 0.08 Module 7 Health...

  • Page 194: Module Identification

    Section 7 1MRS757488 H Modbus TCP communication 7.2.4 Module identification RIO600 modules can be identified with following register addresses. This information can be useful to identify the information about modules connected on the stack. Table 129: Module identification Reg A Type Scale IEC 61850 name...
  • Page 195 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 32.11 <reserved> <reserved> 0=Off 32.12 <reserved> <reserved> 0=Off 32.13 <reserved> <reserved> 0=Off 32.14 <reserved> <reserved> 0=Off 32.15 <reserved> <reserved> 0=Off LD0.DIM8GGIO2/ LD0.DIM8LGGIO2 33.00 .Ind1.stVal DIM8H 2-Input 1 State...
  • Page 196 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 34.15 <reserved> <reserved> 0=Off LD0.DIM8GGIO4/ LD0.DIM8LGGIO4 35.00 .Ind1.stVal DIM8H 4-Input 1 State 0/1=Off/On 35.01 .Ind2.stVal DIM8H 4-Input 2 State 0/1=Off/On 35.02 .Ind3.stVal DIM8H 4-Input 3 State 0/1=Off/On 35.04...
  • Page 197 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 37.03 .Ind4.stVal DIM8H 6-Input 4 State 0/1=Off/On 37.04 .Ind5.stVal DIM8H 6-Input 5 State 0/1=Off/On 37.05 .Ind6.stVal DIM8H 6-Input 6 State 0/1=Off/On 37.06 .Ind7.stVal DIM8H 6-Input 7 State 0/1=Off/On...
  • Page 198 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 39.07 .Ind8.stVal DIM8H 8-Input 8 State 0/1=Off/On 39.08 <reserved> <reserved> 0=Off 39.09 <reserved> <reserved> 0=Off 39.10 <reserved> <reserved> 0=Off 39.11 <reserved> <reserved> 0=Off 39.12 <reserved>...

  • Page 199: Ld0.Domggio Physical I/O States

    Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 41.11 <reserved> <reserved> 0=Off 41.12 <reserved> <reserved> 0=Off 41.13 <reserved> <reserved> 0=Off 41.14 <reserved> <reserved> 0=Off 41.15 <reserved> <reserved> 0=Off 7.2.6 LD0.DOMGGIO physical I/O states The binary output (DOM4) module can be accessed with the addresses listed in Table 131.
  • Page 200 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 49.09 <reserved> <reserved> 0=Off 49.10 <reserved> <reserved> 0=Off 49.11 <reserved> <reserved> 0=Off 49.12 <reserved> <reserved> 0=Off 49.13 <reserved> <reserved> 0=Off 49.14 <reserved> <reserved>...
  • Page 201 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 51.14 <reserved> <reserved> 0=Off 51.15 <reserved> <reserved> 0=Off LD0.DOMGGIO5 52.00 .SPCSO1.stVal DOM 5-Output 1 State 0/1=Off/On 52.01 .SPCSO2.stVal DOM 5-Output 2 State 0/1=Off/On 52.02 .SPCSO3.stVal...
  • Page 202 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 54.02 .SPCSO3.stVal DOM 7-Output 3 State 0/1=Off/On 54.03 .SPCSO4.stVal DOM 7-Output 4 State 0/1=Off/On 54.04 <reserved> <reserved> 0=Off 54.05 <reserved> <reserved> 0=Off 54.06 <reserved>...

  • Page 203: Ld0.Rtdggio Physical I/O Values

    Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 56.07 <reserved> <reserved> 0=Off 56.08 <reserved> <reserved> 0=Off 56.09 <reserved> <reserved> 0=Off 56.10 <reserved> <reserved> 0=Off 56.11 <reserved> <reserved> 0=Off 56.12 <reserved> <reserved>...
  • Page 204 Section 7 1MRS757488 H Modbus TCP communication Table 132: LD0.RTDGGIO physical I/O values Reg A Scale IEC 61850 name SA name Description Values LD0.RTDGGIO1 16 Bit Signed Integer Value reported with a scale .AnIn1.mag.f RTD 1-Channel 1 Input Value -40...200 [°C]/0.0...20.0 factor of "1"...
  • Page 205 Section 7 1MRS757488 H Modbus TCP communication Reg A Scale IEC 61850 name SA name Description Values .AnIn1.range/.An RTD 2- Channel Range Information Normal – 0; In2.range Channel - 2 (High Byte) High – 1; Channel - 1 (Low Byte) Low –...
  • Page 206 Section 7 1MRS757488 H Modbus TCP communication Reg A Scale IEC 61850 name SA name Description Values Value reported with a scale .AnIn1.mag.f RTD 4-Channel 1 Input Value -40...200 [°C]/0.0...20.0 factor of "1" when channel [mA]/-10000...10000 configured as dimensionless .AnIn2.mag.f RTD 4-Channel 2 Input Value -40...200 [°C]/0.0...20.0 and with a scale factor of "100"...
  • Page 207 Section 7 1MRS757488 H Modbus TCP communication Reg A Scale IEC 61850 name SA name Description Values .AnIn3.range/.An RTD 5- Channel Range Information Normal – 0; In4.range Channel - 4 (High Byte) High – 1; Channel - 3 (Low Byte) Low –...
  • Page 208 Section 7 1MRS757488 H Modbus TCP communication Reg A Scale IEC 61850 name SA name Description Values Value reported with a scale .AnIn1.mag.f RTD 7-Channel 1 Input Value -40...200 [°C]/0.0...20.0 factor of "1" when channel [mA]/-10000...10000 configured as dimensionless .AnIn2.mag.f RTD 7-Channel 2 Input Value -40...200 [°C]/0.0...20.0 and with a scale factor of "100"...
  • Page 209 Section 7 1MRS757488 H Modbus TCP communication Reg A Scale IEC 61850 name SA name Description Values .AnIn3.range/.An RTD 8- Channel Range Information Normal – 0; In4.range Channel - 4 (High Byte) High – 1; Channel - 3 (Low Byte) Low –...

