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ABB Remote I/O RIO600, Installation And Commissioning Manual

The ABB Remote I/O RIO600 is a cutting-edge product designed to enhance your industrial automation system. To ensure seamless installation and commissioning, we provide an informative and comprehensive Installation And Commissioning Manual. This manual can be downloaded for free from our website, making it easily accessible for users.

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Remote I/O

RIO600

Installation and Commissioning

Manual

Summary of Contents for Remote I/O RIO600

Page 1: ... Remote I O RIO600 Installation and Commissioning Manual ...

Page 2: ......

Page 3: ...Document ID 1MRS757488 Issued 2019 12 16 Revision H Product version 1 8 Copyright 2019 ABB All rights reserved ...

Page 4: ... in this document is furnished under a license and may be used copied or disclosed only in accordance with the terms of such license Trademarks ABB and Relion are registered trademarks of the ABB Group All other brand or product names mentioned in this document may be trademarks or registered trademarks of their respective holders Warranty Please inquire about the terms of warranty from your neare...

Page 5: ...ce which should be connected to a secure network It is the sole responsibility of the person or entity responsible for network administration to ensure a secure connection to the network and to take the necessary measures such as but not limited to installation of firewalls application of authentication measures encryption of data installation of anti virus programs etc to protect the product and ...

Page 6: ...d 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 The product is designed in accordance with the international standards of t...

Page 7: ... allowed to carry out the electrical installation National and local electrical safety regulations must always be followed The DIN rail of the device has to be carefully earthed The device contains components which are sensitive to electrostatic discharge Unnecessary touching of electronic components must therefore be avoided Whenever changes are made in the device configuration measures should be...

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Page 9: ...le configuration 17 Web HMI 19 PCM600 tool 20 PCM600 and RIO600 connectivity package version 21 Communication 21 TCP IP based protocols and used IP ports 22 Section 4 Unpacking inspecting and storing 23 Removing transport packaging 23 Inspecting the product 23 Identifying the product 23 Checking delivery items 23 Inspecting the product 23 Returning a product damaged in transportation 24 Storing 24...

Page 10: ...rameter settings of RTD mA module 62 Selection of output value format 63 Linear input scaling 64 Measurement chain supervision 64 Calibration 65 Limit value supervision 65 Deadband supervision 66 Operating parameter settings of AOM4 67 Calibration 68 Output channel supervision 68 Deadband supervision 68 Operating parameter settings of SIM8F module 69 Functions available in SIM8F 71 Measurement fun...

Page 11: ...ng 167 Local Remote mode 168 Time synchronization 168 SNTP time synchronization 169 Modbus time synchronization 169 GOOSE performance 170 Section 7 Modbus TCP communication 171 Modbus TCP IP 171 Connection to client 171 Protocol server attachment to a client 171 TCP IP link 171 Modbus TCP IP diagnostic counters over Web HMI 172 Common Modbus TCP IP diagnostic counters 172 Supported Modbus function...

Page 12: ... directional overcurrent fault detection 209 LD0 CMHAI current total demand distortion 210 LD0 VMHAI voltage total demand distortion 211 LD0 EFPTOC non directional earth fault detection 211 LD0 DEFPTOC directional earth fault detection 212 LD0 MFAPSDE multifrequency admittance protection earth fault indication 212 LD0 PHSVPR voltage presence 214 LD0 NSPTOC negative sequence overcurrent fault detec...

Page 13: ...pplication types 241 Binary readable signals of SCM 242 Binary writable signals for SCM 251 Supervision data 258 Section 8 Using the Web HMI 261 Accessing the Web HMI 261 Navigating in the menu 261 Selecting the fault view 261 Selecting the status view 262 Selecting the configuration view 266 Selecting the communication view 270 Section 9 Troubleshooting 273 Checking LED indications 273 Behavior d...

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Page 15: ...e 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 The communication configuration manual contains information on how to engineer the device using the different tools in PCM600 The manual provides information for IEC 61850 engineering with PCM600 ...

Page 16: ...duct version 1 3 3 Related documentation Name of the document Document ID RIO600 Communication Configuration Manual 1MRS757489 Specific Communication Service Mapping SCSM Mappings to MMS ISO 9506 1 and ISO 9506 2 and to ISO IEC 8802 3 IEC 61850 8 1 Download the latest documents from the ABB Web site www abb com mediumvoltage 1 4 Symbols and conventions 1 4 1 Symbols The caution icon indicates impo...

Page 17: ...t conventions A particular convention may not be used in this manual Abbreviations and acronyms are spelled out in the glossary The glossary also contains definitions of important terms Menu paths are presented in bold Select Main menu Settings WHMI menu names are presented in bold Click Information in the WHMI menu structure Parameter names are shown in italics The function can be enabled and dis...

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Page 19: ...rational perspective but they have also introduced cyber security concerns previously known only to office or enterprise IT systems To counter cyber security risks open IT standards are equipped with cyber security mechanisms These mechanisms developed in a large number of enterprise environments are proven technologies They enable the design development and continuous improvement of cyber securit...

Page 20: ...kups available from all applicable parts Collecting and storing backups of the system components and keeping those up to date Changing default passwords and using strong enough passwords Separating public network from automation network Segmenting traffic and networks Using firewalls and demilitarized zones Assessing the system periodically Using antivirus software in workstations and keeping thos...

Page 21: ...n relay or to an upper level system RIO600 accepts three phase sensor signals voltage and current and provides fault detection and metering functions RIO600 allows flexible I O assignment and provides seamless IEC 61850 connectivity between the substation s input and output signals and the protection relay or the COM600 substation gateway ensuring improved functionality and performance RIO600 supp...

Page 22: ... supervise the control circuit of the circuit breaker Furthermore the SCM can be used as a generic module with four binary inputs and four fast power outputs With the RTD mA module RIO600 can be used in different monitoring applications RIO600 can receive temperatures C via RTDs or analog input signals mA from various transducers or devices The input current mA can be linearly scaled for various a...

Page 23: ...s available FPI functionality can be applied as single phase earth fault FPI in case of overhead lines and underground cables and is based on phase current measurements only which can be done with conventional current transformers CTs or with sensors Rogowski coils With the fault passage information the faulted line section can be quickly identified and manual or automatic fault isolation and supp...

Page 24: ...l input module with eight inputs high power supply Digital output module with four outputs 1 1 MOD600BLECMIR MOD600APSML MOD600ADIM8H MOD600APSMH MOD600ADIM8H MOD600ADOM4 New module support added to RIO600 Ver 1 0 New version for communication module to support modules below Low power supply module Digital input module with eight inputs low power supply 1 2 MOD600CLECMIR MOD600ARTD4 MOD600AAOM4 MO...

Page 25: ...OD600GLECMIR MOD600CLECMFO MOD600ASCM8H MOD600ASCM8L MOD600ASIM8F MOD600ASIM4F MOD600ARTD4 MOD600AAOM4 MOD600APSMH MOD600APSML MOD600ADIM8H MOD600ADIM8L MOD600ADOM4 New module support added to RIO600 Ver 1 8 SIM4F sensor module with three phase current input signals New functionality added FPIPTOC INRPHAR SEQSPVC NSPTOC Trip circuit supervision 3 2 Module configuration RIO600 uses a modular archit...

Page 26: ...nt and voltage signals Sensor input module SIM4F Sensor input module with three phase current signals Smart control module SCM8H High voltage range SCM with five application types 4I4O four input and four output channels Three position switch Disconnector Circuit breaker Earthing switch SCM8L Low voltage range SCM with five application types 4I4O four input and four output channels Three position ...

Page 27: ...12 SIM8F SIM4F modules 5 5 Smart control module SCM8H SCM8L 5 40 5 40 A combination of all the modules can be used in a single RIO600 stack The number of modules supported by a number of power supply modules is automatically checked by PCM600 If the selected combination of modules exceeds the number of supported modules related to power consumption the configuration tool gives an indication and do...

Page 28: ...ters for the modules using Parameter Setting Performing the I O mapping across the modules using Signal Matrix Reading and writing the configuration and the parameter file to RIO600 Setting the password using IED Users Establishing the GOOSE communication between the devices configured in PCM600 using IEC 61850 configuration Configuring the Modbus communication settings for connection with Modbus ...

Page 29: ...rallel in the same Ethernet based station bus 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 RIO600 subscribes to a GOOSE message from up to five peer protection relays and publishes to multiple protect...

Page 30: ...loyment guidelines FTP and HTTP are always enabled and cannot be disabled For the FTP protocol it is strongly recommended to change the default password using IED Users Management in PCM600 as described in the communication configuration manual The default password in RIO600 for the ADMINISTRATOR user credential is ABB_RIO600 RIO600 supports only one user credential for ADMINISTRATOR Modbus is dis...

Page 31: ...tom 2 Compare the order number to the ordering information to verify that the received product is correct 4 2 2 Checking delivery items Check that all items are included in the delivery in accordance with the delivery documents 4 2 3 Inspecting the product The product requires careful handling before installation on site Check the product to see if any damage occurred during transportation If the ...

Page 32: ...should be notified immediately if there are any discrepancies in relation to the delivery documents 4 3 Storing If the product is stored before installation it must be done in the original transport packaging in a dry and dust free place Observe the environmental requirements stated in the technical manual Section 4 1MRS757488 H Unpacking inspecting and storing 24 RIO600 Installation and Commissio...

Page 33: ...e in the extreme right side to provide optimally short grounding arrangement to the RTD cable shields Table 5 Predefined order of the modules Number of power supply modules Order of different modules 1 1 1 PSMH or PSML 1 2 LECM 1 3 DIM8H DIM8L DOM4 RTD4 AOM4 SIM8F SIM4F SCM8H or SCM8L 2 1 1 PSMH or PSML 1 2 PSMH or PSML 1 3 LECM 1 4 DIM8H DIM8L DOM4 RTD4 AOM4 SIM8F SIM4F SCM8H or SCM8L 2 Plug in t...

Page 34: ...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 F 99 mm Section 5 1MRS757488 H Installing 26 RIO600 Installation and Commissioning Manual ...

Page 35: ...6C 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 F 99 mm 1MRS757488 H Section 5 Installing RIO600 27 Installation and Commissioning Manual ...

Page 36: ...6 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 F 81 mm Section 5 1MRS757488 H Installing 28 RIO600 Installation and Commissioning Manual ...

Page 37: ...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 F 85 mm 1MRS757488 H Section 5 Installing RIO600 29 Installation and Commissioning Manual ...

Page 38: ...3 IL1 I0 Non Dir EF Inrush 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 F 85 mm Section 5 1MRS757488 H Installing 30 RIO600 Installation and Commissioning Manual ...

Page 39: ...e or during the addition or removal of modules The modules are not hot swappable pluggable Earthing of the used DIN rail should be arranged properly 5 1 1 Configuration examples The user specific configuration can be adapted according to application requirements by combining different modules RIO600 can be configured with a combination of low voltage and high voltage modules for example PSMH LECM ...

Page 40: ...4 PSMH Ready RIO600 LECM Ready IRF Rx Tx 10M 100M DIM8H Ready IRF DI1 DI2 DI3 DI4 DI5 DI6 DI7 DI8 DIM8H Ready IRF DI1 DI2 DI3 DI4 DI5 DI6 DI7 DI8 DIM8H Ready IRF DI1 DI2 DI3 DI4 DI5 DI6 DI7 DI8 DIM8H Ready IRF DI1 DI2 DI3 DI4 DI5 DI6 DI7 DI8 DIM8H Ready IRF DI1 DI2 DI3 DI4 DI5 DI6 DI7 DI8 GUID F70DD116 2FF1 448B B1D5 02DB8E8C404B V1 EN Figure 12 RIO600 configuration 40 channels with 40 DI 5 DIM8H ...

Page 41: ...g wires 5 2 1 Connecting power supply RIO600 supports power supply modules PSMH and PSML With the PSMH module the voltage range for the external power connection is 110 250 V DC 20 and 100 240 V AC 15 to 10 With the PSML module the voltage range for the external power connection is Uaux nominal 24 30 48 60 V DC with variation of 50 120 of Un and the startup threshold is 19 2 V DC 24 V DC 80 1 Fast...

Page 42: ... Figure 15 PSMH terminals Table 6 PSMH screw terminal of power connection X1 Terminal Description 1 Power earth 2 NC Not connected 3 Line positive 4 Neutral negative 5 NC Not connected 6 Power earth Section 5 1MRS757488 H Installing 34 RIO600 Installation and Commissioning Manual ...

Page 43: ... Power earth 2 Positive 3 Positive 4 Negative 5 Negative 6 Power earth terminals of the PSML module are internally shorted terminals of the PSML module are internally shorted Check the source polarity of the terminal connections Reverse polarity can withstand only 60 seconds at the maximum 1MRS757488 H Section 5 Installing RIO600 35 Installation and Commissioning Manual ...

Page 44: ...o the IEC 61850 station bus through the Ethernet switch Ensure that the fiber optic cable is connected on both ends of the device Looking directly at the LC connector may damage eyes Change the default IP address of the LECM module by using the Parameter Setting tool in PCM600 Table 8 Default settings of the LECM module Setting Value IP 192 168 2 10 Subnet mask 255 255 255 0 Default gateway 192 16...

Page 45: ... input connectors through the upper and lower screw terminals 2 Connect wires to the DI and 0V signals DIM8H DIM8L DI 1 DI 2 DI 3 DI 4 X1 0V DI1 DI2 DI3 DI4 0V 4 2 6 1 3 5 DI 5 DI 6 DI 7 DI 8 X2 0V DI5 DI6 DI7 DI8 0V 4 2 6 1 3 5 GUID FE36DD3B 6CE0 4B26 9D9D D2E5B10FDEB8 V2 EN Figure 17 DIM8H DIM8L terminals Table 9 Screw terminal of the DIM8H DIM8L connection X2 Binary input terminal Description L...

Page 46: ...ces The rated voltage for binary output connection is 250 V AC or 250 V DC The binary output contact operation time is 5 7 ms 1 Fasten the output connector through the upper and lower screw terminals 2 Connect wires to the DO and COM signals DOM4 DO1 DO2 DO4 DO3 DO1 COM DO2 DO3 DO4 COM X1 4 2 6 1 3 5 GUID 1E9D25F1 9224 4DBB 921A F310E2ACAE7A V2 EN Figure 18 DOM4 terminals Table 10 Screw terminal o...

Page 47: ...ls 1 Fasten the input connector through the upper and lower screw terminals 2 Connect the signals based on the type of configuration For 2 wire RTD configuration connect the RTD signals between and terminals and short and C terminals else there will be an IRF RTD4 Resistor sensor Resistor sensor Resistor sensor Resistor sensor Earth Clamp mounted on DIN Rail X1 1C 1 1 2C 2 2 4 2 6 1 3 5 RTD1 RTD2 ...

Page 48: ...nsor Earth Clamp mounted on DIN Rail X1 1C 1 1 2C 2 2 4 2 6 1 3 5 RTD1 RTD2 X2 3C 3 3 4C 4 4 4 2 6 1 3 5 RTD3 RTD4 GUID F9DE43D9 89EA 4C64 A58A 3C7D77E9FDA3 V2 EN Figure 20 3 wire RTD Section 5 1MRS757488 H Installing 40 RIO600 Installation and Commissioning Manual ...

Page 49: ...e more accurate Table 11 Screw terminal of RTD mA connection X2 RTD mA input terminal Description X1 RTD mA input terminal Description 1 3C Ch3 compensation 1 1C Ch1 compensation 2 3 Ch3 return path negative terminal 2 1 Ch1 return path negative terminal 3 3 Ch3 positive terminal 3 1 Ch1 positive terminal Table continues on next page 1MRS757488 H Section 5 Installing RIO600 41 Installation and Com...

Page 50: ...gnals 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 Check that the proper power supply and LECM modules are mounted on the DIN rail The AOM4 module has two sets of connectors where each set provides two AOM4 signals 1 Fasten the input connector through the upper and lower screw terminals 2 For AOM4 config...

