background image

Logic rotating switch for function selection and LHMI
presentation SLGAPC

SEMOD114908-4 v11

The logic rotating switch for function selection and LHMI
presentation (SLGAPC) (or the selector switch function
block) is used to get an enhanced selector switch
functionality compared to the one provided by a hardware
selector switch. Hardware selector switches are used
extensively by utilities, in order to have different functions
operating on pre-set values. Hardware switches are
however sources for maintenance issues, lower system
reliability and an extended purchase portfolio. The selector
switch function eliminates all these problems.

Selector mini switch VSGAPC

SEMOD158756-5 v10

The Selector mini switch (VSGAPC) function block is a
multipurpose function used for a variety of applications, as a
general purpose switch.

VSGAPC can be controlled from the menu, from a symbol
on the single line diagram (SLD) on the local HMI or from
Binary inputs.

Generic communication function for Double Point
indication DPGAPC

SEMOD55850-5 v7

Generic communication function for Double Point indication
(DPGAPC) function block is used to send double point
position indications to other systems, equipment or
functions in the substation through IEC 61850-8-1 or other
communication protocols. It is especially intended to be
used in the interlocking station-wide logics.

Single point generic control 8 signals SPC8GAPC

SEMOD176462-4 v11

The Single point generic control 8 signals (SPC8GAPC)
function block is a collection of 8 single point commands
that can be used for direct commands for example reset of
LEDs or putting IED in "ChangeLock" state from remote. In
this way, simple commands can be sent directly to the IED
outputs, without confirmation. Confirmation (status) of the
result of the commands is supposed to be achieved by other
means, such as binary inputs and SPGAPC function blocks.
The commands can be pulsed or steady with a settable
pulse time.

Automation bits, command function for DNP3.0
AUTOBITS

SEMOD158591-5 v9

Automation bits function for DNP3 (AUTOBITS) is used
within PCM600 to get into the configuration of the
commands coming through the DNP3 protocol. The
AUTOBITS function plays the same role as functions
GOOSEBINRCV (for IEC 61850) and MULTICMDRCV (for
LON).

Single command, 16 inputs

M12446-6 v6

The IEDs can receive commands either from a substation
automation system or from the local HMI. The command
function block has outputs that can be used, for example, to

control high voltage apparatuses or for other user defined
functionality.

14. Scheme communication

Scheme communication logic for distance or
overcurrent protection ZCPSCH

M13860-3 v12

To achieve instantaneous fault clearance for all line faults,
scheme communication logic is provided. All types of
communication schemes for permissive underreaching,
permissive overreaching, blocking, delta based blocking,
unblocking and intertrip are available.

The built-in communication module (LDCM) can be used for
scheme communication signaling when included.

Phase segregated scheme communication logic for
distance protection ZPCPSCH

SEMOD141686-4 v4

Communication between line ends is used to achieve fault
clearance for all faults on a power line. All possible types of
communication schemes for example, permissive
underreach, permissive overreach and blocking schemes
are available. To manage problems with simultaneous faults
on parallel power lines phase segregated communication is
needed. This will then replace the standard Scheme
communication logic for distance or Overcurrent protection
(ZCPSCH) on important lines where three communication
channels (in each subsystem) are available for the distance
protection communication.

The main purpose of the Phase segregated scheme
communication logic for distance protection (ZPCPSCH)
function is to supplement the distance protection function
such that:

• fast clearance of faults is also achieved at the line end for

which the faults are on the part of the line not covered by
its underreaching zone.

• correct phase selection can be maintained to support

single-pole tripping for faults occurring anywhere on the
entire length of a double circuit line.

To accomplish this, three separate communication
channels, that is, one per phase, each capable of
transmitting a signal in each direction is required.

ZPCPSCH can be completed with the current reversal and
WEI logic for phase segregated communication, when found
necessary in Blocking and Permissive overreaching
schemes.

Current reversal and weak-end infeed logic for
distance protection ZCRWPSCH

M13896-3 v15

The ZCRWPSCH function provides the current reversal and
weak end infeed logic functions that supplement the
standard scheme communication logic. It is not suitable for
standalone use as it requires inputs from the distance
protection functions and the scheme communications
function included within the terminal.

Line differential protection RED670

1MRK 505 379-BEN R

Version 2.2

 

Hitachi Energy

49

© 2017 - 2022 Hitachi Energy. All rights reserved

Summary of Contents for Relion 670 Series

Page 1: ...Relion 670 SERIES Line differential protection RED670 Version 2 2 Product guide ...

Page 2: ...is product includes software developed by the OpenSSL Project for use in the OpenSSL Toolkit https www openssl org This product includes cryptographic software written developed by Eric Young eay cryptsoft com and Tim Hudson tjh cryptsoft com Trademarks ABB is a registered trademark of ABB Asea Brown Boveri Ltd Manufactured by for a Hitachi Energy company All other brand or product names mentioned...