  • Page 210: Ld0.Rtdggio Rtd Channel Range Information

    Section 7 1MRS757488 H Modbus TCP communication Reg A Scale IEC 61850 name SA name Description Values Value reported to user with a .AnIn1.mag.f RTD 10-Channel 1 Input Value -40...200 [°C]/0.0...20.0 scale factor of "1" when [mA]/-10000...10000 channel configured as .AnIn2.mag.f RTD 10-Channel 2 Input Value -40...200 [°C]/0.0...20.0...
  • Page 211 Section 7 1MRS757488 H Modbus TCP communication Table 133: LD0.RTDGGIO RTD channel range information Reg A Type Scale IEC61850 name SA name Description Values LD0.RTDGGIO1 RTD-1 .AnIn1.range / .AnIn2.range RTD Channel Range Normal = 0 Information High = 1 Channel - 2 (High Byte) Low = 2 Channel - 1 (Low Byte) High High = 3...
  • Page 212 Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC61850 name SA name Description Values .AnIn1.range / .AnIn2.range RTD Channel Range Normal = 0 Information High = 1 Channel - 2 (High Byte) Low = 2 Channel - 1 (Low Byte) High High = 3 Low Low = 4 .AnIn3.range / .AnIn4.range...

  • Page 213: Ld0.Aomggio Physical I/O Values

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC61850 name SA name Description Values .AnIn1.range / .AnIn2.range RTD Channel Range Normal = 0 Information High = 1 Channel - 2 (High Byte) Low = 2 Channel - 1 (Low Byte) High High = 3 Low Low = 4 .AnIn3.range / .AnIn4.range...
  • Page 214 Section 7 1MRS757488 H Modbus TCP communication Reg A Scale IEC 61850 name SA name Description Values <reserved> <reserved> LD0.AOMGGIO2 Value reported with a scale .AnOut1.mxVal.f AOM 2-Channel 1 Output Value 0.0...20.0 [mA] / factor of "1" when channel -32768...+32768 configured as dimensionless .AnOut2.mxVal.f AOM 2-Channel 2 Output Value...

  • Page 215: Ld0.Phptoc Phase Overcurrent Fault Detection

    Section 7 1MRS757488 H Modbus TCP communication Reg A Scale IEC 61850 name SA name Description Values <reserved> <reserved> LD0.AOMGGIO4 Value reported with a scale .AnOut1.mxVal.f AOM 4-Channel 1 Output Value 0.0...20.0 [mA] / factor of "1" when channel -32768...+32768 configured as dimensionless .AnOut2.mxVal.f AOM 4-Channel 2 Output Value...
  • Page 216 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 386.06 .Str.phsB Phase B Start 1 = Start 386.07 .Str.phsC Phase C Start 1 = Start 386.08 .Op.general Operate General Operate 1 = Operate 386.09 .Op.phsA Phase A Operate...

  • Page 217: Ld0.Dphptoc Three-Phase Directional Overcurrent Fault Detection

    Section 7 1MRS757488 H Modbus TCP communication 7.2.11 LD0.DPHPTOC three-phase directional overcurrent fault detection Table 136: LD0.DPHPTOC three-phase directional overcurrent fault detection Bit A Reg A IEC 61850 name SA name Description Values LD0.DPHPTOC1 SIM8F-1 384.12 .Str.general START General Start 1 = Start 384.13 .Str.phsA...

  • Page 218: Ld0.Cmhai Current Total Demand Distortion

    Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 802.13 .Str.phsA Phase A Start 1 = Start 802.14 .Str.phsB Phase B Start 1 = Start 802.15 .Str.phsC Phase C Start 1 = Start 803.00 .Op.general Operate...

  • Page 219: Ld0.Vmhai Voltage Total Demand Distortion

    Section 7 1MRS757488 H Modbus TCP communication 7.2.13 LD0.VMHAI voltage total demand distortion Table 138: LD0.VMHAI voltage total demand distortion Bit A Reg A IEC 61850 name SA name Description Values LD0.VMHAI1 SIM8F-1 385.05 .HiAThd.stVal Voltage THD 1 = Operate LD0.VMHAI2 SIM8F-2 387.05...

  • Page 220: Ld0.Defptoc Directional Earth-Fault Detection

    Section 7 1MRS757488 H Modbus TCP communication 7.2.15 LD0.DEFPTOC directional earth-fault detection Table 140: LD0.DEFPTOC directional earth-fault detection Bit A Reg A IEC 61850 name SA name Description Values LD0.DEFPTOC1 SIM8F-1 385.08 .Str.general START General Start 1 = Start 385.09 .Op.general Operate General Operate...
  • Page 221 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values Intermittent Earth Fault 806.03 .ItmEFInd.stVal 1 = Fault Indication 806.04 .OpFwd.general Forward Operate 1 = operate 806.05 .OpRev.general Reverse Operate 1 = operate LD0.MFAPSDE 2 SIM8F-2 .Str.general...

  • Page 222: Ld0.Phsvpr Voltage Presence

    Section 7 1MRS757488 H Modbus TCP communication 7.2.17 LD0.PHSVPR voltage presence Table 142: LD0.PHSVPR Voltage Presence Bit A Reg A IEC 61850 name SA name Description Values LD0.PHSVPR1 SIM8F-1 Indication For Voltage 806.08 .VLiv.stVal 1 = Presence Presence Indication For Voltage Not 806.09 .VDea.stVal 1 = Non-Presence...