Page 51: ...e terminal 2 1 Ch1 return path negative terminal 3 NC Not connected 3 NC Not connected 4 NC Not connected 4 NC Not connected 5 4 Ch4 out 5 2 Ch2 out 6 4 Ch4 return negative terminal 6 2 Ch2 return negative terminal 5 2 7 Connecting SIM8F sensor signals RIO600 accepts three phase voltage and current signals to RJ 45 connectors The input signals are fed from combined non conventional instrument tran...

Page 52: ...ut 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 B21 RIO600 supports also split core current sensor type for retro fit purposes Preferred split core sensor is KECA 80 D85 KEVCY XX RE...

Page 53: ...n Sensor terminal connection Description I0 4 5 S1 S2 Analog input connection for neutral Io earth current connection IL1 UL1 4 5 7 8 S1 S2 a n Analog input connector for phase 1 current and voltage signals IL2 UL2 4 5 7 8 S1 S2 a n Analog input connector for phase 2 current and voltage signals IL3 UL3 4 5 7 8 S1 S2 a n Analog input connector for phase 3 current and voltage signals 1MRS757488 H Se...

Page 54: ...nector with adapter 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 KEVCY XX RE1 RIO600 RJ 45 Cable RJ 45 GUID 3FE5111C 6DB7 4836 A187 CD4C363DB8C7 ...

Page 55: ...erminal Connector Pin Sensor terminal connection Description I0 4 5 S1 S2 Analog input connection for neutral Io earth current connection IL1 4 5 S1 S2 a n Analog input connector for phase 1 current signal IL2 4 5 S1 S2 a n Analog input connector for phase 2 current signal IL3 4 5 S1 S2 a n Analog input connector for phase 3 current signal 1MRS757488 H Section 5 Installing RIO600 47 Installation a...

Page 56: ...he voltage range for SCM8H binary input connection is 110 250 V DC 20 The threshold is 78 V DC The voltage range for SCM8L binary input connection is 24 60 V DC 20 The threshold is 13 V DC The operation time of the high speed output contact is 200 µs 1 Fasten the input and output connectors through the upper and lower screw terminals 2 Connect wires to the signals according to the used application...

Page 57: ...CM connection for three position switch application X1 Connector inputs Description X2 Connector outputs Description OV 1 Common return for DI1 and DI2 1 AUX DC voltage L DI1 2 Earthing switch CLOSE position signal HS1 2 DC motor connection DI2 3 Earthing switch OPEN position signal HS2 3 DC motor connection DI3 4 Disconnector switch CLOSE position signal HS3 4 DC motor connection DI4 5 Disconnect...

Page 58: ...connection for two position earthing switch application X1 Connector inputs Description X2 Connector outputs Description OV 1 Common return for DI1 and DI2 1 AUX DC voltage L DI1 2 Earthing switch CLOSE position signal HS1 2 DC motor connection DI2 3 Earthing switch OPEN position signal HS2 3 DC motor connection DI3 4 Digital input 3 HS3 4 DC motor connection DI4 5 Digital input 4 HS4 5 DC motor c...

Page 59: ...ion for two position disconnector switch application X1 Connector inputs Description X2 Connector outputs Description OV 1 Common return for DI1 and DI2 1 AUX DC voltage L DI1 2 Digital input 1 HS1 2 DC motor connection DI2 3 Digital input 2 HS2 3 DC motor connection DI3 4 Disconnector switch CLOSE position signal HS3 4 DC motor connection DI4 5 Disconnector switch OPEN position signal HS4 5 DC mo...

Page 60: ...V3 EN Figure 30 Connection diagram for circuit breaker application with trip circuit supervision direct tripping double pole Table 18 SCM connection for circuit breaker application X1 Connector inputs Description X2 Connector outputs Description OV 1 Common return for for DI1 and DI2 1 AUX DC voltage L DI1 2 Position indication for CB Open HS1 2 CB OPEN Trip coil DI2 3 Position indication for CB C...

Page 61: ...V 1 2 3 4 5 6 X2 HS1 HS2 HS3 HS4 1 2 3 4 5 6 COM for DI1 and DI2 DIGITAL INPUT 1 DIGITAL INPUT 2 DIGITAL INPUT 3 COM for DI3 and DI4 L L High Speed output 1 High Speed output 2 High Speed output 3 High Speed output 4 HS1 HS2 HS3 HS4 DIGITAL INPUT 4 GUID 3EC4F59A 7633 4CBE 8FDB 3CE12B4386D4 V2 EN Figure 31 Connection diagram for generic four DI and four high speed power outputs HS 1MRS757488 H Sect...

Page 62: ...ription X2 Connector outputs Description OV 1 Common return for DI1 and DI2 1 AUX DC voltage L DI1 2 Digital input 1 HS1 2 High speed output 1 DI2 3 Digital input 2 HS2 3 High speed output 2 DI3 4 Digital input 3 HS3 4 High speed output 3 DI4 5 Digital input 4 HS4 5 High speed output 4 OV 6 Common return for DI3 and DI4 6 AUX DC voltage L 5 3 Connecting RIO600 to a PC Connect RIO600 to a PC within...

Page 63: ...open the Run dialog box 2 Type cmd in the Open box 3 Click OK to access the command prompt GUID 06A4AF7C 7A20 4D63 BD70 E2B633777D65 V1 EN Figure 33 Starting command prompt 4 Ping the IP address of RIO600 by typing for example ping 192 168 2 10 GUID 4C8C424E 1711 4601 A423 F8531B635488 V1 EN Figure 34 Type ping command RIO600 responds with valid Ping replies if the connection and used IP address a...

Page 64: ...56 ...

Page 65: ...s for RIO600 Synch Source None SNTP Modbus None Time synchronization SNTP selection None SNTP functionality not selected If the SNTP time synchronization is not required or available the Synch Source parameter must be set to None RIO600 displays the default time on the WHMI in red to indicate that time is not synchronized SNTP SNTP functionality selected If two separate SNTP servers are available ...

Page 66: ...erateinastandalonemode Duringthismode RIO600 ignores all events from the publisher It also does not check for any communication errors or warnings and the modules can be configured as desired With the parameter default value false the Ethernet cable is expected to be connected otherwise RIO600 indicates a warning due to communication failure 6 1 1 2 Intermodule communication Binary signals in RIO6...

Page 67: ...nnel 4 input type non inverted inverted Channel 5 Inversion Non Inverted Inverted Non Inverted channel 5 input type non inverted inverted Channel 6 Inversion Non Inverted Inverted Non Inverted channel 6 input type non inverted inverted Channel 7 Inversion Non Inverted Inverted Non Inverted channel 7 input type non inverted inverted Channel 8 Inversion Non Inverted Inverted Non Inverted channel 8 i...

Page 68: ...inals Accordingly the input state is FALSE 0 when a control voltage is applied to the terminals of the binary input LEDs and WHMI reflect the physical input signal present on the binary input terminal 6 1 2 3 Oscillation suppression Oscillation suppression is used to reduce the load from the system when a binary input starts oscillating A binary input is regarded as oscillating if the number of va...

Page 69: ...s parameter is configurable separately for each output channel Output Channel 1 Inversion Non Inverted Inverted Non Inverted channel 1 output type non inverted inverted Output Channel 2 Inversion Non Inverted Inverted Non Inverted channel 2 output type non inverted inverted Output Channel 3 Inversion Non Inverted Inverted Non Inverted channel 3 output type non inverted inverted Output Channel 4 In...

Page 70: ...200 C 0 0 20 0 mA Minimum range of input based on the selected input mode For example if the selected Input Mode is 0 20 mA and the channel has to be configured for 4 20 mA Input Min is 4 0 SuperVision time 0 5 s 5 The rate at which value of measurements is reported Tolerance Low 0 4 0 Tolerance in percentage on lower value of mA input range For RTD this is not applicable For example if the channe...

Page 71: ... 10 0 5 Deadband value in percentage or range Configure the input mode of unused RTD channels as Not in use 6 1 4 1 Selection of output value format Each channel has individual Value unit settings for selecting the unit for the channel output The default setting is Dimensionless The other settings like Input minimum Input maximum Value maximum and Value minimum have to be adjusted according to the...

Page 72: ...lue minimum and Value maximum is the range of the scaled value of the input The input scaling can be bypassed by selecting Value unit to be mA when Input mode is 0 20 mA Example of linear scaling The mA input is used as tap changer position information The sensor information is from 4 20 mA which is equivalent to the tap changer position from 36 36 respectively GUID 2605859F 0877 4477 A3AA 98BC1F8...

Page 73: ...low 40 C Current high 20 mA Current low Minimum of Input Min parameter value One supervisory circuitry is shared between two input channels If the supervisory circuitry detects failure both input channels are declared faulty 6 1 4 4 Calibration The RTD and mA input channel is calibrated at the factory 6 1 4 5 Limit value supervision The limit value supervision indicates whether the measured value ...

Page 74: ...supervision Deadband settings are used to select how sensitively RIO600 sends the updated measurements to data subscriber over the GOOSE and Modbus communication The deadband settings must be sensitive enough to report events fast enough but also insensitive enough not to load the Ethernet network with unnecessary events The deadband functionality decides the percentage change in the input values ...

Page 75: ...adband supervision works properly 6 1 5 Operating parameter settings of AOM4 Table 27 Operating parameter settings of AOM4 Parameter name Range Unit Default value Description Description Analog Output 1 4 User defined channel name not exceeding 30 characters Output Mode 0 20 Not in use mA Not in use Mode of configuration When Not in use is selected the channel is disabled Output Max 0 20 20 Maximu...

Page 76: ... AOM4 module operates the output based on the information received over GOOSE or Modbus communication The deadband functionality decides the percentage change in the output value that needs to be generated at the AOM4 output terminals If the percentage change between the newly received value and the last driven value is greater than the set Deadband Value in of the output range then the newly rece...

Page 77: ...urrent sensor phase A Current Phase 3 0000 3 0000 deg 0 00025 0 000 Phase correction factor for current sensor phase A Voltage Amplitude 0 7000 1 3000 0 0001 1 0000 Amplitude correction factor for voltage sensor phase A Voltage Phase 3 0000 3 0000 deg 0 00025 0 000 Phase correction factor for voltage sensor phase A Phase B Current Amplitude 0 7000 1 3000 0 0001 1 0000 Amplitude correction factor f...

Page 78: ...g 0 00025 0 000 Phase correction factor for current sensor residual LED Reset Time Delay 1 1440 min 1 60 LEDs Reset delay time incase no external signal received for resetting This is applicable to THD TDD OC and EF fault indication LEDs Default Load Flow Direction Forward Reverse Forward Load flow direction selection The load flow direction LED color for Forward selection is Forward Green Reverse...

Page 79: ... 4 Update interval for metering values 500 ms New installation Performs reset of energy counter and internal statistics information 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 6 1 6 1 Functions available in SIM8F Table 29 Function...

Page 80: ...etection PHPTOC PHPTOC 3I 51P Three phase directional overcurrent fault detection DPHPTOC DPHPTOC 3I 67P Non directional earth fault fault detection EFPTOC EFPTOC I0 51N Directional earth fault fault detection DEFPTOC DEFPTOC I0 67N Multifrequency admittance based earth fault indication MFAPSDE MFAPSDE I0 Y 67YN Voltage presence indication PHSVPR PHSVPR PHSVPR PHSVPR Negative sequence overcurrent ...

Page 81: ... A phsB cVal mag f REAL Current amplitude for phase B A phsB cVal ang f REAL Current phase angle for phase B A phsC cVal mag f REAL Current amplitude for phase C A phsC cVal ang f REAL Current phase angle for phase C Table 32 CMMXU Technical data Characteristic Value Operation accuracy At frequency f fn 5 or 1 A in the range of 4 80 A 1 in the range of 80 4800 A 10 in the range of 4800 8000 A Supp...

Page 82: ...t signals Name Type Description PhV phsA cVal mag f REAL Phase to ground voltage amplitude for phase A PhV phsA cVal ang f REAL Voltage phase angle for Phase A PhV phsB cVal mag f REAL Phase to ground voltage amplitude for phase B PhV phsB cVal ang f REAL Voltage phase angle for Phase B PhV phsC cVal mag f REAL Phase to ground voltage amplitude for phase C PhV phsC cVal ang f REAL Voltage phase an...

Page 83: ...ession of harmonics RMS No suppression Residual current measurement RESCMMXU Identification Function description IEC 61850 identification IEC 60617 identification ANSI IEEE C37 2 device number Residual current measurement RESCMMXU Io Io Function block RESCMMXU I_A A res cVal mag f A res cVal ang f I_B I_C GUID 80967B14 2C3D 4CB8 BA66 EB6DE083DEF4 V1 EN Figure 40 Function block Signals Table 36 RES...

Page 84: ...easurement RESVMMXU Identification Function description IEC 61850 identification IEC 60617 identification ANSI IEEE C37 2 device number Residual voltage measurement RESVMMXU Uo Uo Function block RESVMMXU U_A PhV res cVal mag f PhV res cVal ang f U_B U_C GUID AA414F24 C0AE 4743 93C7 939D98C69FE4 V1 EN Figure 41 Function block Signals Table 39 RESVMMXU Input signals Name Type Default Description U_A...

Page 85: ...2 device number Three phase power and energy measurement PEMMXU P P Function block PEMMXU I_A I_B I_C VA phsA cVal U_A U_B U_C W phsA cVal VAr phsA cVal VA phsB cVal W phsB cVal VAr phsB cVal VA phsC cVal W phsC cVal VAr phsC cVal TotVA TotW TotVAr TotPF Hz GUID 78BA8F95 76F5 4348 9A01 BCDB6750D41F V1 EN Figure 42 Function block Power and energy calculation The three phase power is calculated from...

Page 86: ...D 46D2 9344 87912681BF9D V1 EN Equation 4 Q1 Q2 Q3 Q4 Fwd active energy Rev active energy Fwd reactive energy Rev reactive energy P Q ind PF 1 00 PF 1 00 PF 0 00 P Q cap P Q cap P Q ind S GUID D76C8746 7BA9 43CE 93F4 B7750B667D86 V1 EN Figure 43 Power quadrants Table 42 Complex Power quadrants Quadrant Current P Q PF Power Q1 Lagging 0 1 00 ind Q2 Lagging 0 1 00 cap Q3 Leading 0 1 00 ind Q4 Leadin...

Page 87: ...ower Phase C W phsC cVal REAL Active power Phase C VAr phsC cVal REAL Reactive power Phase C TotVA REAL Total Apparent power TotW REAL Total Active power TotVAr REAL Total Reactive power TotPF REAL Total Power Factor Hz REAL System frequency Table 45 PEMMXU Technical data Characteristic Value Operation accuracy At frequency f fn All three voltages are in the range of 9 6 14 4 kV or 19 2 28 8 kV Al...

Page 88: ...e 46 PWRRDIR Input signals Name Type Default Description P_INST_A SIGNAL Active power Phase A P_INST_B SIGNAL Active power Phase B P_INST_C SIGNAL Active power Phase C Table 47 PWRRDIR Output signals Name Type Description Dir General BOOLEAN Direction of load flow forward or reverse Energy monitoring EMMTR Identification Function description IEC 61850 identification IEC 60617 identification ANSI I...

Page 89: ...gram Energy Calculation Based on the measured powers the linear average of the active and reactive energies over a preset time interval of 500 ms is calculated The accumulated forward and reverse active energy value is available at DmdWh and SupWh and the accumulated forward and reverse reactive energy value is available at DmdVArh and SupVArh respectively The binary signal RESET ENERGY COUNTER fr...

Page 90: ... are in the range of 9 6 14 4 kV or 19 2 28 8 kV All three currents are in the range of 80 630 A Active power and energy are in the range PF 0 71 Reactive power and energy are in the range PF 0 71 3 0 for energy Suppression of harmonics RMS No suppression Current voltage and power average and peak measurement CMSTA VMSTA PEMSTA Identification Function description IEC 61850 identification IEC 60617...