  • Page 223: Ld0.Fpiptoc Fault Direction Indication

    Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values LD0.NSPTOC4 SIM8F-4/SIM4F-4 .Str.general START General Start 1 = Start 813.01 .Op.general Operate General Operate 1 = Operate LD0.NSPTOC5 SIM8F-5/SIM4F-5 .Str.general START General Start 1 = Start 815.01 .Op.general...

  • Page 224: Ld0.Inrphar Inrush Detector

    Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 813.05 .Str.general START General Start 1 = Start LD0.SEQSPVC5 SIM8F-5 815.05 .Str.general START General Start 1 = Start 7.2.21 LD0.INRPHAR inrush detector Table 146: LD0.INRPHAR inrush detector Bit A...

  • Page 225: Binary Writable Signals For Sim4F

    Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 817.01 Reset Energy Counter 1 = Reset 1 = Update 817.02 Update Statistics statistics SIM8F-5 Reset Fault Indicator 1 = Reset 818.01 Reset Energy Counter 1 = Reset 1 = Update...

  • Page 226: Ld0.Pwrrdir Phase Load Flow Direction

    Section 7 1MRS757488 H Modbus TCP communication 7.2.24 LD0.PWRRDIR phase load flow direction Table 149: LD0.PWRRDIR phase load flow direction Reg A Type Scale IEC 61850 name SA name Description Values LD0.PWRRDIR1 SIM8F-1 0 = unknown 1 = forward .Dir.dirgeneral General Load Flow Direction 2 = reverse 3 = both...

  • Page 227: Ld0.Phptoc Phase Overcurrent Fault Detection

    Section 7 1MRS757488 H Modbus TCP communication 7.2.25 LD0.PHPTOC phase overcurrent fault detection Table 150: LD0.PHPTOC phase overcurrent fault detection Reg A Type Scale IEC 61850 name SA name Description Values LD0.PHPTOC1 SIM8F-1/SIM4F-1 0 = unknown 1 = forward .Str.dirgeneral General Start 2 = reverse 3 = both...

  • Page 228: Ld0.Dphptoc Three-Phase Directional Overcurrent Fault Detection

    Section 7 1MRS757488 H Modbus TCP communication 7.2.26 LD0.DPHPTOC three-phase directional overcurrent fault detection Table 151: LD0.DPHPTOC three-phase directional overcurrent fault detection Reg A Type Scale IEC 61850 name SA name Description Values LD0.DPHPTOC1 SIM8F-1 0 = unknown 1 = forward .Str.dirgeneral General Start 2 = reverse...

  • Page 229: Ld0.Efptoc Non-Directional Earth-Fault Detection

    Section 7 1MRS757488 H Modbus TCP communication 7.2.27 LD0.EFPTOC non-directional earth-fault detection Table 152: LD0.EFPTOC non-directional earth-fault detection Reg A Type Scale IEC 61850 name SA name Description Values LD0.EFPTOC1 SIM8F-1/SIM4F-1 0 = unknown 1 = forward .Str.dirgeneral General Start 2 = reverse 3 = both LD0.EFPTOC2...
  • Page 230 Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .A.phsB.cVal.ang.f Phase B Current Angle .A.phsC.cVal.mag.f Phase C Current Magnitude .A.phsC.cVal.ang.f Phase C Current Angle LD0.CMMXU2 SIM8F-2/SIM4F-2 .A.phsA.cVal.mag.f Phase A Current Magnitude .A.phsA.cVal.ang.f Phase A Current Angle .A.phsB.cVal.mag.f...

  • Page 231: Ld0.Vmmxu Voltage Measurements

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values 1015 1016 .A.phsB.cVal.ang.f Phase B Current Angle 1017 1018 .A.phsC.cVal.mag.f Phase C Current Magnitude 1019 1020 .A.phsC.cVal.ang.f Phase C Current Angle 1021 LD0.CMMXU5 SIM8F-5/SIM4F-5 1142...
  • Page 232 Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .PhV.phsA.cVal.mag.f Phase A Voltage Magnitude .PhV.phsA.cVal.ang.f Phase A Voltage Angle .PhV.phsB.cVal.mag.f Phase B Voltage Magnitude .PhV.phsB.cVal.ang.f Phase B Voltage Angle .PhV.phsC.cVal.mag.f Phase C Voltage Magnitude .PhV.phsC.cVal.ang.f Phase C Voltage Angle LD0.VMMXU2...
  • Page 233 Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .PPV.phsAB.cVal.mag.f Magnitude .PPV.phsAB.cVal.ang.f Angle .PPV.phsBC.cVal.mag.f Magnitude .PPV.phsBC.cVal.ang.f Angle .PPV.phsCA.cVal.mag.f Magnitude .PPV.phsCA.cVal.ang.f Angle .PhV.phsA.cVal.mag.f Phase A Voltage Magnitude .PhV.phsA.cVal.ang.f Phase A Voltage Angle .PhV.phsB.cVal.mag.f Phase B Voltage Magnitude .PhV.phsB.cVal.ang.f...
  • Page 234 Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values 1036 .PhV.phsA.cVal.ang.f Phase A Voltage Angle 1037 1038 .PhV.phsB.cVal.mag.f Phase B Voltage Magnitude 1039 1040 .PhV.phsB.cVal.ang.f Phase B Voltage Angle 1041 1042 .PhV.phsC.cVal.mag.f Phase C Voltage Magnitude 1043...

  • Page 235: Ld0.Pemmxu Power Measurements

    Section 7 1MRS757488 H Modbus TCP communication 7.2.31 LD0.PEMMXU power measurements Table 156: LD0.PEMMXU power measurements RegA Type Scale IEC 61850 name SA name Description Values LD0.PEMMXU1 SIM8F-1 .W.phsA.cVal.mag.f Phase A Active Power .W.phsB.cVal.mag.f Phase B Active Power .W.phsC.cVal.mag.f Phase C Active Power .TotW.mag.f Total Active Power .VAr.phsA.cVal.mag.f...
  • Page 236 Section 7 1MRS757488 H Modbus TCP communication RegA Type Scale IEC 61850 name SA name Description Values .TotW.mag.f Total Active Power .VAr.phsA.cVal.mag.f Phase A Reactive Power .VAr.phsB.cVal.mag.f Phase B Reactive Power .VAr.phsC.cVal.mag.f Phase C Reactive Power .TotVAr.mag.f Total Reactive Power .VA.phsA.cVal.mag.f Phase A Apparent Power .VA.phsB.cVal.mag.f...
  • Page 237 Section 7 1MRS757488 H Modbus TCP communication RegA Type Scale IEC 61850 name SA name Description Values .VA.phsA.cVal.mag.f Phase A Apparent Power .VA.phsB.cVal.mag.f Phase B Apparent Power .VA.phsC.cVal.mag.f Phase C Apparent Power .TotVA.mag.f Total Apparent Power .Hz.mag.f Frequency 1000 .TotPF.mag.f Average Power Factor LD0.PEMMXU4 SIM8F-4...

  • Page 238: Ld0.Rescmmxu Residual Current Measurement

    Section 7 1MRS757488 H Modbus TCP communication RegA Type Scale IEC 61850 name SA name Description Values 1072 1000 .TotPF.mag.f Average Power Factor 1073 LD0.PEMMXU5 SIM8F-5 1178 .W.phsA.cVal.mag.f Phase A Active Power 1179 1180 .W.phsB.cVal.mag.f Phase B Active Power 1181 1182 .W.phsC.cVal.mag.f Phase C Active Power...

  • Page 239: Ld0.Resvmmxu Residual Voltage Measurement

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .A.res.cVal.ang.f Residual Current Angle LD0.RESCMMXU2 SIM8F-2/SIM4F-2 .A.res.cVal.mag.f Residual Current Magnitude .A.res.cVal.ang.f Residual Current Angle LD0.RESCMMXU3 SIM8F-3/SIM4F-3 .A.res.cVal.mag.f Residual Current Magnitude .A.res.cVal.ang.f Residual Current Angle LD0.RESCMMXU4 SIM8F-4/SIM4F-4 1074...

  • Page 240: Ld0.Cavmmxu Average Current Measurements

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .PhV.res.cVal.mag.f Residual Voltage Magnitude .PhV.res.cVal.ang.f Residual Voltage Angle LD0.RESVMMXU4 SIM8F-4 1078 .PhV.res.cVal.mag.f Residual Voltage Magnitude 1079 1080 .PhV.res.cVal.ang.f Residual Voltage Angle 1081 LD0.RESVMMXU5 SIM8F-5 1210...

  • Page 241: Ld0.Rcavmmxu Average Current Measurements

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .A.phA.cVal.mag.f Phase A Average Operating Current .A.phB.cVal.mag.f Phase B Average Operating Current .A.phC.cVal.mag.f Phase C Average Operating Current LD0.CAVMMXU4 SIM8F-4/SIM4F-4 1082 .A.phA.cVal.mag.f Phase A Average Operating Current 1083...

  • Page 242: Ld0.Cmammxu Peak Current Measurements

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .A.res.cVal.mag.f Residual Average Operating Current LD0. RCAVMMXU4 SIM8F-4/SIM4F-4 1088 .A.res.cVal.mag.f Residual Average Operating Current 1089 LD0. RCAVMMXU5 SIM8F-5/SIM4F-5 1220 .A.res.cVal.mag.f Residual Average Operating Current 7.2.36 LD0.CMAMMXU peak current measurements...

  • Page 243: Ld0.Vavmmxu Average Voltage Measurements

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values 1092 .A.phB.cVal.mag.f Phase B Peak Current 1093 1094 .A.phC.cVal.mag.f Phase C Peak Current 1095 LD0.CMAMMXU5 SIM8F-5/SIM4F-5 1222 .A.phA.cVal.mag.f Phase A Peak Current 1223 1224 .A.phB.cVal.mag.f...

  • Page 244: Ld0.Vmammxu Peak Voltage Measurements

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .PhsV.phsB.cVal.mag.f Phase B Average Operating Voltage .PhsV.phsC.cVal.mag.f Phase C Average Operating Voltage LD0.VAVMMXU4 SIM8F-4 1096 .PhsV.phsA.cVal.mag.f Phase A Average Operating Voltage 1097 1098 .PhsV.phsB.cVal.mag.f Phase B Average Operating...

  • Page 245: Ld0.Peavmmxu Average Power Measurements

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .PhsV.phsB.cVal.mag.f Phase B Peak Voltage .PhsV.phsC.cVal.mag.f Phase C Peak Voltage LD0.VMAMMXU3 SIM8F-3 .PhsV.phsA.cVal.mag.f Phase A Peak Voltage .PhsV.phsB.cVal.mag.f Phase B Peak Voltage .PhsV.phsC.cVal.mag.f Phase C Peak Voltage LD0.VMAMMXU4...

  • Page 246: Ld0.Pemammxu Peak Power Measurements

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .TotW.mag.f Average Active Power .TotVAr.mag.f Average Reactive Power .TotVA.mag.f Average Apparent Power LD0.PEAVMMXU3 SIM8F-3 .TotW.mag.f Average Active Power .TotVAr.mag.f Average Reactive Power .TotVA.mag.f Average Apparent Power LD0.PEAVMMXU4...