Page 91: ...n be enabled and disabled with the Operation setting The corresponding parameter values are On and Off The average interval can be set to 3 10 15 60 120 or 1440 minutes and the peak interval to 1 day 1 week 1 month or 1 year Signals Table 51 CMSTA VMSTA PEMSTA Input signals Name Type Default Description I_A REAL Phase A current I_B REAL Phase B current I_C REAL Phase C current U_A REAL Phase to ea...

Page 92: ...plicable if Io signal sel is Measured Io MaxAmpsI0 REAL Peak Residual current Applicable if Io signal sel is Measured Io AvW REAL Average total Active power MaxW REAL Peak total Active power AvVAr REAL Average total reactive power MaxVAr REAL Peak total reactive power AvVA REAL Average total apparent power MaxVA REAL Peak total apparent power Settings Table 53 CMSTA VMSTA PEMSTA Settings Name Valu...

Page 93: ...on TDD The function can be enabled and disabled with the Operation setting The corresponding parameter values are On and Off The operation of the current distortion monitoring function can be described with a module diagram All the modules in the diagram are explained in the next sections Operation principle The function can be enabled and disabled with the Operation setting The corresponding para...

Page 94: ...istortion in a power system is caused by nonlinear devices Electronic power converter loads constitute the most important class of nonlinear loads in a power system The switch mode power supplies in a number of single phase electronic equipment such as personal computers printers and copiers have very high third harmonic content in the current Three phase electronic power converters that is dc ac ...

Page 95: ...TDD Settings Table 56 CMHAI Settings Name Values Range Unit Step Default Description Operation On Off On Operation Off On TDD Alarm Limit 5 0 100 0 0 1 10 Limit of TDD Measuring Mode Worst case Phase A Phase B Phase C Worst case Specifies the monitored phase Voltage total demand distortion monitoring VMHAI Identification Function description IEC 61850 identification IEC 60617 identification ANSI I...

Page 96: ...OCK HiAThd U_A U_B U_C GUID 59E5E9BC 90DB 4467 860E B0470C220118 V1 EN Figure 51 Functional module diagram Distortion measurement The distortion measurement module measures harmonics up to the 8th harmonic The total harmonic distortion THD is calculated from the measured harmonic components with the formula THD Uk U k N 2 2 1 GUID E60DDDB4 1527 49FF 92C6 2F9768515268 V1 EN Equation 6 Uk kth harmon...

Page 97: ...able 59 VMHAI Settings Name Values Range Unit Step Default Description Operation On Off On Operation Off On THD Alarm Limit 5 0 100 0 0 1 10 Limit of THD Measuring Mode Worst case Phase A Phase B Phase C Worst case Specifies the monitored phase 6 1 6 4 Three phase current fault detection Three phase non directional overcurrent fault detection PHPTOC Identification Function description IEC 61850 id...

Page 98: ...r reports the exceeding value to the phase selection logic The Absolute hysteresis setting can be used for preventing unnecessary oscillations in the START and OPERATE output signals if the input current is slightly above or below the Start value setting After leaving the hysteresis area the start condition has to be met again and if it is not sufficient the signal returns to the hysteresis area P...

Page 99: ...signal for phase B Str phsC Boolean Start signal for phase C Settings Table 61 PHPTOC Settings Name Values Range Unit Step Default Description Operation Off On On Operation Off On No of Start Phases 1 out of 3 2 out of 3 3 out of 3 1 out of 3 Number of phases required for operate activation Start Value 50 2000 A 10 480 Start value for overcurrent fault detection Operate Delay Time 40 60000 ms 10 4...

Page 100: ...n be described by using a module diagram All modules in the diagram are explained in the next sections I_A Op general I_C I_B Op phsA t Timer Op phsB Op phsC Str general Str phsA Str phsA Str phsA Level detector U_AB U_CA U_BC Directional calculation Str dirGeneral Str dirPhsA Str dirPhsb Str dirPhsc Phase selection logic GUID 2AF67C1E 7D35 4BE0 8E27 B9C37F8B9579 V1 EN Figure 53 Functional module ...

Page 101: ...voltage is applied again when the voltage is above 500 V The fictive voltage is also discarded if the measured voltage stays below Min operate voltage of 500 V longer than the Voltage Mem time of 100 ms or if the fault current disappears while the fictive voltage is in use When the voltage is below Min operate voltage of 500 V and the fictive voltage is unusable the fault direction cannot be deter...

Page 102: ...o Forward or Reverse When Directional mode is set to Non directional and PHPTOC operates in unknown direction none of the LEDs show fault inditation The OP GENERAL output is available at LED 6 of 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 OP PHSB OpFwd and OpRev are available over communication Di...

Page 103: ...ult direction and combined fault directions values are calculated Table 63 Per phase fault direction indication Criterion for per phase fault direction information Value for fault direction FLT_A FLT_B FLT_C Angle between the polarizing and operating quantity is not in any of the defined sectors 0 unknown Angle between the polarizing and operating quantity is in the forward sector 1 forward Angle ...

Page 104: ... current Used polarizing voltage Angle difference A IA UBC φ φ φ U I BC A RCA 90 GUID A462A4C2 7617 4944 9B69 5AD854D3B40F V1 EN B IB UCA φ φ φ U I CA B RCA 90 GUID 55FC4CD6 7CFB 4ECA 90B9 CDC92683A42F V1 EN C IC UAB φ φ φ U I AB C RCA 90 GUID C599D19E ECE2 4741 9B01 5A7743EA36E7 V1 EN A B I I A B GUID FAFD19A0 FE4B 4B96 9DBE DC325D510215 V1 EN U U BC CA GUID 13B8B970 B7FF 4BE0 A6A0 1647C3E76B40 V...

Page 105: ... quantity IA is marked as ϕ Note that the polarizing quantity is rotated with 90 The Characteristic angle is assumed to be 0 Figure 56 shows phasors in two phase short circuit failure where the fault is between phase B and phase C The angle difference between the polarizing quantity U U CA AB and operating quantity I I B C is marked as ϕ Figure 55 and Figure 56 are valid if the phase rotation is A...

Page 106: ... Name Type Description Op general Boolean General operate signal Op phsA Boolean Operate signal for phase A Op phsB Boolean Operate signal for phase B Op phsC Boolean Operate signal for phase C OpFwd Boolean Operate signal indicating fault in forward direction when Directional mode is set to Non Directional Table continues on next page Section 6 1MRS757488 H Commissioning 98 RIO600 Installation an...

Page 107: ...f Start Phases 1 out of 3 2 out of 3 3 out of 3 1 out of 3 Number of phases required for operate activation Start Value 50 2000 A 10 480 Start value for overcurrent fault detection Operate Delay Time 40 60000 ms 10 40 Operate delay time Directional Mode Forward Reverse Non directional Forward Directional mode Characteristics Angle 179 180 Deg 1 0 Characteristics angle Max Forward Angle 0 90 Deg 1 ...

Page 108: ...Identification Function description IEC 61850 identification IEC 60617 identification ANSI IEEE C37 2 device number Non directional earth fault fault detection EFPTOC I0 51N Functionality The earth fault overcurrent fault detection function EFPTOC is used as a non directional phase to earth fault detection The function starts when the residual current exceeds the set limit Function operates with d...

Page 109: ... above or below the Start value setting After leaving the hysteresis area the start condition has to be fulfilled again and if it is not sufficient the signal returns to the hysteresis area Timer Once the Timer is activated it activates the STR GENERAL output The time characteristic is according to the definite time When the operation timer has reached the value set by Operate delay time the OP GE...

Page 110: ...ication IEC 60617 identification ANSI IEEE C37 2 device number Directional earth fault fault detection DEFPTOC I0 67N Functionality The earth fault function DEFPTOC is used as a directional earth fault detection for feeders The function starts when the operating quantity residual current Io and polarizing quantity zero sequence voltage Uo exceed the set limits and the angle between them is inside ...

Page 111: ...RAL output if the operating and or polarizing quantity is slightly above or below the Start value setting After leaving the hysteresis area the start condition has to be fulfilled again and if it is not sufficient the signal returns to the hysteresis area Directional calculation The directional calculation module monitors the angle between the polarizing quantity and operating quantity When the an...

Page 112: ...ion module also provides the information about the direction of fault STR DIRGENERAL during fault situation The information is available over GOOSE communication Timer Once the Timer is activated it activates the STR GENERAL output The time characteristic is according to the definite time When the operation timer has reached the value set by Operate delay time the OP GENERAL output is activated If...

Page 113: ...o produce the maximum torque That is RCA is the angle between the maximum torque line and polarizing quantity If the polarizing quantity is in phase with the maximum torque line RCA is 0 The angle is positive if operating current lags the polarizing quantity and negative if it leads the polarizing quantity Example 1 If the Phase angle mode is selected the compensated network ϕRCA 0 and Characteris...

Page 114: ...aracteristic angle 60 Min forward angle Maximum torque line Zero torque line Uo Polarizing quantity Io Operating quantity GUID F4486C5A 7AD2 416D 865D A0E03E4418B2 V1 EN Figure 60 Definition of the relay characteristic angle RCA 60 in a solidly earthed network Example 3 If the Phase angle mode is selected the solidly earthed network ϕRCA 90 and Characteristic angle 90 Section 6 1MRS757488 H Commis...

Page 115: ...ugh the phase to earth capacitances C0 of phases and leakage resistances R0 This means that the residual current is mainly capacitive and has a phase shift of 90 compared to the polarizing voltage Consequently the relay characteristic angle RCA should be set to 90 and the operation criteria to IoSin or Phase angle The width of the operating sector in the phase angle criteria can be selected with t...

Page 116: ...coil would disturb the operation of the relays In this case the selectivity is based on the measurement of the active current component The magnitude of this component is often small and must be increased by a parallel resistor in the compensation equipment When measuring the resistive part of the residual current the relay characteristic angle RCA should be set to 0 and the operation criteria to ...

Page 117: ...e angle settings The sector limits are always defined as positive degree values In the forward operation area the Max forward angle setting defines the clockwise sector and the Min forward angle setting defines the counter clockwise sector measured from the Characteristic angle setting In the reverse operation area the Max reverse angle setting defines the clockwise sector and the Min reverse angl...

Page 118: ...ard Angle between the polarizing and operating quantity is in the reverse sector 2 backward Angle between the polarizing and operating quantity is in both the forward and the reverse sectors that is the sectors are overlapping 3 both The directional operations forward and reverse are not allowed when the measured polarizing or operating quantities are invalid that is their magnitude is below the m...

Page 119: ...ted with the Operation mode setting using the values IoSin or IoCos respectively When the Iosin ϕ or Iocos ϕ criterion is used the component indicates a forward or reverse type fault through the STR DIRGENERAL output where 1 forward fault and 2 reverse fault In case of low magnitude the STR DIRGENERAL output is set to 0 unknown The function is allowed to operate in the directional mode as non dire...

Page 120: ...erating current jRCA 90 deg 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 Section 6 1MRS757488 H Commissioning 112 RIO600 Installation and Commissioning Manual ...

Page 121: ...erating current jRCA 90 deg 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 1MRS757488 H Section 6 Commissioning RIO600 113 Installation and Commissioning Manual ...

Page 122: ...in operating current 0 deg 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 Section 6 1MRS757488 H Commissioning 114 RIO600 Installation and Commissioning Manual ...

Page 123: ...Output signals Name Type Description Op general Boolean Operate signal OpFwd Boolean Operate signal indicating fault in forward direction when Directional mode is set to Non Directional OpRev Boolean Operate signal indicating fault in reverse direction when Directional mode is set to Non Directional Str general Boolean Start signal Str dirGeneral Integer Detected fault direction 1MRS757488 H Secti...

Page 124: ...cs Angle 179 180 Deg 1 0 Characteristics angle Max Forward Angle 0 180 Deg 1 80 Maximum phase angle in forward direction Max Reverse Angle 0 180 Deg 1 80 Maximum phase angle in reverse direction Min Forward Angle 0 180 Deg 1 80 Minimum phase angle in forward direction Min Reverse Angle 0 180 Deg 1 80 Minimum phase angle in reverse direction Min Operate Current A 1 Minimum operating current to allo...

Page 125: ...t protection of overhead lines and underground cables The operation of MFAPSDE is based on multifrequency neutral admittance measurement utilizing cumulative phasor summing technique This concept provides extremely secure dependable and selective earth fault protection also in cases where the residual quantities are highly distorted and contain non fundamental frequency components Besides faults w...

Page 126: ...e voltage defined as the vector sum of fundamental frequency phase voltage phasors divided by three U U U U A B C 0 1 1 1 1 3 GUID C4866966 64A3 4E7E 9794 8920040B61B5 V1 EN Equation 7 When the magnitude of U0 1 exceeds the Voltage start value setting an earth fault is detected The GFC module reports the exceeded value to the Fault direction determination module and Operation logic The reporting i...

Page 127: ...es of a particular harmonic in residual current and zero sequence voltage are measurable by the IED Fundamental frequency admittance conductance and susceptance Y I U G j B o o 0 1 0 1 0 1 1 1 3 GUID 594F3E58 1090 49B0 BB46 B531EA1FDF4D V1 EN Equation 8 Y0 1 Fundamental frequency neutral admittance phasor I0 1 Fundamental frequency zero sequence current phasor I I I A B C 1 1 1 3 U0 1 Fundamental ...

Page 128: ...le To obtain dependable and secure fault direction determination regardless of the fault type transient intermittent permanent high or low ohmic the fault direction is calculated using a special filtering algorithm that is the Cumulative Phasor Summing CPS technique This filtering method is advantageous during transient and intermittent earth faults with dominantly non sinusoidal or transient cont...

Page 129: ... as an intermittent earth fault This is also true for harmonic components included in the sum admittance phasor Harmonics have typically a highly fluctuating character Harmonic components provide a more distinctive directional determination in compensated networks than the fundamental frequency components With higher frequencies the compensation coil appears as a very high impedance and the harmon...

Page 130: ...ion adequate tilt angle must be allowed to ensure dependable operation of MFAPSDE In Figure 71 phasors 1 4 demonstrate the behavior of the directional phasor in different network fault conditions Phasor 1 depicts the direction of accumulated sum admittance phasor in case of an earth fault outside the protected feeder assuming that the admittance of the protected feeder is dominantly capacitive The...

Page 131: ..._OpRe Outputs MFAPSDE_OpFw and MFAPSDE_OpRe provide the fault direction irrespective of settings Power direction logic and Directional mode To adapt the fault direction determination to possible fault direction change during the fault for example during manual fault location process a cyclic accumulation of sum admittance phasors is conducted The duration of this directional evaluation cycle is 1 ...

Page 132: ...cy residual current estimate which is obtained after conversion from the corresponding admittance value by multiplying it with the system nominal phase to earth voltage value IoCosstab 1 Real part of stabilized fundamental frequency residual current estimate IoSinstab 1 Imaginary part of stabilized fundamental frequency residual current estimate The main advantage of the filtering method is that d...

Page 133: ...nimum operate current threshold is compared to the resistive component of I stab 0 1 This automatic adaptation of the magnitude supervision enables secure and dependable directional determination in compensated networks and it is also valid when network is unearthed compensation coil is switched off If the operation direction is set to Reverse the resistive and amplitude sectors are mirrored in th...

Page 134: ... to the amplitude of I stab 0 1 In case of restriking earth faults harmonics created by the fault type make the accumulated sum admittance phasor behave as in case of an unearthed network Therefore operation can be achieved without the need for resistive part of I stab 0 1 This also means that in compensated networks during earth faults with rich harmonic content in residual quantities operation c...

Page 135: ... a risk of local overcompensation of a protected feeder that is when the earth fault current is compensated with distributed compensation coil and their inductive current exceeds the amount of capacitive current produced by the phase to earth capacitance of the feeder In compensated networks where distributed compensation coils are also used to compensate earth fault current setting Operating Quan...