  • Page 247: Ld0.Emmtr Energy Measurement

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values LD0.PEMAMMXU2 SIM8F-2 .TotW.mag.f Peak Active Power .TotVAr.mag.f Peak Reactive Power .TotVA.mag.f Peak Apparent Power LD0.PEMAMMXU3 SIM8F-3 .TotW.mag.f Peak Active Power .TotVAr.mag.f Peak Reactive Power .TotVA.mag.f Peak Apparent Power LD0.PEMAMMXU4...
  • Page 248 Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values .DmdVArh.actVal Reactive Energy Demand .SupVArh.actVal Reactive Energy Supply LD0.EMMTR2 SIM8F-2 .DmdWh.actVal Real Energy Demand .SupWh.actVal Real Energy Supply .DmdVArh.actVal Reactive Energy Demand .SupVArh.actVal Reactive Energy Supply LD0.EMMTR3...

  • Page 249: Ld0.Mfapsde Multifrequency Admittance Protection (Earth-Fault Indication)

    Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values 1256 .DmdVArh.actVal Reactive Energy Demand 1257 1258 .SupVArh.actVal Reactive Energy Supply 1259 7.2.42 LD0.MFAPSDE multifrequency admittance protection (earth-fault indication) Table 167: LD0.MFAPSDE multifrequency admittance protection Reg A Type Scale...

  • Page 250: Binary Readable Signals Of Scm

    Section 7 1MRS757488 H Modbus TCP communication Table 169: SCM application types Reg A Type IEC 61850 name SA name Description Values 1500 Application Type (Application type – Value) 1501 Application Type 4I4O – 128; Three position 1502 Application Type switch –...
  • Page 251 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 1675 1516.11 .Ind13.stVal Error Code: No Act 0/1 = Off/On 1676 1516.12 .Ind14.stVal Error Code: Interlocking Error 0/1 = Off/On 1677 1516.13 .Ind15.stVal Error Code: REED/ Release 0/1 = Off/On...
  • Page 252 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values SCM-3 1. LD0.SCMLGGIO3/ LD0.SCMHGGIO3 2. LD0.SCMLPGGIO3/ LD0.SCMHPGGIO3 3. LD0.SCMLDGGIO3/ LD0.SCMHDGGIO3 4. LD0.SCMLEGGIO3/ LD0.SCMHEGGIO3 5. LD0.SCMLCGGIO3/ LD0.SCMHCGGIO3 6. LD0.TCSLSCBR3/ LD0.TCSHSCBR3 1728 1520 .Ind1.stVal Digital Input Channel 1 0/1 = Off/On 1729...
  • Page 253 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 1760 1522 .Ind1.stVal Digital Input Channel 1 0/1 = Off/On 1761 1522.01 .Ind2.stVal Digital Input Channel 2 0/1 = Off/On 1762 1522.02 .Ind3.stVal Digital Input Channel 3 0/1 = Off/On...
  • Page 254 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 1799 1524.07 RELEASE_CB Release Circuit Breaker 0/1 = Off/On Information 1800 1524.08 .Ind10.stVal Error Code: No Fault 0/1 = Off/On 1801 1524.09 .Ind11.stVal Error Code: Device Error 0/1 = Off/On...
  • Page 255 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 1838 1526.14 .Ind16.stVal Error Code: Position Error 0/1 = Off/On 1839 1526.15 .Ind17.stVal Error Code: Time-out Error 0/1 = Off/On 1840 1527 .CircAlm.stVal Trip Circuit Supervision Alarm 0/1 = Off/On...
  • Page 256 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values SCM-8 1. LD0.SCMLGGIO8/ LD0.SCMHGGIO8 2. LD0.SCMLPGGIO8/ LD0.SCMHPGGIO8 3. LD0.SCMLDGGIO8/ LD0.SCMHDGGIO8 4. LD0.SCMLEGGIO8/ LD0.SCMHEGGIO8 5. LD0.SCMLCGGIO8/ LD0.SCMHCGGIO8 6. LD0.TCSLSCBR8/ LD0.TCSHSCBR8 1888 1530 .Ind1.stVal Digital Input Channel 1 0/1 = Off/On 1889...
  • Page 257 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 1920 1532 .Ind1.stVal Digital Input Channel 1 0/1 = Off/On 1921 1532.01 .Ind2.stVal Digital Input Channel 2 0/1 = Off/On 1922 1532.02 .Ind3.stVal Digital Input Channel 3 0/1 = Off/On...
  • Page 258 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 1959 1534.07 RELEASE_CB Release Circuit Breaker 0/1 = Off/On Information 1960 1534.08 .Ind10.stVal Error Code: No Fault 0/1 = Off/On 1961 1534.09 .Ind11.stVal Error Code: Device Error 0/1 = Off/On...

  • Page 259: Binary Writable Signals For Scm

    Section 7 1MRS757488 H Modbus TCP communication - .Ind12.stVal - .Ind13.stVal - .Ind14.stVal - .Ind15.stVal - .Ind16.stVal - .Ind17.stVal LD0.SCMLCGGIO/LD0.SCMHCGGIO - .Ind1.stVal - .Ind2.stVal - .Ind3.stVal - .Ind4.stVal - RELEASE_CB - .Ind10.stVal - .Ind11.stVal - .Ind12.stVal - .Ind13.stVal - .Ind14.stVal - .Ind15.stVal - .Ind16.stVal - .Ind17.stVal...
  • Page 260 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 2510 1568.14 <reserved> <reserved> 2511 1568.15 OPEN_CB Circuit Breaker Open 0/1 = Off/On Command 2512 1569.00 CLOSE_CB Circuit breaker Close 0/1 = Off/On Command 2513 1569.01...
  • Page 261 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 2561 1572.01 .SPCSO2.stVal Digital Output Channel 2 0/1 = Off/On 2562 1572.02 .SPCSO3.stVal Digital Output Channel 3 0/1 = Off/On 2563 1572.03 .SPCSO4.stVal Digital Output Channel 4 0/1 = Off/On...
  • Page 262 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 2606 1574.14 <reserved> <reserved> 2607 1574.15 OPEN_CB Circuit Breaker Open 0/1 = Off/On Command 2608 1575.00 CLOSE_CB Circuit breaker Close 0/1 = Off/On Command 2609 1575.01...
  • Page 263 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 2657 1578.01 .SPCSO2.stVal Digital Output Channel 2 0/1 = Off/On 2658 1578.02 .SPCSO3.stVal Digital Output Channel 3 0/1 = Off/On 2659 1578.03 .SPCSO4.stVal Digital Output Channel 4 0/1 = Off/On...
  • Page 264 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 2702 1580.14 <reserved> <reserved> 2703 1580.15 OPEN_CB Circuit Breaker Open 0/1 = Off/On Command 2704 1581.00 CLOSE_CB Circuit breaker Close 0/1 = Off/On Command 2705 1581.01...
  • Page 265 Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 2753 1584.01 .SPCSO2.stVal Digital Output Channel 2 0/1 = Off/On 2754 1584.02 .SPCSO3.stVal Digital Output Channel 3 0/1 = Off/On 2755 1584.03 .SPCSO4.stVal Digital Output Channel 4 0/1 = Off/On...

  • Page 266: Supervision Data

    Section 7 1MRS757488 H Modbus TCP communication Bit A Reg A IEC 61850 name SA name Description Values 2798 1586.14 <reserved> <reserved> 2799 1586.15 OPEN_CB Circuit Breaker Open 0/1 = Off/On Command 2800 1587.00 CLOSE_CB Circuit breaker Close 0/1 = Off/On Command 2801 1587.01...
  • Page 267 Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values 2282 Unsigne LECM - Firmware Version 0...65535 d 16 Major (High byte) Minor (Low byte) 2283 Unsigne LECM - Firmware Version 0...65535 d 16 Patch (Low byte) 2284...
  • Page 268 Section 7 1MRS757488 H Modbus TCP communication Reg A Type Scale IEC 61850 name SA name Description Values 2304 Unsigne Module 5 - Reserved For d 16 Future Use 2305 Unsigne Module 5 - Reserved For d 16 Future Use 2306 Unsigne Module 6 - Firmware Version...

  • Page 269: Section 8 Using The Web Hmi

    Section 8 1MRS757488 H Using the Web HMI Section 8 Using the Web HMI Accessing the Web HMI • Type the IP address of RIO600 in the address bar of the Web browser and press ENTER. • Ensure that both the computer and RIO600 are configured for the same subnet. Navigating in the menu •...

  • Page 270: Selecting The Status View

    Section 8 1MRS757488 H Using the Web HMI GUID-4EF332D9-C570-4C71-B378-D2456AD63233 V4 EN Figure 90: Fault view Selecting the status view The status view shows GOOSE, Modbus, time synchronization and I/O statuses. • Click Status in the menu bar. GUID-080B805A-0F4D-4124-A6B0-6E5A4E8B386B V5 EN Figure 91: Status page of RIO600 WHMI •...
  • Page 271 Section 8 1MRS757488 H Using the Web HMI • If no GOOSE messages are received or accepted (if the MAC acceptance filter is enabled) or the GOOSE engineering has not been done, the GOOSE Tx/Rx status is "-". • If there is an error in the received GOOSE frame, the error information is displayed in the error column of the GOOSE Receive Status table.
  • Page 272 Section 8 1MRS757488 H Using the Web HMI GUID-930B527E-ACFB-4880-9A75-41BE83205A25 V3 EN Figure 93: GOOSE Transmit Status • Click the Click Here For Details link under Modbus status header for the detailed Modbus status. GUID-7B00E7C8-7F11-478B-BA29-741F840A0758 V1 EN Figure 94: Modbus status •...
  • Page 273 Section 8 1MRS757488 H Using the Web HMI • If the time sync source is disabled or not configured, the status is "-". • If the time sync source is configured as SNTP and if the server is accessible to RIO600, the time sync status is "Good". Otherwise the status is "Bad". •...

  • Page 274: Selecting The Configuration View

    Section 8 1MRS757488 H Using the Web HMI GUID-0E7FE30F-F66E-434A-8022-1DF9D0A380D1 V1 EN Figure 96: SIM4F status Pulse output statuses are not updated on the WHMI. Selecting the configuration view The configuration view shows the settings of all modules. • Click Configuration in the menu bar. GUID-397B905F-682E-4BDE-A717-7DEC5710CB34 V3 EN Figure 97: Module configuration...
  • Page 275 Section 8 1MRS757488 H Using the Web HMI • Click Click Here For Details for detailed configuration of each module. The LECM Configuration section shows the General Configuration and Modbus Configuration details. GUID-E6EEF668-E929-4CBA-9F92-00E0CE360E37 V2 EN Figure 98: LECM configuration • The DIM Configuration status section shows the settings for each channel of DIM8H_L module present in RIO600.
  • Page 276 Section 8 1MRS757488 H Using the Web HMI GUID-32C2895C-BCBC-40CF-882F-B9424DD4B904 V2 EN Figure 100: DOM configuration • The RTD Configuration setting section shows the settings for each RTD4 module present in RIO600. The row that belongs to the module number gives the configuration details of all individual channels for that particular module.
  • Page 277 Section 8 1MRS757488 H Using the Web HMI GUID-B0901270-2F08-49A3-81B3-35EA8EC9A46E V2 EN Figure 102: AOM configuration • The SIM8F Configuration setting section shows the SIM8F configuration for the selected SIM8F module. It gives configuration details (in read-only mode) of the SIM8F module as configured by Parameter Setting of RIO600 Connectivity Package.