Page 136: ...d setting operating quantity Amplitude If the Adaptive or Resistive operating quantity is selected setting Min Forward Operate Current should be set to a value less than p IRtot IRtot is the total resistive earth fault current of the network corresponding to the resistive current of the parallel resistor of the coil and the network losses of the system typically in order of 1 5 of the total capaci...

Page 137: ...hat only the faulty feeder is disconnected or alarmed Therefore the threshold values should be selected carefully and not set too high as this can inhibit the disconnection of the faulty feeder Transient detector The transient detector module is used for detecting transients in the residual current and residual voltage signals When the number of detected transients equals or exceeds the Peak Count...

Page 138: ...s of earth faults regardless of their type transient intermittent permanent high or low ohmic The Voltage start value setting defines the basic sensitivity of the MFAPSDE function The operate timer is started in the following conditions Earth fault is detected by the General fault criteria GFC Fault direction equals the Directional mode setting If the Power direction logic setting is set to Enable...

Page 139: ...The LED turns ON when this signal becomes high The LED color depends on setting Directional mode of the MFAPSDE function The LED is green for forward setting and red for reverse setting If the detection of temporary earth faults is not desired the activation of MFAPSDE_St output may be delayed with the Start Delay Time setting The same setting can also be used to avoid restarting of the function d...

Page 140: ... If the fault direction changes before the previous fault is cleared the WHMI shows the direction as reverse since its direction variable is updated with the latest condition in SIM and start and operate are not cleared as they are latched In the second case the WHMI shows Unknown direction because it ignores the direction information if start and operate are not triggered To keep the operate time...

Page 141: ... output is activated once Start delay time has elapsed Reset timer is activated at the falling edge of General Fault Criterion release that is when zero sequence voltage falls below Voltage start value MFAPSDE_ReEF is reset once the reset delay time elapses MFAPSDE_ReEF is also available as a GOOSE output If the Power direction logic setting is set to Enable the active power flow direction must be...

Page 142: ...operate direction Signals Table 78 MFAPSDE Output signals Name Type Description MFAPSDE_Oper Boolean Operate signal MFAPSDE_St Boolean Start signal MFAPSDE_ReEF Boolean Signal for EF to indicate opposite fault direction MFAPSDE_InEF Boolean Intermittent earth fault indication MFAPSDE_OpFw Boolean Operate in forward direction MFAPSDE_OpRe Boolean Operate in reverse direction Section 6 1MRS757488 H ...

Page 143: ...lay Time 0 60000 ms 1 500 Reset delay time Start Delay Time 30 60000 ms 1 30 Start delay time Min Forward Operate Current 1 0 20 0 A 0 1 1 Minimum operate current in forward direction Min Reverse Operate Current 1 0 20 0 A 0 1 1 Minimum operate current in reverse direction Table 80 MFAPSDE Technical data Characteristic Value Operation accuracy At frequency f fn 5 in the range of 480 V 9 6 kV 0 5 i...

Page 144: ...e for 1 second for the phases defined under Alive Phase Supervision the PHSVPR_ULive output activates indicating the voltage presence Similarly if the measured phase to earth voltage remains below the set Voltage Dead Value for 1 second for the phases defined under Dead Phase Supervision the PHSVPR_UDead output activates indicating voltage absence However if the phase to earth voltage for the phas...

Page 145: ...nce detection Voltage Dead Value 300 25000 V 1 300 Limit for phase to neutral voltage absence detection Table 83 PHSVPR Technical data Characteristic Value Operation accuracy At frequency f fn 5 in the range of 480 V 9 6 kV 0 5 in the range of 9 6 28 8 kV 6 1 6 7 Negative sequence overcurrent indication NSPTOC Identification Description IEC 61850 identification IEC 60617 identification ANSI IEEE C...

Page 146: ... module diagram Level detector The measured negative sequence current is compared to the set Start Value If the measured value exceeds the set Start Value Level detector activates the Timer module Timer Once activated Timer activates the NSPTOC_Start output When the operation time has reached the value of Operate Delay Time the NSPTOC_Oper output is activated Signals Table 84 NSPTOC Input signals ...

Page 147: ...ailure supervision SEQSPVC FUSEF 60 Functionality The fuse failure supervision function SEQSPVC is used to block the voltage measuring functions when failure occurs in the secondary circuits between the voltage transformer or combi sensor or voltage sensor and the protection relay to avoid malfunctions of the voltage protection functions SEQSPVC has two algorithms a negative sequence based algorit...

Page 148: ...makes a phase specific comparison between each voltage input and the Seal in Voltage setting If the input voltage is lower than the setting the corresponding phase is reported to the Decision logic module Current and voltage delta criterion The delta function can be activated by setting the Change Rate Enable parameter to True Once the function is activated it operates in parallel with the negativ...

Page 149: ...proper operation of SEQSPVC with an open breaker If this is considered to be an important disadvantage the FF_CBCLOSED input is to be connected to FALSE In this way only the second criterion can activate the delta function The second condition requires the delta criterion to be fulfilled in one phase together with a high current for the same phase The measured phase current is used to reduce the r...

Page 150: ...nected through a protection relay binary input to the N C auxiliary contact of the line disconnector The FF_DISCONOPEN signal sets the FUSEF_U output signal to block the voltage related functions when the line disconnector is in the open state It is recommended to always set Enable Seal in to True This secures that the blocked protection functions remain blocked until normal voltage conditions are...

Page 151: ...nge based function Min Op Voltage Delta 300 10000 V 5 7500 Minimum operate level of phase voltage for delta calculation Min Op Current Delta 4 1000 A 1 40 Minimum operate level of phase current for delta calculation Seal in Voltage 300 10000 V 5 7500 Operate level of seal in phase voltage Enable Seal In FALSE TRUE FALSE Enabling seal in functionality Current Dead Lin Val 4 1000 A 1 20 Operate leve...

Page 152: ...fundamental frequency current I_1H exceeds the set value 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 and Off The operation of INRPHAR can be described with a module diagram All modules in the diagram are explained in the next sections BLK2H I_2H_A...

Page 153: ...e BLK2H output is activated After the timer has elapsed and the inrush situation still exists the BLK2H signal remains active until the I_2H I_1H ratio drops below the value set for the ratio in all phases that is until the inrush situation is over Signals Table 93 INRPHAR Input signals Name Type Default Description I_2H_A SIGNAL 0 Second harmonic phase A current I_1H_A SIGNAL 0 Fundamental freque...

Page 154: ... data can be corrupted in the non volatile memory of the SIM8F module This leads to the loss of stored information All time related information used for statistics is lost and statistics calculation restarts To avert the loss of data the UPS power failure output signal from UPS should be connected to any one of the DIM8H L input channels or the subscribed Boolean GOOSE data set element can be used...

Page 155: ...r name Range Unit Step Default Description Frequency 50 60 Hz 50 Hz Rated system frequency Nominal current 80 630 A 1 400 Nominal phase current Rated sensor current 80 250 A 80 Rated primary current of sensor Io signal sel Calculated Io Measured Io Calculated Io Selection used for Io signal Phase Rotation ABC ACB ABC Phase rotation order Sensor Correction Factors Table continues on next page 1MRS7...

Page 156: ...ase C Residual Current Amplitude 0 7000 1 3000 0 0001 1 Amplitude correction factor for current sensor residual Current Phase 3 0000 3 0000 deg 0 0003 0 Phase correction factor for current sensor residual LED reset time delay 1 1440 min 1 60 LEDs Reset delay time incase no external signal received for resetting This is applicable to OC fault detection EF Protection LEDs Fault Indication Reset Meth...

Page 157: ...ctions Three phase non directional overcurrent fault detection PHPTOC PHPTOC 3I 51P Non directional earth fault detection EFPTOC EFPTOC I0 51N Negative sequence overcurrent protection NSPTOC NSPTOC I2 46 Three phase inrush detector INRPHAR INRPHAR 3I2f 68 Fault passage indicator FPIPTOC FPIPTOC 6 1 7 2 Measurement functions Three phase current measurement CMMXU See Measurement functions Residual c...

Page 158: ... fault type continuous transient or intermittent or fault resistance value low or high er ohmic FPIPTOC is based only on phase current measurements thus it is applicable in cases where voltage measurements are not available Current measurement can be done with conventional current transformers CTs or with sensors Rogowski coils Accurate and reliable fault location information is the key for effect...

Page 159: ...ce current component due to earth fault is used phase A as reference a cos 120o j sin 120o phase rotation A B C Estimated fundamental frequency earth fault current amplitude can be derived from phase currents as IEF 3 I2 IA a2 IB a IC IEF abs IEF where I2 Negative sequence current phasor Earth fault detection is based on monitoring the amplitude of residual current Io and earth fault current IEF a...

Page 160: ...etected by the General fault criterion module calculation of delta quantities for residual current and earth fault current is conducted Calculation of change in the amplitude of residual current ΔIo and in the earth fault current ΔIF due to earth fault is done by comparing the present value of residual current phasor Io and earth fault current phasor IF to value Revert Time earlier and calculating...

Page 161: ...E_FLT change of phase A current phasor due to earth fault ΔIB IB tFLT IB tPRE_FLT change of phase B current phasor due to earth fault ΔIC IC tFLT IC tPRE_FLT change of phase C current phasor due to earth fault Faulted phase is identified by comparing the magnitudes of Equations 20 22 If Equation 20 has a minimum value the faulted phase is A If Equation 21 has a minimum value the faulted phase is B...

Page 162: ... demonstrated in Figure 85 and Figure 86 The main advantage of the CPS method is that it can estimate stable magnitude and phase angle also during intermittent or re striking earth faults Accumulation of phasors is started when the presence of an earth fault in the network is confirmed and accumulation of phasors is reset when the fault condition is over and afterReset Delay Time has elapsed Fault...

Page 163: ...IC IC tFLT IC tPRE_FLT change of phase C current phasor due to earth fault Actual implementation uses CPS calculation Accumulation of phasors is started when the presence of earth fault in the network is confirmed and accumulation of phasors is reset when fault condition is over and after Reset Delay Time has elapsed The indication of fault passage is declared when the maximum phase angle is above...

Page 164: ...tions 23 25 and ΔIEF ΔIo ratio of Equation 26 are shown GUID D67DCE74 A2C9 457D B0B8 9139214C1C75 V1 EN Figure 86 Re striking phase C to earth fault current flowing through the measuring point of FPIPTOC in a compensated network In Figure 86 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 of Equ...

Page 165: ...F to Res Cur is 0 2 When all conditions for detection of fault passage are fulfilled then FPIPTOC functions starts This is indicated by activation of FPIPTOC_Start output The FPIPTOC_Oper output is activated when Operate Delay Time has elapsed The FPIPTOC_ Start signal is prolonged with setting Reset Delay Time Proper setting is 350 500 ms In order to prevent unwanted function reset between the cu...

Page 166: ... threshold EF Start Cur 1 100 A 1 4 Earth fault current start threshold Inst Start Cur 10 100 A 1 50 Earth fault current threshold for instantaneous start condition Angle Sector 10 90 Deg 1 15 Phase angle sector boundary threshold for fault passage Operate Delay Time 100 60000 ms 10 500 Operate delay time Ratio EF to Res Cur 0 1 1 0 0 1 0 1 Ratio earth fault current to residual current Start Delay...

Page 167: ...witches or two position switches of for example gas insulated switchgears which requires a so called 4 4H bridge in order to turn a DC motor in both directions 6 1 8 1 Functions available in SCM Table 103 Functions available in SCM Function IEC 61850 IEC 60617 IEC ANSI Edition 1 Edition 2 Supervision function Trip circuit supervision TCSHSCBR TCSLSCBR TCSHSCBR TCSLSCBR TCS TCM 6 1 8 2 Three positi...

Page 168: ...ose time out 0 32000 ms 25000 Maximal time from Disconnector opened to Disconnector closed Disconnector open time out 0 32000 ms 25000 Maximal time from Disconnector closed to Disconnector opened CB parameters Trip coil pulse time 1 500 ms 100 Pulse time for trip coil Pulse ends if start position leaved or end position reached Closing coil pulse time 1 500 ms 100 Pulse time for closing coil Pulse ...

Page 169: ... Inverted channel 4 input type non inverted inverted Output channels Description High speed output 1 4 User defined channel name not exceeding 30 characters Interlocking rules for motor driven switch earthing switch disconnector When configured for motor driven switch control the smart control module runs on different interlocking rules which helps the switchgear to function safely It checks diffe...

Page 170: ...ion Stop motor immediately Interlocking rules for circuit breaker control Smart control module configured for a circuit breaker application controls two double poled coils The circuit breaker interlocking has to be realized inside the belonging protection and control device Table 106 Interlocking rules for circuit breaker control Operation Position of switch Allowed state CB Open Circuit breaker r...

Page 171: ... reflect the physical input signal present on the binary input terminal Oscillation suppression Oscillation suppression is used to reduce the load from the system when a binary input starts oscillating A binary input is regarded as oscillating if the number of valid state changes number of events after filtering during configured time period as per oscillation time parameter is equal to or greater...

Page 172: ...mit Oscillation suppression hysteresis 1 62 Counts 62 This parameter is the oscillation suppression hysteresis The parameter value acts as the count for hysteresis Oscillation time 0 4095 ms 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 Description Digit...

Page 173: ...inverted inverted Non inverted Output channel 4 non inverted inverted 6 1 8 4 Trip circuit supervision TCSHSCBR TCSLSCBR Identification Description IEC 61850 identification IEC 60617 identification ANSI IEEE C37 2 device number Trip circuit supervision TCSHSCBR TCSLSCBR TCS TCM Functionality The trip circuit supervision function TCSHSCBR TCSLSCBR supervises the control circuit of the circuit break...

Page 174: ...is activated If the reset timer reaches the value set by Reset Delay Time the operation timer resets and the TCSLSCBR_ALR output is deactivated TCSHSCBR is available for high voltage circuit breaker and TCSLSCBR for low voltage circuit breaker configuration Signals Table 108 TCSHSCBR Output signals Name Type Description TCSHSCBR_ALR Boolean Alarm output Table 109 TCSLSCBR Output signals Name Type ...

Page 175: ... received data Off Off Operate On Off Not operate Off On Not operate On On Operate When RIO600 is in the test mode the Ready LED of the LECM module flashes RIO600 does not support Simulation mode of IEC61850 Edition 2 6 3 Channel output value handling The channel values of the binary output modules follow the value in the subscribed GOOSE message if the output is connected to the subscribed data I...

Page 176: ...operations Binary Modbus read operations NO YES YES YES YES YES Remote NO YES YES YES YES YES Local NO YES NO YES NO YES YES YES YES YES N A N A Remote YES YES YES YES N A N A Local YES YES NO YES N A N A 6 5 Time synchronization RIO600 can be synchronized to an NTP time server or the time synchronization can be achieved using Modbus TCP client Time synchronization is used to synchronize the devic...

Page 177: ...us client should send an unsigned 16 bit value range for setting the time value Modbus time synchronization can be used only if it is enabled in Parameter Setting through the configuration and the time synchronization source is made as Modbus or an exception code 4 is sent The time synchronization registers can only be written with data within the valid range of each parameter In case the data to ...

Page 178: ...ceiving 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 In case of SIM8F the metering values are sent over GOOSE based on the set parameter Update interval for Metering values Section 6 1MRS757488 H Commissioning 170 RIO600 Installation and Commission...

Page 179: ...rver is activated by setting the Modbus operation parameter to ON and selecting Write to IED in PCM600 Modbus TCP can be used in parallel with the IEC 61850 GOOSE 7 1 2 Protocol server attachment to a client After protocol activation RIO600 should be connected to the intended client When the client makes a TCP connection its IP address is checked Protocol reservation is given to the client with th...

Page 180: ...s a TCP socket disconnection or if the live TCP socket connection times out 7 1 5 Common Modbus TCP IP diagnostic counters Table 116 TCP IP diagnostic counters client independent Counter Description CnReject No sockets Amount of connection requests rejected due to unavailable TCP sockets CnReject Not reg Amount of connection requests rejected since the client is not registered 7 1 6 Supported Modb...