  • Page 278: Selecting The Communication View

    Section 8 1MRS757488 H Using the Web HMI GUID-D39F297B-4DE4-477F-95AB-1CCC962FA4F5 V1 EN Figure 104: SIM4F configuration Selecting the communication view The communication parameter settings are presented in the communication view. • Click Communication in the menu bar. • If the SNTP server is disabled, the SNTP server address is "-". •...
  • Page 279 Section 8 1MRS757488 H Using the Web HMI GUID-2EBB410F-2AD5-4BFE-BFDE-E0C42F090730 V4 EN Figure 105: Communication view RIO600 Installation and Commissioning Manual...

  • Page 281: Section 9 Troubleshooting

    Section 9 1MRS757488 H Troubleshooting Section 9 Troubleshooting Checking LED indications LED indicators describe the state of the RIO600 modules. Each module has indication LEDs showing the state of module functionality. Generally, each module is able to show whether it is functioning properly. Communication and binary I/O states are shown with separate LEDs.
  • Page 282 Section 9 1MRS757488 H Troubleshooting Table 175: LED indicators (I/O modules) Color State Description Ready Green Module is ready Ready Green Flashing Module is powered on, configuration is pending Module is healthy Module is in error condition DI1 to DI8 Yellow Binary I/O signal DO1 to DO4...
  • Page 283 Section 9 1MRS757488 H Troubleshooting Color State Description OC Fwd/Rv Green/Red Directional overcurrent fault detection condition is not detected OC Fwd/Rv Green/Red Directional overcurrent fault detection condition is detected. LED color indication is as per configuration and fault detection direction. Non Dir EF Non-directional earth- fault detection...
  • Page 284 Section 9 1MRS757488 H Troubleshooting Color State Description Non Dir Oc Green Non-directional overcurrent fault detection condition is not detected Non Dir Oc Green Non-directional overcurrent fault detection condition is detected Neg Seq Oc Green Negative-sequence overcurrent fault condition is not detected Neg Seq Oc Green...

  • Page 285: Behavior During Irf Condition

    Section 9 1MRS757488 H Troubleshooting Color State Description Module is in error condition DI1 to DI4 Yellow Binary I/O signal HS1 to HS4 activated DI1 to DI4 Yellow Binary I/O signal not HS1 to HS4 activated 9.1.1 Behavior during IRF condition Table 179: Behavior during IRF in LECM module Module IRF...
  • Page 286 Section 9 1MRS757488 H Troubleshooting Table 180: Behavior during IRF in DIM8L/DIM8H module Module IRF Behavior in an IRF condition RIO600 as a whole LECM DIM8L/DIM8H DOM4, AOM4, RTD4 IRF in DIM8L/DIM8H Continues normal Shows IRF by Normal functionality is Continues normal module function with corrective...
  • Page 287 Section 9 1MRS757488 H Troubleshooting Table 182: Behavior during IRF in RTD4 module Module IRF Behavior in an IRF condition RIO600 as a whole LECM RTD4 DIM8L/DIM8H, DOM4, AOM4 IRF in RTD4 module Continues normal Show IRF to user Normal functionality is Continues normal function with corrective by steady IRF LED...

  • Page 288: Restoring Communication

    Section 9 1MRS757488 H Troubleshooting Table 184: Behavior during IRF in SIM8F module Module IRF Behavior in an IRF condition RIO600 as a whole LECM DIM8L/DIM8H, DOM4, RTD4, AOM4 IRF in SIM8F module Continues normal function with Shows IRF by steady IRF Continues normal corrective action LED on LECM module...

  • Page 289: Restoring Factory Settings

    Section 9 1MRS757488 H Troubleshooting Windows XP SP2 or later contains a built-in firewall. Table 186: TCP/IP and UDP ports Protocol TCP/UDP port FTP file transfer protocol 21, 20 Network time management protocol HTTP Modbus TCP The FTP timeout period in RIO600 is 100 ms. Check the network if the communication issue persists.

  • Page 290: Ping Command Response

    Section 9 1MRS757488 H Troubleshooting GUID-02F47E78-F8FD-4D5D-AC89-EF44514A002B V1 EN Figure 106: Accessing the reset push button Press the push button and while keeping the button pressed, power up RIO600. Keep the push button pressed for 30 seconds after RIO600 is powered up. The IRF LED (red) appears static (continuous ON).

  • Page 291: Troubleshooting Inactive I/O Modules

    Section 9 1MRS757488 H Troubleshooting GUID-E6C87A82-7392-4EBE-94F8-E5166AF05966 V1 EN Figure 107: Response to the ping command When there is network traffic on the TCP/IP layer, the ping command response time varies and may cross the specified limits as the priority is in the I/O and GOOSE functionality.

  • Page 292: Sim8F/Sim4F Measurement Quality

    Section 9 1MRS757488 H Troubleshooting SIM8F/SIM4F measurement quality The quality of the measured or derived electrical quantities provided by SIM8F/ SIM4F can be bad due to one of the following reasons. • Connection between SIM8F/SIM4F and the measurement sensor is incorrect •...