Page 181: ...ta should be used by an application 7 1 8 Change events and time synchronization The Modbus standard does not define event reporting or time synchronization procedures Proprietary solutions are introduced in RIO600 to support these functionalities and are depicted later in this document 7 1 9 Control operations The Modbus standard defines data types 0X for coils and 4X for holding registers to be ...

Page 182: ...ead either from the 3X or the 4X area In this case the bit values are packed into 16 bit 3X and 4X registers Controls and set points are mapped to Modbus 0X data coils Only one coil can be operated at a time Some control bits are packed bits in the 4X control register structures 7 1 15 Digital input data As the indication signals related to fault detection applications often change rapidly the Mod...

Page 183: ...e Modbus stack needs to scale these values to integer format Thus a scale factor always exists for each Modbus register value and the same is mentioned against each Modbus addressable data point in the Modbus point list manual 7 1 17 Register value update The Modbus register values can be updated in different ways The update method is predefined and fixed The Modbus register values are available s...

Page 184: ...and types are stated in the Modbus memory map list 7 1 20 Control operations RIO600 outputs can be controlled either through the 0X coil objects or 4X holding register control structures See the Modbus control objects memory map for the available control objects The control objects in RIO600 are single point control objects Single point control objects can be either pulse outputs or persistent out...

Page 185: ...w of the RIO600 health Table 119 System status register 1 Device health status Bit Value Description 0 0 Healthy 1 Warning or error LECM warning 1 0 Healthy 1 Warning or error LECM error 2 0 Healthy 1 Warning or error Module 1 health 3 0 Healthy 1 Warning or error Module 2 health 4 0 Healthy 1 Warning or error Module 3 health 5 0 Healthy 1 Warning or error Module 4 health 6 0 Healthy 1 Warning or ...

Page 186: ...fication address range For example in a RIO600 stack with the configuration LECM DIM8H DIM8L DOM4 RTD4 the addresses 16 17 18 19 and 20 show the values 76 67 67 66 and 68 respectively 7 1 25 Modbus time synchronization RIO600 s internal UTC time structure can be synchronized using the Modbus time synch implementation For this Synch source should be set as Modbus in the parameter settings for LECM ...

Page 187: ...onisation Hour 1 Unsigned 16 0 23 12 Time synchronisation Minute 1 Unsigned 16 0 59 13 Time synchronisation Seconds 1 Unsigned 16 0 59 7 1 26 Parameter settings Modbus communication needs to be enabled via the PCM600 path Configuration Station communication MODBUS The station communication parameters need to be set to use Modbus communication in RIO600 Table 122 Station communication parameters fo...

Page 188: ...Modbus slave does not respond to the Modbus master s poll request even if it is in connected state with the master For the RIO600 Modbus slave to respond to a master s request the IP addresses of both the master and the slave ID must be the same as configured in PCM600 or RIO600 must be configured with a zero IP address default IP address and the slave ID should be the same as configured in PCM600...

Page 189: ...code 4 If the analog output write is set to Not Allowed and the Modbus master tries to write a value to either AOM channels this results in exception code 4 If the time synch source is not selected as Modbus and the Modbus master tries to write a value to the time registers an exception code 4 is sent from the RIO600 Modbus slave to the Modbus master 7 1 27 Module reserved channel concept Keeping ...

Page 190: ...rrelation between the function code and address range Module name Data type 0X 1X 3X 4X Readable FC 01 Writeable FC 05 Readable FC 02 Writeable Readable FC 04 Writeable Readable FC 03 Writeable FC 06 DOM4 Boolean Yes Yes No No Yes No Yes Yes DIM8H DIM8L Boolean No No Yes No Yes No Yes No RTD4 Signed 16 bit channel status informatio n No No No No Yes No Yes No Channel range informatio n unsigned 16...

Page 191: ...s No Yes No RTD4 Signed 16 bit channel status information No No No No Yes No Yes No Channel range information unsigned 16 No No No No Yes No Yes No AOM4 Signed 16 bit channel status information No No No No Yes No Yes Yes SIM8F SIM4F Readable data Boolean No No Yes No Yes No Yes No Writeable data Boolean Yes Yes No No Yes No Yes Yes Signed 32 bit Analog data and Signed 16 bit enum No No No No Yes N...

Page 192: ...gular Modbus data addresses should be incremented by one Modbus point list can be exported from the connectivity package 7 2 1 SSR1 System status register 1 device health System status register address provides information about the health status of the RIO600 system and all individual modules present in its stack It also provides status of the UPS power failure and local remote mode Table 126 SSR...

Page 193: ...e alive register This register provides information about the Modbus device alive counter Table 127 SSR2 System status register 2 device alive register Reg A Type Scale IEC 61850 name SA name Description Values 1 u16 1 Device Alive Counter 0 65535 7 2 3 Time synchronization RIO600 time can be synchronized with the Modbus client by writing to the register addresses in Table 20 The time can also be ...

Page 194: ... addresses corresponding to the module identification address range 7 2 5 LD0 DIM8GGIO LD0 DIM8LGGIO physical I O states Status of binary input information can be accessed using the following addresses of DIM8H DIM8L module Table 130 LD0 DIM8GGIO LD0 DIM8LGGIO physical I O states Bit A Reg A IEC 61850 name SA name Description Values LD0 DIM8GGIO1 LD0 DIM8LGGIO1 0 32 00 Ind1 stVal DIM8H 1 Input 1 S...

Page 195: ...7 33 11 reserved reserved 0 Off 28 33 12 reserved reserved 0 Off 29 33 13 reserved reserved 0 Off 30 33 14 reserved reserved 0 Off 31 33 15 reserved reserved 0 Off LD0 DIM8GGIO3 LD0 DIM8LGGIO3 32 34 00 Ind1 stVal DIM8H 3 Input 1 State 0 1 Off On 33 34 01 Ind2 stVal DIM8H 3 Input 2 State 0 1 Off On 34 34 02 Ind3 stVal DIM8H 3 Input 3 State 0 1 Off On 35 34 03 Ind4 stVal DIM8H 3 Input 4 State 0 1 Of...

Page 196: ...nd1 stVal DIM8H 5 Input 1 State 0 1 Off On 65 36 01 Ind2 stVal DIM8H 5 Input 2 State 0 1 Off On 66 36 02 Ind3 stVal DIM8H 5 Input 3 State 0 1 Off On 67 36 03 Ind4 stVal DIM8H 5 Input 4 State 0 1 Off On 68 36 04 Ind5 stVal DIM8H 5 Input 5 State 0 1 Off On 69 36 05 Ind6 stVal DIM8H 5 Input 6 State 0 1 Off On 70 36 06 Ind7 stVal DIM8H 5 Input 7 State 0 1 Off On 71 36 07 Ind8 stVal DIM8H 5 Input 8 Sta...

Page 197: ...On 100 38 04 Ind5 stVal DIM8H 7 Input 5 State 0 1 Off On 101 38 05 Ind6 stVal DIM8H 7 Input 6 State 0 1 Off On 102 38 06 Ind7 stVal DIM8H 7 Input 7 State 0 1 Off On 103 38 07 Ind8 stVal DIM8H 7 Input 8 State 0 1 Off On 104 38 08 reserved reserved 0 Off 105 38 09 reserved reserved 0 Off 106 38 10 reserved reserved 0 Off 107 38 11 reserved reserved 0 Off 108 38 12 reserved reserved 0 Off 109 38 13 r...

Page 198: ...al DIM8H 9 Input 8 State 0 1 Off On 136 40 08 reserved reserved 0 Off 137 40 09 reserved reserved 0 Off 138 40 10 reserved reserved 0 Off 139 40 11 reserved reserved 0 Off 140 40 12 reserved reserved 0 Off 141 40 13 reserved reserved 0 Off 142 40 14 reserved reserved 0 Off 143 40 15 reserved reserved 0 Off LD0 DIM8GGIO10 LD0 DIM8LGGIO10 144 41 00 Ind1 stVal DIM8H 10 Input 1 State 0 1 Off On 145 41...

Page 199: ... Off 261 48 05 reserved reserved 0 Off 262 48 06 reserved reserved 0 Off 263 48 07 reserved reserved 0 Off 264 48 08 reserved reserved 0 Off 265 48 09 reserved reserved 0 Off 266 48 10 reserved reserved 0 Off 267 48 11 reserved reserved 0 Off 268 48 12 reserved reserved 0 Off 269 48 13 reserved reserved 0 Off 270 48 14 reserved reserved 0 Off 271 48 15 reserved reserved 0 Off LD0 DOMGGIO2 272 49 0...

Page 200: ...eserved 0 Off 298 50 10 reserved reserved 0 Off 299 50 11 reserved reserved 0 Off 300 50 12 reserved reserved 0 Off 301 50 13 reserved reserved 0 Off 302 50 14 reserved reserved 0 Off 303 50 15 reserved reserved 0 Off LD0 DOMGGIO4 304 51 00 SPCSO1 stVal DOM 4 Output 1 State 0 1 Off On 305 51 01 SPCSO2 stVal DOM 4 Output 2 State 0 1 Off On 306 51 02 SPCSO3 stVal DOM 4 Output 3 State 0 1 Off On 307 ...

Page 201: ...Off 335 52 15 reserved reserved 0 Off LD0 DOMGGIO6 336 53 00 SPCSO1 stVal DOM 6 Output 1 State 0 1 Off On 337 53 01 SPCSO2 stVal DOM 6 Output 2 State 0 1 Off On 338 53 02 SPCSO3 stVal DOM 6 Output 3 State 0 1 Off On 339 53 03 SPCSO4 stVal DOM 6 Output 4 State 0 1 Off On 340 53 04 reserved reserved 0 Off 341 53 05 reserved reserved 0 Off 342 53 06 reserved reserved 0 Off 343 53 07 reserved reserved...

Page 202: ...te 0 1 Off On 371 55 03 SPCSO4 stVal DOM 8 Output 4 State 0 1 Off On 372 55 04 reserved reserved 0 Off 373 55 05 reserved reserved 0 Off 374 55 06 reserved reserved 0 Off 375 55 07 reserved reserved 0 Off 376 55 08 reserved reserved 0 Off 377 55 09 reserved reserved 0 Off 378 55 10 reserved reserved 0 Off 379 55 11 reserved reserved 0 Off 380 55 12 reserved reserved 0 Off 381 55 13 reserved reserv...

Page 203: ...l DOM 10 Output 3 State 0 1 Off On 403 57 03 SPCSO4 stVal DOM 10 Output 4 State 0 1 Off On 404 57 04 reserved reserved 0 Off 405 57 05 reserved reserved 0 Off 406 57 06 reserved reserved 0 Off 407 57 07 reserved reserved 0 Off 408 57 08 reserved reserved 0 Off 409 57 09 reserved reserved 0 Off 410 57 10 reserved reserved 0 Off 411 57 11 reserved reserved 0 Off 412 57 12 reserved reserved 0 Off 413...

Page 204: ...Low 2 High High 3 Low Low 4 73 AnIn3 range An In4 range RTD 1 Channel Range Information Channel 4 High Byte Channel 3 Low Byte Normal 0 High 1 Low 2 High High 3 Low Low 4 74 reserved reserved 0 75 reserved reserved 0 76 reserved reserved 0 77 reserved reserved 0 78 reserved reserved 0 79 reserved reserved 0 LD0 RTDGGIO2 80 Value reported with a scale factor of 1 when channel configured as dimensio...

Page 205: ... 10000 100001 97 AnIn2 mag f RTD 3 Channel 2 Input Value 40 200 C 0 0 20 0 mA 10000 100001 98 AnIn3 mag f RTD 3 Channel 3 Input Value 40 200 C 0 0 20 0 mA 10000 100001 99 AnIn4 mag f RTD 3 Channel 4 Input Value 40 200 C 0 0 20 0 mA 10000 100001 100 reserved reserved 0 101 reserved reserved 0 102 reserved reserved 0 103 reserved reserved 0 104 AnIn1 range An In2 range RTD 3 Channel Range Informatio...

Page 206: ...nel 3 Low Byte Normal 0 High 1 Low 2 High High 3 Low Low 4 122 reserved reserved 0 123 reserved reserved 0 124 reserved reserved 0 125 reserved reserved 0 126 reserved reserved 0 127 reserved reserved 0 LD0 RTDGGIO5 128 Value reported with a scale factor of 1 when channel configured as dimensionless and with a scale factor of 100 when channel configured as either mA or RTD AnIn1 mag f RTD 5 Channe...

Page 207: ...0 20 0 mA 10000 100001 146 AnIn3 mag f RTD 6 Channel 3 Input Value 40 200 C 0 0 20 0 mA 10000 100001 147 AnIn4 mag f RTD 6 Channel 4 Input Value 40 200 C 0 0 20 0 mA 10000 100001 148 reserved reserved 0 149 reserved reserved 0 150 reserved reserved 0 151 reserved reserved 0 152 AnIn1 range An In2 range RTD 6 Channel Range Information Channel 2 High Byte Channel 1 Low Byte Normal 0 High 1 Low 2 Hig...

Page 208: ...nel 3 Low Byte Normal 0 High 1 Low 2 High High 3 Low Low 4 170 reserved reserved 0 171 reserved reserved 0 172 reserved reserved 0 173 reserved reserved 0 174 reserved reserved 0 175 reserved reserved 0 LD0 RTDGGIO8 176 Value reported with a scale factor of 1 when channel configured as dimensionless and with a scale factor of 100 when channel configured as either mA or RTD AnIn1 mag f RTD 8 Channe...

Page 209: ... 20 0 mA 10000 100001 194 AnIn3 mag f RTD 9 Channel 3 Input Value 40 200 C 0 0 20 0 mA 10000 100001 195 AnIn4 mag f RTD 9 Channel 4 Input Value 40 200 C 0 0 20 0 mA 10000 100001 196 reserved reserved 0 197 reserved reserved 0 198 reserved reserved 0 199 reserved reserved 0 200 AnIn1 range An In2 range RTD 9 Channel Range Information Channel 2 High Byte Channel 1 Low Byte Normal 0 High 1 Low 2 High...

Page 210: ...3 reserved reserved 0 214 reserved reserved 0 215 reserved reserved 0 216 AnIn1 range An In2 range RTD 10 Channel Range Information Channel 2 High Byte Channel 1 Low Byte Normal 0 High 1 Low 2 High High 3 Low Low 4 217 AnIn3 range An In4 range RTD 10 Channel Range Information Channel 4 High Byte Channel 3 Low Byte Normal 0 High 1 Low 2 High High 3 Low Low 4 218 reserved reserved 0 219 reserved res...

Page 211: ...ge AnIn4 range RTD Channel Range Information Channel 4 High Byte Channel 3 Low Byte LD0 RTDGGIO3 RTD 3 720 u16 1 AnIn1 range AnIn2 range RTD Channel Range Information Channel 2 High Byte Channel 1 Low Byte Normal 0 High 1 Low 2 High High 3 Low Low 4 721 u16 1 AnIn3 range AnIn4 range RTD Channel Range Information Channel 4 High Byte Channel 3 Low Byte LD0 RTDGGIO4 RTD 4 728 u16 1 AnIn1 range AnIn2 ...

Page 212: ...ormation Channel 4 High Byte Channel 3 Low Byte LD0 RTDGGIO7 RTD 7 752 u16 1 AnIn1 range AnIn2 range RTD Channel Range Information Channel 2 High Byte Channel 1 Low Byte Normal 0 High 1 Low 2 High High 3 Low Low 4 753 u16 1 AnIn3 range AnIn4 range RTD Channel Range Information Channel 4 High Byte Channel 3 Low Byte LD0 RTDGGIO8 RTD 8 760 u16 1 AnIn1 range AnIn2 range RTD Channel Range Information ...

Page 213: ... A Scale IEC 61850 name SA name Description Values LD0 AOMGGIO1 16 bit signed Integer 224 Value reported with a scale factor of 1 when channel configured as dimensionless and with a scale factor of 100 when channel configured as mA AnOut1 mxVal f AOM 1 Channel 1 Output Value 0 0 20 0 mA 32768 327681 225 AnOut2 mxVal f AOM 1 Channel 2 Output Value 0 0 20 0 mA 32768 327681 226 AnOut3 mxVal f AOM 1 C...

Page 214: ...erved reserved 0 253 reserved reserved 0 254 reserved reserved 0 255 reserved reserved 0 LD0 AOMGGIO3 256 Value reported with a scale factor of 1 when channel configured as dimensionless and with a scale factor of 100 when channel configured as mA AnOut1 mxVal f AOM 3 Channel 1 Output Value 0 0 20 0 mA 32768 327681 257 AnOut2 mxVal f AOM 3 Channel 2 Output Value 0 0 20 0 mA 32768 327681 258 AnOut3...

Page 215: ...reserved reserved 0 285 reserved reserved 0 286 reserved reserved 0 287 reserved reserved 0 1 As per user configuration 7 2 10 LD0 PHPTOC phase overcurrent fault detection Table 135 LD0 PHPTOC phase overcurrent fault detection Bit A Reg A IEC 61850 name SA name Description Values LD0 PHPTOC1 SIM8F 1 SIM4F 1 516 384 04 Str general START General Start 1 Start 517 384 05 Str phsA Phase A Start 1 Star...

Page 216: ... Operate 1 Operate LD0 PHPTOC4 SIM8F 4 SIM4F 4 676 802 04 Str general START General Start 1 Start 677 802 05 Str phsA Phase A Start 1 Start 678 802 06 Str phsB Phase B Start 1 Start 679 802 07 Str phsC Phase C Start 1 Start 680 802 08 Op general Operate General Operate 1 Operate 681 802 09 Op phsA Phase A Operate 1 Operate 682 802 10 Op phsB Phase B Operate 1 Operate 683 802 11 Op phsC Phase C Ope...

Page 217: ...art 1 Start 559 386 15 Str phsC Phase C Start 1 Start 560 387 00 Op general Operate General Operate 1 Operate 561 387 01 Op phsA Phase A Operate 1 Operate 562 387 02 Op phsB Phase B Operate 1 Operate 563 387 03 Op phsC Phase C Operate 1 Operate 570 387 10 OpFwd general Forward Operate 1 Operate 571 387 11 OpRev general Reverse Operate 1 Operate LD0 DPHPTOC3 SIM8F 3 652 800 12 Str general START Gen...

Page 218: ...1 Operate 721 805 01 Op phsA Phase A Operate 1 Operate 722 805 02 Op phsB Phase B Operate 1 Operate 723 805 03 Op phsC Phase C Operate 1 Operate 730 805 10 OpFwd general Forward Operate 1 Operate 731 805 11 OpRev general Reverse Operate 1 Operate 7 2 12 LD0 CMHAI current total demand distortion Table 137 LD0 CMHAI current total demand distortion Bit A Reg A IEC 61850 name SA name Description Value...

Page 219: ...C 61850 name SA name Description Values LD0 EFPTOC1 SIM8F 1 SIM4F 1 534 385 06 Str general START General Start 1 Start 535 385 07 Op general Operate General Operate 1 Operate LD0 EFPTOC2 SIM8F 2 SIM4F 2 566 387 06 Str general START General Start 1 Start 567 387 07 Op general Operate General Operate 1 Operate LD0 EFPTOC3 SIM8F 3 SIM4F 3 662 801 06 Str general START General Start 1 Start 663 801 07 ...

Page 220: ...669 801 13 OpRev general Reverse Operate 1 Operate LD0 DEFPTOC4 SIM8F 4 696 803 08 Str general START General Start 1 Start 697 803 09 Op general Operate General Operate 1 Operate 700 803 12 OpFwd general Forward Operate 1 Operate 701 803 13 OpRev general Reverse Operate 1 Operate LD0 DEFPTOC5 SIM8F 5 728 805 08 Str general START General Start 1 Start 729 805 09 Op general Operate General Operate 1...

Page 221: ...0 03 ItmEFInd stVal Intermittent Earth Fault Indication 1 Fault 804 810 04 OpFwd general Forward Operate 1 operate 805 810 05 OpRev general Reverse Operate 1 operate LD0 MFAPSDE4 SIM8F 4 832 812 Str general Start General Start 1 Start 833 812 01 Op general Operate General Operate 1 Operate 834 812 02 RevEF stVal Reverse Earth Fault 1 Fault 835 812 03 ItmEFInd stVal Intermittent Earth Fault Indicat...

Page 222: ...ication For Voltage Not Presence 1 Non Presence LD0 PHSVPR5 SIM8F 5 872 814 08 VLiv stVal Indication For Voltage Presence 1 Presence 873 814 09 VDea stVal Indication For Voltage Not Presence 1 Non Presence 7 2 18 LD0 NSPTOC negative sequence overcurrent fault detection Table 143 LD0 NSPTOC negative sequence overcurrent fault detection Bit A Reg A IEC 61850 name SA name Description Values LD0 NSPTO...

Page 223: ...perate 1 Operate LD0 FPIPTOC3 SIM4F 3 818 811 02 Str general START General Start 1 Start 819 811 03 Op general Operate General Operate 1 Operate LD0 FPIPTOC4 SIM4F 4 850 813 02 Str general START General Start 1 Start 851 813 03 Op general Operate General Operate 1 Operate LD0 FPIPTOC5 SIM4F 5 882 815 02 Str general START General Start 1 Start 883 815 03 Op general Operate General Operate 1 Operate...

Page 224: ... Start 1 Start LD0 INRPHAR5 SIM8F 5 SIM4F 5 886 815 06 Str general START General Start 1 Start 7 2 22 Binary writable signals for SIM8F Table 147 Binary writable signals for SIM8F Bit A Reg A IEC 61850 name SA name Description Values SIM8F 1 576 391 Reset Fault Indicator 1 Reset 577 391 01 Reset Energy Counter 1 Reset 578 391 02 Update Statistics 1 Update statistics SIM8F 2 592 392 Reset Fault Ind...

Page 225: ...istics 7 2 23 Binary writable signals for SIM4F Table 148 Binary writable signals for SIM4F Bit A Reg A IEC 61850 name SA name Description Values SIM4F 1 576 391 Reset Fault Indicator 1 Reset SIM4F 2 592 392 Reset Fault Indicator 1 Reset SIM4F 3 896 816 Reset Fault Indicator 1 Reset SIM4F 4 912 817 Reset Fault Indicator 1 Reset SIM4F 5 928 818 Reset Fault Indicator 1 Reset 1MRS757488 H Section 7 M...

Page 226: ...ad Flow Direction LD0 PWRRDIR3 SIM8F 3 864 u16 1 Dir dirgeneral General Load Flow Direction 865 u16 1 Dir dirphsA Phase A Per Phase Load Flow Direction 866 u16 1 Dir dirphsB Phase B Per Phase Load Flow Direction 867 u16 1 Dir dirphsC Phase C Per Phase Load Flow Direction LD0 PWRRDIR4 SIM8F 4 996 u16 1 Dir dirgeneral General Load Flow Direction 997 u16 1 Dir dirphsA Phase A Per Phase Load Flow Dire...

Page 227: ... Str dirphsB Phase B Start 539 u16 1 Str dirphsC Phase C Start LD0 PHPTOC3 SIM8F 3 SIM4F 3 868 u16 1 Str dirgeneral General Start 869 u16 1 Str dirphsA Phase A Start 870 u16 1 Str dirphsB Phase B Start 871 u16 1 Str dirphsC Phase C Start LD0 PHPTOC4 SIM8F 4 SIM4F 4 1000 u16 1 Str dirgeneral General Start 1001 u16 1 Str dirphsA Phase A Start 1002 u16 1 Str dirphsB Phase B Start 1003 u16 1 Str dirph...

Page 228: ...hase A Start 542 u16 1 Str dirphsB Phase B Start 543 u16 1 Str dirphsC Phase C Start LD0 DPHPTOC3 SIM8F 3 872 u16 1 Str dirgeneral General Start 873 u16 1 Str dirphsA Phase A Start 874 u16 1 Str dirphsB Phase B Start 875 u16 1 Str dirphsC Phase C Start LD0 DPHPTOC4 SIM8F 4 1004 u16 1 Str dirgeneral General Start 1005 u16 1 Str dirphsA Phase A Start 1006 u16 1 Str dirphsB Phase B Start 1007 u16 1 S...

Page 229: ... Type Scale IEC 61850 name SA name Description Values LD0 DEFPTOC1 SIM8F 1 0 unknown 1 forward 2 reverse 3 both 413 u16 1 Str dirgeneral General Start LD0 DEFPTOC2 SIM8F 2 545 u16 1 Str dirgeneral General Start LD0 DEFPTOC3 SIM8F 3 877 u16 1 Str dirgeneral General Start LD0 DEFPTOC4 SIM8F 4 1009 u16 1 Str dirgeneral General Start LD0 DEFPTOC5 SIM8F 5 1141 u16 1 Str dirgeneral General Start 7 2 29 ...

Page 230: ...56 i32 1 A phsC cVal ang f Phase C Current Angle 557 LD0 CMMXU3 SIM8F 3 SIM4F 3 878 i32 10 A phsA cVal mag f Phase A Current Magnitude 879 880 i32 1 A phsA cVal ang f Phase A Current Angle 881 882 i32 10 A phsB cVal mag f Phase B Current Magnitude 883 884 i32 1 A phsB cVal ang f Phase B Current Angle 885 886 i32 10 A phsC cVal mag f Phase C Current Magnitude 887 888 i32 1 A phsC cVal ang f Phase C...

Page 231: ...gle 1149 1150 i32 10 A phsC cVal mag f Phase C Current Magnitude 1151 1152 i32 1 A phsC cVal ang f Phase C Current Angle 1153 7 2 30 LD0 VMMXU voltage measurements Table 155 LD0 VMMXU voltage measurements Reg A Type Scale IEC 61850 name SA name Description Values LD0 VMMXU1 SIM8F 1 426 i32 1 PPV phsAB cVal mag f Vab Magnitude 427 428 i32 1 PPV phsAB cVal ang f Vab Angle 429 430 i32 1 PPV phsBC cVa...

Page 232: ... ang f Vab Angle 561 562 i32 1 PPV phsBC cVal mag f Vbc Magnitude 563 564 i32 1 PPV phsBC cVal ang f Vbc Angle 565 566 i32 1 PPV phsCA cVal mag f Vca Magnitude 567 568 i32 1 PPV phsCA cVal ang f Vca Angle 569 570 i32 1 PhV phsA cVal mag f Phase A Voltage Magnitude 571 572 i32 1 PhV phsA cVal ang f Phase A Voltage Angle 573 574 i32 1 PhV phsB cVal mag f Phase B Voltage Magnitude 575 576 i32 1 PhV p...

Page 233: ... Voltage Magnitude 907 908 i32 1 PhV phsB cVal ang f Phase B Voltage Angle 909 910 i32 1 PhV phsC cVal mag f Phase C Voltage Magnitude 911 912 i32 1 PhV phsC cVal ang f Phase C Voltage Angle 913 LD0 VMMXU4 SIM8F 4 1022 i32 1 PPV phsAB cVal mag f Vab Magnitude 1023 1024 i32 1 PPV phsAB cVal ang f Vab Angle 1025 1026 i32 1 PPV phsBC cVal mag f Vbc Magnitude 1027 1028 i32 1 PPV phsBC cVal ang f Vbc A...

Page 234: ... Angle 1157 1158 i32 1 PPV phsBC cVal mag f Vbc Magnitude 1159 1160 i32 1 PPV phsBC cVal ang f Vbc Angle 1161 1162 i32 1 PPV phsCA cVal mag f Vca Magnitude 1163 1164 i32 1 PPV phsCA cVal ang f Vca Angle 1165 1166 i32 1 PhV phsA cVal mag f Phase A Voltage Magnitude 1167 1168 i32 1 PhV phsA cVal ang f Phase A Voltage Angle 1169 1170 i32 1 PhV phsB cVal mag f Phase B Voltage Magnitude 1171 1172 i32 1...

Page 235: ... cVal mag f Phase C Reactive Power 463 464 i32 1 TotVAr mag f Total Reactive Power 465 466 i32 1 VA phsA cVal mag f Phase A Apparent Power 467 468 i32 1 VA phsB cVal mag f Phase B Apparent Power 469 470 i32 1 VA phsC cVal mag f Phase C Apparent Power 471 472 i32 1 TotVA mag f Total Apparent Power 473 474 i32 100 Hz mag f Frequency 475 476 i32 1000 TotPF mag f Average Power Factor 477 LD0 PEMMXU2 S...

Page 236: ...i32 1 TotVA mag f Total Apparent Power 605 606 i32 100 Hz mag f Frequency 607 608 i32 1000 TotPF mag f Average Power Factor 609 LD0 PEMMXU3 SIM8F 3 914 i32 1 W phsA cVal mag f Phase A Active Power 915 916 i32 1 W phsB cVal mag f Phase B Active Power 917 918 i32 1 W phsC cVal mag f Phase C Active Power 919 920 i32 1 TotW mag f Total Active Power 921 922 i32 1 VAr phsA cVal mag f Phase A Reactive Po...

Page 237: ... phsC cVal mag f Phase C Active Power 1051 1052 i32 1 TotW mag f Total Active Power 1053 1054 i32 1 VAr phsA cVal mag f Phase A Reactive Power 1055 1056 i32 1 VAr phsB cVal mag f Phase B Reactive Power 1057 1058 i32 1 VAr phsC cVal mag f Phase C Reactive Power 1059 1060 i32 1 TotVAr mag f Total Reactive Power 1061 1062 i32 1 VA phsA cVal mag f Phase A Apparent Power 1063 1064 i32 1 VA phsB cVal ma...

Page 238: ... 1 TotVAr mag f Total Reactive Power 1193 1194 i32 1 VA phsA cVal mag f Phase A Apparent Power 1195 1196 i32 1 VA phsB cVal mag f Phase B Apparent Power 1197 1198 i32 1 VA phsC cVal mag f Phase C Apparent Power 1199 1200 i32 1 TotVA mag f Total Apparent Power 1201 1202 i32 100 Hz mag f Frequency 1203 1204 i32 1000 TotPF mag f Average Power Factor 1205 7 2 32 LD0 RESCMMXU residual current measureme...

Page 239: ...le 1077 LD0 RESCMMXU5 SIM8F 5 SIM4F 5 1206 i32 10 A res cVal mag f Residual Current Magnitude 1207 1208 i32 1 A res cVal ang f Residual Current Angle 1209 7 2 33 LD0 RESVMMXU residual voltage measurement Table 158 LD0 RESVMMXU residual voltage measurement Reg A Type Scale IEC 61850 name SA name Description Values LD0 RESVMMXU1 SIM8F 1 482 i32 10 PhV res cVal mag f Residual Voltage Magnitude 483 48...

Page 240: ...le 159 LD0 CAVMMXU average current measurements Reg A Type Scale IEC 61850 name SA name Description Values LD0 CAVMMXU1 SIM8F 1 SIM4F 1 486 i32 10 A phA cVal mag f Phase A Average Operating Current 487 488 i32 10 A phB cVal mag f Phase B Average Operating Current 489 490 i32 10 A phC cVal mag f Phase C Average Operating Current 491 LD0 CAVMMXU2 SIM8F 2 SIM4F 2 618 i32 10 A phA cVal mag f Phase A A...

Page 241: ...F 5 1214 i32 10 A phA cVal mag f Phase A Average Operating Current 1215 1216 i32 10 A phB cVal mag f Phase B Average Operating Current 1217 1218 i32 10 A phC cVal mag f Phase C Average Operating Current 1219 7 2 35 LD0 RCAVMMXU average current measurements Table 160 LD0 RCAVMMXU average current measurements Reg A Type Scale IEC 61850 name SA name Description Values LD0 RCAVMMXU1 SIM8F 1 SIM4F 1 49...