  • Page 293: Section 10 Technical Data

    Section 10 1MRS757488 H Technical data Section 10 Technical data Table 187: Interfaces Description Value LECM Ethernet interface RJ-45 (STP CAT5e) galvanic connector Multimode LC fiber-optic connector Power Supply Module (PSMH/PSML/DIM8H/ Suggested part: Weidmuller P/N 1844260000 DIM8L/DOM4/SCM8H/SCM8L) front mating connector Sensor input module SIM8F/SIM4F Table 188: Module weights...
  • Page 294 Section 10 1MRS757488 H Technical data Description PSMH PSML Maximum interruption time in 100 ms at U nominal 50 ms at U nominal the auxiliary DC without resetting the RIO600 modules Ripple in the DC auxiliary Max. 15% of the DC value (at frequency of 100 Hz) voltage Reversal of DC power supply 1 minute for each polarity...
  • Page 295 Section 10 1MRS757488 H Technical data Description Value Make and carry for 3.0 s 10 A Make and carry for 0.5 s 15 A Breaking capacity when the control circuit time 1 A/0.25 A/0.15 A constant L/R <40 ms, at 48/110/220 V DC Table 193: mA/RTD input (RTD4 module) Description...
  • Page 296 1MRS757488 H Technical data Table 195: Sensor input module (SIM8F) Description Value Preferred ABB sensors • Combined sensors KEVCY 24 RE1, KEVCY36 RE1, KEVCY 40.5 RE1, KEVCD • Combination of current sensor KECA 80 C85 or KECA D85 and voltage sensor KEVA 24 C10, 24 C21, 24 C22, 24 C23, 17.5 B20,...
  • Page 297 Section 10 1MRS757488 H Technical data Description Value Non-directional earth- Operating range 4...200 A (isolated/compensated network) fault detection 200...1000 A (solidly grounded/low-impedance network) Accuracy Depending on the nominal frequency of the current measured: f ±10% of the set value in the range of 4...25 A ±1.5% of the set value in the range of >25...1000 A Operate time: ±1.0% of the set value or ±20 ms (Current measurement based on internal...
  • Page 298 Operate time: ±1.0% of the set value or ±20 ms Table 196: Current sensor module (SIM4F) Description Value Preferred ABB sensors Current sensors KECA 80 C85 or KECA 80 D85 Current measurement Range 4...8000 A Accuracy ±5% or ±1 A in the range of 4...80 A ±1% in the range of 80...4800 A...
  • Page 299 Section 10 1MRS757488 H Technical data Description Value Fault pass indicator Operating range 1...100 A (earth-fault and residual current) 10…100 A (instantaneous current) Accuracy Depending on the nominal frequency of the current measured: f Current: ±1.5% of the set value Start time :±1.0% of the set value or ±70 ms Operate time: ±1.0% of the set value or ±30 ms Three-phase inrush...
  • Page 300 Section 10 1MRS757488 H Technical data Table 199: Communication interface (communication module LECM) Connector Cable Data transfer Maximum Wave length Permitted distance path attenuation RJ-45 Shielded twisted pair 10/100 30 m cable, at minimum CAT5e Mbits/s Multimode 62.5/125 μm or 100 Mbits/s 2 km 1310 nm...

  • Page 301: Section 11 Device And Functionality Tests

    Section 11 1MRS757488 H Device and functionality tests Section 11 Device and functionality tests Table 202: Inspection of mechanical structure Description Reference Result Markings and mechanical IEC 60255-1 and IEC 60255-27 structure Enclosure class of the flush- IEC 60529 IP 20 mounted device Clearances and creepage IEC 60255-27...
  • Page 302 Section 11 1MRS757488 H Device and functionality tests Table 205: Contact tests Description Type test value Reference Make and carry Signaling contacts IEC 60255-1, IEC 61810-1 and IEEE C37.90-2005 • 5 A, continuous • 10 A for 3 s • 15 A for 0.5 s Breaking capacity for DC, L/R Signaling contacts...
  • Page 303 Section 11 1MRS757488 H Device and functionality tests Description Type test value Reference Pulsed magnetic field 1000 A/m; 6.4/16 μs Tr/Td; 5 IEC 61000-4-9, Level 5 pulses positive/negative; 10 s (time interval) Conducted disturbance induced 0.15...80 MHz - 10 V (unmod, IEC 60255-26 and IEC by radio frequency fields, RMS);...
  • Page 304 Section 11 1MRS757488 H Device and functionality tests Description Type test value Reference • Differential mode 150 V (RMS) 100 Ω coupling resistor 0.1 μF coupling capacitor • Common mode 300 V (RMS) 220 Ω coupling resistor 0.47 μF coupling capacitor Emission tests IEC 60255-26 •...
  • Page 305 Section 11 1MRS757488 H Device and functionality tests Description Type test value Reference • Shock withstanding test Peak acceleration: 15 g Duration of the pulse: 11 ms Number of pulses in each direction: 3 • Bump test Peak acceleration: 10 g Duration of the pulse: 16 ms Number of pulses in each direction: 1000...

  • Page 307: Section 12 Glossary

    Section 12 1MRS757488 H Glossary Section 12 Glossary 1. Application Configuration tool in PCM600 2. Trip status in IEC 61850 Analog output module AOM4 Analog output module Connectivity A collection of software and information related to a package specific protection and control IED, providing system products and tools to connect and interact with the IED Cumulative phasor summing DIM8H...
  • Page 308 Section 12 1MRS757488 H Glossary IEC 61850-8-1 A communication protocol based on the IEC 61850 standard series Intelligent electronic device Internet protocol IP address A set of four numbers between 0 and 255, separated by periods. Each server connected to the Internet is assigned a unique IP address that specifies the location for the TCP/IP protocol.
  • Page 309 Section 12 1MRS757488 H Glossary SCADA Supervision, control and data acquisition Smart control module SIM4F Sensor input module (4 currents) SIM8F Sensor input module (4 currents and 4 voltages) SNTP Simple Network Time Protocol Transmission Control Protocol TCP/IP Transmission Control Protocol/Internet Protocol User datagram protocol Coordinated universal time WHMI...
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