Page 242: ... mag f Phase A Peak Current 495 496 i32 10 A phB cVal mag f Phase B Peak Current 497 498 i32 10 A phC cVal mag f Phase C Peak Current 499 LD0 CMAMMXU2 SIM8F 2 SIM4F 2 626 i32 10 A phA cVal mag f Phase A Peak Current 627 628 i32 10 A phB cVal mag f Phase B Peak Current 629 630 i32 10 A phC cVal mag f Phase C Peak Current 631 LD0 CMAMMXU3 SIM8F 3 SIM4F 3 958 i32 10 A phA cVal mag f Phase A Peak Curr...

Page 243: ...A name Description Values LD0 VAVMMXU1 SIM8F 1 500 i32 1 PhsV phsA cVal mag f Phase A Average Operating Voltage 501 502 i32 1 PhsV phsB cVal mag f Phase B Average Operating Voltage 503 504 i32 1 PhsV phsC cVal mag f Phase C Average Operating Voltage 505 LD0 VAVMMXU2 SIM8F 2 632 i32 1 PhsV phsA cVal mag f Phase A Average Operating Voltage 633 634 i32 1 PhsV phsB cVal mag f Phase B Average Operating...

Page 244: ...rating Voltage 1229 1230 i32 1 PhsV phsB cVal mag f Phase B Average Operating Voltage 1231 1232 i32 1 PhsV phsC cVal mag f Phase C Average Operating Voltage 1233 7 2 38 LD0 VMAMMXU peak voltage measurements Table 163 LD0 VMAMMXU peak voltage measurements Reg A Type Scale IEC 61850 name SA name Description Values LD0 VMAMMXU1 SIM8F 1 506 i32 1 PhsV phsA cVal mag f Phase A Peak Voltage 507 508 i32 1...

Page 245: ...hsV phsC cVal mag f Phase C Peak Voltage 1107 LD0 VMAMMXU5 SIM8F 5 1234 i32 1 PhsV phsA cVal mag f Phase A Peak Voltage 1235 1236 i32 1 PhsV phsB cVal mag f Phase B Peak Voltage 1237 1238 i32 1 PhsV phsC cVal mag f Phase C Peak Voltage 1239 7 2 39 LD0 PEAVMMXU average power measurements Table 164 LD0 PEAVMMXU average power measurements Reg A Type Scale IEC 61850 name SA name Description Values LD0...

Page 246: ...eactive Power 1111 1112 i32 1 TotVA mag f Average Apparent Power 1113 LD0 PEAVMMXU5 SIM8F 5 1240 i32 1 TotW mag f Average Active Power 1241 1242 i32 1 TotVAr mag f Average Reactive Power 1243 1244 i32 1 TotVA mag f Average Apparent Power 1245 7 2 40 LD0 PEMAMMXU peak power measurements Table 165 LD0 PEMAMMXU peak power measurements Reg A Type Scale IEC 61850 name SA name Description Values LD0 PEM...

Page 247: ... 1115 1116 i32 1 TotVAr mag f Peak Reactive Power 1117 1118 i32 1 TotVA mag f Peak Apparent Power 1119 LD0 PEMAMMXU5 SIM8F 5 1246 i32 1 TotW mag f Peak Active Power 1247 1248 i32 1 TotVAr mag f Peak Reactive Power 1249 1250 i32 1 TotVA mag f Peak Apparent Power 1251 7 2 41 LD0 EMMTR energy measurement Table 166 LD0 EMMTR energy measurement Reg A Type Scale IEC 61850 name SA name Description Values...

Page 248: ...ergy Demand 989 990 i32 1 SupWh actVal Real Energy Supply 991 992 i32 1 DmdVArh actVal Reactive Energy Demand 993 994 i32 1 SupVArh actVal Reactive Energy Supply 995 LD0 EMMTR4 SIM8F 4 1120 i32 1 DmdWh actVal Real Energy Demand 1121 1122 i32 1 SupWh actVal Real Energy Supply 1123 1124 i32 1 DmdVArh actVal Reactive Energy Demand 1125 1126 i32 1 SupVArh actVal Reactive Energy Supply 1127 LD0 EMMTR5 ...

Page 249: ... Str dirGeneral General Start LD0 MFAPSDE3 SIM8F 3 1356 u16 1 Str dirGeneral General Start LD0 MFAPSDE4 SIM8F 4 1404 u16 1 Str dirGeneral General Start LD0 MFAPSDE5 SIM8F 5 1452 u16 1 Str dirGeneral General Start 7 2 43 SCM Application types Table 168 IEC 61850 name for SCM application types SCM application type IEC 61850 name Low voltage High voltage Four Input Four Output LD0 SCMLGGIO LD0 SCMHGG...

Page 250: ...DGGIO1 4 LD0 SCMLEGGIO1 LD0 SCMHEGGIO1 5 LD0 SCMLCGGIO1 LD0 SCMHCGGIO1 6 LD0 TCSLSCBR1 LD0 TCSHSCBR1 SCM 1 1664 1516 Ind1 stVal Digital Input Channel 1 0 1 Off On 1665 1516 01 Ind2 stVal Digital Input Channel 2 0 1 Off On 1666 1516 02 Ind3 stVal Digital Input Channel 3 0 1 Off On 1667 1516 03 Ind4 stVal Digital Input Channel 4 0 1 Off On 1668 1516 04 RELEASE_ES Release Earth Switch Information 0 1...

Page 251: ... 1699 1518 03 Ind4 stVal Digital Input Channel 4 0 1 Off On 1700 1518 04 RELEASE_ES Release Earth Switch Information 0 1 Off On 1701 1518 05 RELEASE_DS Release Disconnector Information 0 1 Off On 1702 1518 06 REED_ES REED Earth Switch Information 0 1 Off On 1703 1518 07 RELEASE_CB Release Circuit Breaker Information 0 1 Off On 1704 1518 08 Ind10 stVal Error Code No Fault 0 1 Off On 1705 1518 09 In...

Page 252: ...n 1736 1520 08 Ind10 stVal Error Code No Fault 0 1 Off On 1737 1520 09 Ind11 stVal Error Code Device Error 0 1 Off On 1738 1520 1 Ind12 stVal Error code Release 0 1 Off On 1739 1520 11 Ind13 stVal Error Code No Act 0 1 Off On 1740 1520 12 Ind14 stVal Error Code Interlocking Error 0 1 Off On 1741 1520 13 Ind15 stVal Error Code REED Release Error 0 1 Off On 1742 1520 14 Ind16 stVal Error Code Positi...

Page 253: ...al Error Code REED Release Error 0 1 Off On 1774 1522 14 Ind16 stVal Error Code Position Error 0 1 Off On 1775 1522 15 Ind17 stVal Error Code Time out Error 0 1 Off On 1776 1523 CircAlm stVal Trip Circuit Supervision Alarm Status 0 1 Off On 1777 1523 01 CircAlm stVal Trip Circuit Supervision Alarm Status 0 1 Off On 1 1 LD0 SCMLGGIO5 LD0 SCMHGGIO5 2 LD0 SCMLPGGIO5 LD0 SCMHPGGIO5 3 LD0 SCMLDGGIO5 LD...

Page 254: ... LD0 SCMHEGGIO6 5 LD0 SCMLCGGIO6 LD0 SCMHCGGIO6 6 LD0 TCSLSCBR6 LD0 TCSHSCBR6 SCM 6 1824 1526 Ind1 stVal Digital Input Channel 1 0 1 Off On 1825 1526 01 Ind2 stVal Digital Input Channel 2 0 1 Off On 1826 1526 02 Ind3 stVal Digital Input Channel 3 0 1 Off On 1827 1526 03 Ind4 stVal Digital Input Channel 4 0 1 Off On 1828 1526 04 RELEASE_ES Release Earth Switch Information 0 1 Off On 1829 1526 05 RE...

Page 255: ...arth Switch Information 0 1 Off On 1861 1528 05 RELEASE_DS Release Disconnector Information 0 1 Off On 1862 1528 06 REED_ES REED Earth Switch Information 0 1 Off On 1863 1528 07 RELEASE_CB Release Circuit Breaker Information 0 1 Off On 1864 1528 08 Ind10 stVal Error Code No Fault 0 1 Off On 1865 1528 09 Ind11 stVal Error Code Device Error 0 1 Off On 1866 1528 1 Ind12 stVal Error code Release 0 1 O...

Page 256: ...n 1896 1530 08 Ind10 stVal Error Code No Fault 0 1 Off On 1897 1530 09 Ind11 stVal Error Code Device Error 0 1 Off On 1898 1530 1 Ind12 stVal Error code Release 0 1 Off On 1899 1530 11 Ind13 stVal Error Code No Act 0 1 Off On 1900 1530 12 Ind14 stVal Error Code Interlocking Error 0 1 Off On 1901 1530 13 Ind15 stVal Error Code REED Release Error 0 1 Off On 1902 1530 14 Ind16 stVal Error Code Positi...

Page 257: ...or Code REED Release Error 0 1 Off On 1934 1532 14 Ind16 stVal Error Code Position Error 0 1 Off On 1935 1532 15 Ind17 stVal Error Code Time out Error 0 1 Off On 1936 1533 CircAlm stVal Trip Circuit Supervision Alarm Status 0 1 Off On 1937 1533 01 CircAlm stVal Trip Circuit Supervision Alarm Status 0 1 Off On 1 1 LD0 SCMLGGIO10 LD0 SCMHGGIO10 2 LD0 SCMLPGGIO10 LD0 SCMHPGGIO10 3 LD0 SCMLDGGIO10 LD0...

Page 258: ...pervision Alarm Status 0 1 Off On 1969 1535 01 CircAlm stVal Trip Circuit Supervision Alarm Status 0 1 Off On 1 Applicable read only data attributes are mentioned under their respective data objects LD0 SCMLGGIO LD0 SCMHGGIO Ind1 stVal Ind2 stVal Ind3 stVal Ind4 stVal LD0 SCMLPGGIO LD0 SCMHPGGIO Ind1 stVal Ind2 stVal Ind3 stVal Ind4 stVal RELEASE_ES RELEASE_DS REED_ES Ind10 stVal Ind11 stVal Ind12...

Page 259: ...2496 1568 00 SPCSO1 stVal Digital Output Channel 1 0 1 Off On 2497 1568 01 SPCSO2 stVal Digital Output Channel 2 0 1 Off On 2498 1568 02 SPCSO3 stVal Digital Output Channel 3 0 1 Off On 2499 1568 03 SPCSO4 stVal Digital Output Channel 4 0 1 Off On 2500 1568 04 reserved reserved 2501 1568 05 reserved reserved 2502 1568 06 reserved reserved 2503 1568 07 reserved reserved 2504 1568 08 CLOSE_ES Earth ...

Page 260: ... 2534 1570 06 reserved reserved 2535 1570 07 reserved reserved 2536 1570 08 CLOSE_ES Earth Switch Close Command 0 1 Off On 2537 1570 09 OPEN_ES Earth Switch Open Command 0 1 Off On 2538 1570 10 CLOSE_DS Disconnector Close Command 0 1 Off On 2539 1570 11 OPEN_DS Disconnector Open Command 0 1 Off On 2540 1570 12 reserved reserved 2541 1570 13 reserved reserved 2542 1570 14 reserved reserved 2543 157...

Page 261: ...d 0 1 Off On 2577 1573 01 reserved reserved 1 1 LD0 SCMLGGIO4 LD0 SCMHGGIO4 2 LD0 SCMLPGGIO4 LD0 SCMHPGGIO4 3 LD0 SCMLDGGIO4 LD0 SCMHDGGIO4 4 LD0 SCMLEGGIO4 LD0 SCMHEGGIO4 5 LD0 SCMLCGGIO4 LD0 SCMHCGGIO4 SCM 4 2592 1574 00 SPCSO1 stVal Digital Output Channel 1 0 1 Off On 2593 1574 01 SPCSO2 stVal Digital Output Channel 2 0 1 Off On 2594 1574 02 SPCSO3 stVal Digital Output Channel 3 0 1 Off On 2595...

Page 262: ...reserved 2630 1576 06 reserved reserved 2631 1576 07 reserved reserved 2632 1576 08 CLOSE_ES Earth Switch Close Command 0 1 Off On 2633 1576 09 OPEN_ES Earth Switch Open Command 0 1 Off On 2634 1576 10 CLOSE_DS Disconnector Close Command 0 1 Off On 2635 1576 11 OPEN_DS Disconnector Open Command 0 1 Off On 2636 1576 12 reserved reserved 2637 1576 13 reserved reserved 2638 1576 14 reserved reserved ...

Page 263: ...d 0 1 Off On 2673 1579 01 reserved reserved 1 1 LD0 SCMLGGIO7 LD0 SCMHGGIO7 2 LD0 SCMLPGGIO7 LD0 SCMHPGGIO7 3 LD0 SCMLDGGIO7 LD0 SCMHDGGIO7 4 LD0 SCMLEGGIO7 LD0 SCMHEGGIO7 5 LD0 SCMLCGGIO7 LD0 SCMHCGGIO7 SCM 7 2688 1580 00 SPCSO1 stVal Digital Output Channel 1 0 1 Off On 2689 1580 01 SPCSO2 stVal Digital Output Channel 2 0 1 Off On 2690 1580 02 SPCSO3 stVal Digital Output Channel 3 0 1 Off On 2691...

Page 264: ...reserved 2726 1582 06 reserved reserved 2727 1582 07 reserved reserved 2728 1582 08 CLOSE_ES Earth Switch Close Command 0 1 Off On 2729 1582 09 OPEN_ES Earth Switch Open Command 0 1 Off On 2730 1582 10 CLOSE_DS Disconnector Close Command 0 1 Off On 2731 1582 11 OPEN_DS Disconnector Open Command 0 1 Off On 2732 1582 12 reserved reserved 2733 1582 13 reserved reserved 2734 1582 14 reserved reserved ...

Page 265: ... Off On 2769 1585 01 reserved reserved 1 1 LD0 SCMLGGIO10 LD0 SCMHGGIO10 2 LD0 SCMLPGGIO10 LD0 SCMHPGGIO10 3 LD0 SCMLDGGIO10 LD0 SCMHDGGIO10 4 LD0 SCMLEGGIO10 LD0 SCMHEGGIO10 5 LD0 SCMLCGGIO10 LD0 SCMHCGGIO10 SCM 10 2784 1586 00 SPCSO1 stVal Digital Output Channel 1 0 1 Off On 2785 1586 01 SPCSO2 stVal Digital Output Channel 2 0 1 Off On 2786 1586 02 SPCSO3 stVal Digital Output Channel 3 0 1 Off O...

Page 266: ...n data register addresses provide information about the file revision and checksum of RIO600 s configuration and IO parameter file It also provides information about the firmware version major minor and patch and its checksum of the modules present in the RIO600 Table 172 Supervision data Reg A Type Scale IEC 61850 name SA name Description Values 2260 Unsigne d 16 1 RIO Configuration File Revision...

Page 267: ...5535 2292 Unsigne d 16 1 Module 2 Reserved For Future Use 0 2293 Unsigne d 16 1 Module 2 Reserved For Future Use 0 2294 Unsigne d 16 1 Module 3 Firmware Version Major High byte Minor Low byte 0 65535 2295 Unsigne d 16 1 Module 3 Firmware Version Patch Low byte 0 65535 2296 Unsigne d 16 1 Module 3 Reserved For Future Use 0 2297 Unsigne d 16 1 Module 3 Reserved For Future Use 0 2298 Unsigne d 16 1 M...

Page 268: ... 0 2314 Unsigne d 16 1 Module 8 Firmware Version Major High byte Minor Low byte 0 65535 2315 Unsigne d 16 1 Module 8 Firmware Version Patch Low byte 0 65535 2316 Unsigne d 16 1 Module 8 Reserved For Future Use 0 2317 Unsigne d 16 1 Module 8 Reserved For Future Use 0 2318 Unsigne d 16 1 Module 9 Firmware Version Major High byte Minor Low byte 0 65535 2319 Unsigne d 16 1 Module 9 Firmware Version Pa...

Page 269: ...600 related fault and warning information The Status view shows status information The Configuration view shows information about the configuration The Communication view shows communication parameter settings 8 3 Selecting the fault view The fault view shows RIO600 related fault and warning information The left column lists the modules related to the fault or warning and the right column shows th...

Page 270: ...the menu bar GUID 080B805A 0F4D 4124 A6B0 6E5A4E8B386B V5 EN Figure 91 Status page of RIO600 WHMI Click the Click Here For Details link beside GOOSE Rx to view GOOSE Receive Status The content area is updated with information related to the last GOOSE frame as received by RIO600 for each GOOSE AppID Section 8 1MRS757488 H Using the Web HMI 262 RIO600 Installation and Commissioning Manual ...

Page 271: ...is displayed in the error column of the GOOSE Receive Status table GUID 345B5EED AA81 4D07 BC06 BF261F875127 V3 EN Figure 92 GOOSE Receive Status Click the Click Here For Details link beside GOOSE Tx to view GOOSE Transmit Status The content area is updated with information related to the last transmitted GOOSE frame for each GOOSE AppID 1MRS757488 H Section 8 Using the Web HMI RIO600 263 Installa...

Page 272: ...Details link under Modbus status header for the detailed Modbus status GUID 7B00E7C8 7F11 478B BA29 741F840A0758 V1 EN Figure 94 Modbus status View Time Sync Status to see the statuses of SNTP Server 1 and 2 or Modbus Section 8 1MRS757488 H Using the Web HMI 264 RIO600 Installation and Commissioning Manual ...

Page 273: ...O Status to see the LED statuses of the channels of the binary I O modules Grey indicates that the LED is off Yellow color indicates that the LED is on The LED status does not reflect the actual output if the DOM output is configured as pulse mode or when SCM8H SCM8L module is configured for application types other than 4 I O In case of SIM8F and SIM4F click the Click Here link to see the detailed...

Page 274: ...on the WHMI 8 5 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 Section 8 1MRS757488 H Using the Web HMI 266 RIO600 Installation and Commissioning Manual ...

Page 275: ... all channels in that particular module The configurations that are specific to a particular channel are shown on a row pertaining to that channel GUID 8F3E200A AC91 4F75 9609 4B58869A3A47 V2 EN Figure 99 DIM configuration The DOM Configuration status section shows the settings for each channel of DOM4 module present in RIO600 The row that belongs to the module number gives configuration details c...

Page 276: ...s of all individual channels for that particular module GUID 710D8095 E41F 401F 9BB7 386EBC890B7F V2 EN Figure 101 RTD configuration The AOM Configuration setting section shows the settings for each AOM4 module present in RIO600 The row that belongs to the module number gives the configuration details of all individual channels for that particular module Section 8 1MRS757488 H Using the Web HMI 26...

Page 277: ...ed by Parameter Setting of RIO600 Connectivity Package GUID 7E9167E0 E04A 4E4B B13B 17DB5AE2C5F3 V3 EN Figure 103 SIM8F configuration The SIM4F Configuration setting section shows the SIM4F configuration for the selected SIM4F module It gives configuration details in read only mode of the SIM4F module as configured by Parameter Setting of RIO600 Connectivity Package 1MRS757488 H Section 8 Using th...

Page 278: ...P server address is If Modbus is disabled the Modus client address is The GOOSE publisher and subscriber multicast MAC addresses display the GOOSE publisher and subscriber related information If the publisher MAC filtering is enabled it is shown by the GOOSE Publisher Physical MAC parameter If the publisher MAC is not configured it is not visible under Communication Parameters Section 8 1MRS757488...

Page 279: ...GUID 2EBB410F 2AD5 4BFE BFDE E0C42F090730 V4 EN Figure 105 Communication view 1MRS757488 H Section 8 Using the Web HMI RIO600 271 Installation and Commissioning Manual ...

Page 280: ...272 ...

Page 281: ...reen OFF Power is not available or PSMH is not working Table 174 LED indicators LECM LED Color State Description Ready Green ON LECM is ready Ready Green Flashing LECM is ready and in test mode or FACTORY reset operation in progress IRF Red OFF LECM is healthy IRF Red ON LECM is in error condition IRF Red Flashing LECM is in warning condition Ethernet link Green ON Link is established Ethernett li...

Page 282: ...althy IRF Red ON Module is in error condition IRF Red Flashing Module is in warning condition LF Fwd Rv Green ON Power direction indication as per configuration LF Fwd Rv Red ON Power direction indication as per configuration LF Fwd Rv Orange ON Power direction indication as per configuration THD TDD Green Red OFF THD TDD is not present THD TDD Green Red ON THD TDD is present LED color indication ...

Page 283: ... is detected LED color indication is as per configuration and fault detection direction Table 177 LED indicators SIM4F modules LED Color State Description Ready Green ON Module is ready Ready Green Flashing Module is powered on configuration is pending IRF Red OFF Module is healthy IRF Red ON Module is in error condition IRF Red Flashing Module is in warning condition Inrush Green OFF Inrush fault...

Page 284: ... input signal is HIGH DIM8H 100 V DC DIM8L 24 V DC and OFF if the signal is LOW 0 V DC The operation is independent of normal inverted parameter The binary output LED is ON if the output contact is closed and OFF if the output contact is open The operation is independent of normal inverted parameter Flashing protection indication LEDs signify that the fault has been cleared and is waiting for rese...

Page 285: ...ECM module Normal functionality is compromised 1 Shows error by steady red LED on LECM module 2 Shows IRF source information on WHMI under faults page 3 Force all DOM4 outputs to default that is 0 4 All AOM4 output continues to drive the last GOOSE received value 5 GOOSE Update Quality of all data attributes and RIO600 module health as per IEC 61850 6 Open DOM4 IRF output contact if configured 1 C...

Page 286: ...r in previous module over LECM WHMI if detected Table 181 Behavior during IRF in DOM4 module Module IRF Behavior in an IRF condition RIO600 as a whole LECM DOM4 DIM8L DIM8H RTD4 AOM4 IRF in DOM4 module Continues normal function with corrective action 1 Shows IRF by steady IRF LED on LECM module 2 DOM4 Module under fault s channel is forced to default i e FALSE or OFF state The DOM4 module s channe...

Page 287: ... LECM WHMI if detected Table 183 Behavior during IRF in AOM4 module Module IRF Behavior in an IRF condition RIO600 as a whole LECM AOM4 DIM8L DIM8H DOM4 RTD4 IRF in AOM4 module Continues normal function with corrective action 1 Show IRF to user by steady IRF LED on LECM module 2 Shows IRF source information on WHMI under Faults page 3 AOM4 module under fault s channels are forced to default that i...

Page 288: ...Module IRF Behavior in an IRF condition RIO600 as a whole LECM DIM8L DIM8H DOM4 RTD4 AOM4 IRF in SIM4F module Continues normal function with corrective action 1 Shows IRF by steady IRF LED on LECM module 2 Shows IRF source information on WHMI under faults page 3 SIM4F module information is sent with bad quality 4 GOOSE Updates quality of all modules data attributes and RIO600 module health as per ...

Page 289: ... arp d 4 2 Press ENTER to flush the ARP table and establish the communication to RIO600 RIO600 supports only one user credential for FTP with the user name Administrator 9 3 Restoring factory settings The LECM board has a push button to restore RIO600 to factory settings The configuration files in RIO600 are deleted and the communication parameters are changed to the default values 1 Power off the...

Page 290: ...ration files and bring the LECM module to its factory default state The LECM board automatically reboots when the stored configuration files have been deleted The ready LED turns OFF and then ON once and the IRF LED turns OFF and back ON to indicate an internal relay fault The absence of RIO600 configuration files causes this internal relay fault 9 4 Ping command response In the absence of TCP IP ...

Page 291: ... Ready LED flashes indicating that the module has been powered up but the configuration is missing 1 Separate the modules from each other If the modules are loosely connected with each other or the back plane pins on the modules do not connect exactly between the two modules the I O modules are not detected by the communication module Thus the configuration is not applied 2 Reconnect the modules T...

Page 292: ... is not within valid range Sensor input signals are not within valid range For more information on the valid measurement range see the product guide 9 7 Contacting customer support Before contacting the customer service gather the required background information Firmware version for the different modules available in WHMI Connectivity package version PCM600 version Section 9 1MRS757488 H Troublesh...

Page 293: ...4 163 g RTD4 206 g AOM4 206 g SIM8F SIM4F 180 g SCM8H SCM8L 215 g Table 189 Dimensions of the end clamp EW 35 Weidmuller Description Value Width 8 5 mm to be fixed at the ends of assembled modules Table 190 Power supply Description PSMH PSML Uaux nominal 100 110 120 220 240 V AC 50 and 60 Hz 24 30 48 60 V DC 110 125 220 250 V DC Uaux variation 85 110 of Uaux nominal 85 264 V AC 50 120 of Uaux nomi...

Page 294: ...M DIM8L PSM LECM DOM4 All DOs activated 4 W PSM LECM DOM4 5 All DOs activated 12 W PSM 2 LECM DIM8H 5 All DIs activated 11 W PSM 2 LECM DIM8L 5 PSM 2 LECM DOM4 10 All DOs activated 22 W Table 191 Binary inputs Description DIM8H DIM8L Rated voltage 110 250 V DC 24 30 48 60 V DC Operating voltage range 20 of rated voltage 20 of rated voltage Current drain 3 3 7 mA 2 mA Power consumption input channe...

Page 295: ... per lead 100 Ω nickel 200 Ω per lead 120 Ω nickel 200 Ω per lead 250 Ω nickel 200 Ω per lead Isolation 4 kV Inputs to all other channel outputs and protective earth RTD resistance sensing maximum 0 275 mA rms current Operation accuracy 1 C Response time Filter time 350 ms mA inputs Supported current range 0 20 mA Current input impedance 44 Ω 0 1 Operation accuracy 0 5 or 0 1 mA Isolation 4 kV Inp...

Page 296: ...erage operating current voltage and power Average operating current voltage power according to selection 3 min 10 min 15 min 1 hour 2 hours 24 hours Peak current voltage and power values Peak values for 1 day 1 week 1 month 1 year General detection of the harmonics disturbances Current TDD Total demand distortion up to the 8th harmonics Voltage THD Total harmonic distortion up to the 8th harmonics...

Page 297: ...the set value in the range of 25 1000 A Voltage 1 5 of the set value Phase angle 3 Operate time 1 0 of the set value or 20 ms Current measurement based on internal calculation Fuse failure protection Operating range 4 1000 A Negative sequence current level 300 10000 V Negative sequence voltage level Accuracy Depending on the nominal frequency of the current measured fn NPS function 36 ms for UFaul...

Page 298: ... in the range of 80 4800 A 10 in the range of 4800 8000 A Line frequency measurement Range 50 or 60 Hz Accuracy For 50 Hz 50 mHz For 60 Hz 60 mHz Average operating current Average operating current according to selection 3 min 10 min 15 min 1 hour 2 hours 24 hours Peak current Peak values for 1 day 1 week 1 month 1 year Non directional overcurrent fault detection Operating range 50 2000 A Accuracy...

Page 299: ...unded low impedance network Accuracy Depending on the nominal frequency of the current measured f fn Current 1 5 of the set value or 0 02 A IFault 2 set value 36 ms IFault 10 set value 30 ms Operate time 1 0 of the set value or 20 ms Table 197 Binary inputs SCM Description SCM8H SCM8L Rated voltage 110 250 V DC 24 30 48 60 V DC Operating voltage range 20 of rated voltage 20 of rated voltage Curren...

Page 300: ...used by connectors and cable together Table 200 Degree of protection by enclosure Description Value Degree of protection IP201 1 If a higher IP class is required the cabinet where the device is installed should provide proper protection Table 201 Environmental conditions Description Value Operating temperature range 25 70 C Relative humidity 93 Atmospheric pressure 86 106 kPa Altitude up to 2000 m...

Page 301: ...1 and IEC 60255 27 OK Table 204 Power supply module tests Test Type test value Result Operating range of auxiliary supply voltage test 80 and 120 of rated value for DC 85 and 110 of rated value for AC frequency is between 50 Hz for 5 and 60 Hz for 5 IEC 60255 1 and IEEE C37 90 2005 Power consumption of auxiliary supply IEC 60255 1 and IEEE C37 90 2005 Quiescent load 4 W Maximum load 12 W Reversal ...

Page 302: ... 50 μs 0 5 J IEC 60255 27 and IEEE C37 90 2005 Insulation resistance measurements 100 MΩ 500 V DC IEC 60255 27 1 Insulation tests are not applicable to SIM8F SIM4F Table 207 Electromagnetic compatibility and immunity tests Description Type test value Reference Electrostatic discharge IEC 60255 26 and IEC 61000 4 2 Level 3 Air discharge 8 kV Radio frequency electromagnetic field amplitude modulated...

Page 303: ...voltage pulse 1 2 50 μs Tr Th open circuit 8 20 μs Tr Th short circuit IEC 60255 26 and IEC 61000 4 5 Auxiliary power supply and input output ports1 4 kVp L Gnd 2 kVp L L Communication port 2 kVp L Gnd while no L L test is applicable Voltage dips short interruptions and voltage variation immunity tests AC 50 Hz and 60 Hz 30 reduction for 25 30 cycles 60 reduction for 10 12 cycles 100 reduction for...

Page 304: ...rts 2 5 kV common mode differential mode IEEE C37 90 1 2002 Fast transient SWC test All ports 4 kV common mode differential mode IEEE C37 90 1 2002 Radio frequency interference tests 20 V m prior to modulation f 80 1000 MHz AM f 900 MHz PM IEEE C37 90 2 2004 Electrostatic discharge test 15 kV air discharge IEEE C37 90 3 2001 Table 209 Mechanical tests Description Type test value Reference Vibratio...

Page 305: ...0 C IEC 60068 2 2 and IEEE C37 90 2005 Dry cold test 96 h at 25 C 16 h at 40 C IEC 60068 2 1 and IEEE C37 90 2005 Damp heat cyclic test 6 cycles 12 h 12 h at 25 55 C humidity 93 IEC 60068 2 30 Damp heat steady state test Temperature 40 C Humidity 93 Duration 96 h IEC 60068 2 78 and IEEE C37 90 2005 Change of temperature test 5 cycles 3 h 3 h at 25 55 C IEC60068 2 14 Storage test 96 h at 40 C 96 h ...

Page 306: ...298 ...

Page 307: ... shaped cross section DOM Binary output module four channels DOM4 Binary output module four channels DST Daylight saving time DT Definite time EF Earth fault EMC Electromagnetic compatibility Ethernet A standard for connecting a family of frame based computer networking technologies into a LAN FPI Measured value short floating point information FPI Fault passage indicator FTP File transfer protoco...

Page 308: ...rotocol developed by the Modicon company in 1979 Originally used for communication in PLCs and RTU devices Modbus TCP IP Modbus RTU protocol which uses TCP IP and Ethernet to carry data between devices MTA Also known as RCA or base angle Maximum torque angle MV Medium voltage NTP Network time protocol OC Overcurrent PC 1 Personal computer 2 Polycarbonate PCM600 Protection and Control IED Manager P...

Page 309: ... module 4 currents and 4 voltages SNTP Simple Network Time Protocol TCP Transmission Control Protocol TCP IP Transmission Control Protocol Internet Protocol UDP User datagram protocol UTC Coordinated universal time WHMI Web human machine interface 1MRS757488 H Section 12 Glossary RIO600 301 Installation and Commissioning Manual ...

Page 310: ...302 ...

Page 311: ...303 ...

Page 312: ... FI 65101 VAASA Finland Phone 358 10 22 11 ABB India Limited Distribution Automation Maneja Works Vadodara 390013 India Phone 91 265 272 4402 Fax 91 265 263 8922 www abb com mediumvoltage Copyright 2019 ABB All rights reserved 1MRS757488 H ...

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