Page 3: ...lure would create a risk for harm to property or persons including but not limited to personal injuries or death shall be the sole responsibility of the person or entity applying the equipment and those so responsible are hereby requested to ensure that all measures are taken to exclude or mitigate such risks This document has been carefully checked by Hitachi Energy but deviations cannot be compl...

Page 4: ...cerning electrical equipment for use within specified voltage limits Low voltage directive 2006 95 EC This conformity is the result of tests conducted by Hitachi Energy 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 standard...

Page 5: ...ystem supervision 46 13 Control 47 14 Scheme communication 49 15 Logic 51 16 Monitoring 54 17 Metering 57 18 Human machine interface 58 19 Basic IED functions 58 20 Ethernet 59 21 Station communication 60 22 Remote communication 62 23 Hardware description 62 24 Connection diagrams 66 25 Certification 66 26 Technical data 67 27 Ordering for customized IED 168 28 Ordering for pre configured IED 180 ...

Page 6: ...eleased L Document not released M Document not released N 2020 09 2 2 4 Functions ZMBURPSB APPTEF IEC 61850SIM and ALGOS added Updates enhancements made to functions REFPDIF L4CPDIF ZMFPDIS ZMFCPDIS PPLPHIZ PPL2PHIZ ZCVPSOF EF4PTOC ROV2PTOV SAPTUF SAPTOF CCSSPVC FUFSPVC SESRSYN SMPPTRC SSIMG and SSIML Ordering section updated Previous revisions of SOM removed heavy duty SOM only alternative Certif...

Page 7: ...cording and fault locator are available to allow independent post fault analysis after primary disturbances The Disturbance recorder will also show remote station currents as received to this IED time compensated with measure communication time The fault locator in the IED is an essential complement to other monitoring functions since it measures and indicates the distance to the fault with high a...

Page 8: ...put module which is sufficient for the default configured I O to trip and close circuit breaker All IEDs can be reconfigured with the help of the application configuration tool in PCM600 The IED can be adapted to special applications and special logic can be developed such as logic for automatic opening of disconnectors and closing of ring bays automatic load transfer from one busbar to the other ...

Page 9: ...N MMXU MET UN SMB RREC 79 5 0 1 SMP PTRC 94 1 0 25 SC VC SES RSYN FUF SPVC U I WA1_VT LINE_CT CC PDSC 52PD PD SDEPSDE 67N IN EF4 PTOC 51N_67N 4 IN ZMF PDIS 21 Z PSL PSCH Zpsl OOS PPAM 78 Ucos SA PFRC 81 df dt ECRW PSCH 85 EC PSCH 85 S CSWI 3 Control S XSWI 3 Control Q CRSV 3 Control LINE_VT S SCBR Control S SCBR Control S XCBR 3 Control S SCBR Control S SCBR Control S SCBR Control LC PTTR 26 θ FLT...

Page 10: ...S 21 Z PSP PPAM 78 Ucos SA PFRC 81 df dt EC PSCH 85 SA PTUF 81 f SA PTOF 81 f OEX PVPH 24 U f GOP PDOP 32 P S CILO 3 Control S CSWI 3 Control ZCLC PSCH ZCRW PSCH 85 Q CRSV 3 Control ZC PSCH 85 ECRW PSCH 85 S XSWI 3 Control VN MMXU MET UN VN MMXU MET UN VN MMXU MET UN LMB RFLO 21FL FL WA1 WA1_VT WA1_CT LINE1_VT TIE_CT LINE2_VT WA2_VT WA2 CC PDSC 52PD PD CC PDSC 52PD PD ZPCW PSCH 85 ZPC PSCH 85 S SI...

Page 11: ... Ucos PSL PSCH Zpsl GUP PDUP 37 P EF PIOC 50N IN PSP PPAM 78 Ucos SA PFRC 81 df dt EC PSCH 85 SA PTUF 81 f SA PTOF 81 f OEX PVPH 24 U f GOP PDOP 32 P S CILO 3 Control S CSWI 3 Control Q CRSV 3 Control ECRW PSCH 85 S XSWI 3 Control VN MMXU MET UN VN MMXU MET UN VN MMXU MET UN SMT RFLO 21FL FL WA1 WA1_VT WA1_CT LINE1_VT TIE_CT LINE2_VT WA2_VT WA2 CC PDSC 52PD PD CC PDSC 52PD PD ZPCW PSCH 85 ZPC PSCH...

Page 12: ...OS PPAM 78 Ucos SA PFRC 81 df dt S CSWI 3 Control S XSWI 3 Control Q CRSV 3 Control LINE_VT ZPC PSCH 85 S SCBR Control S SCBR Control S XCBR 3 Control S SCBR Control S SCBR Control S SCBR Control LC PTTR 26 θ LF PTTR 26 θ PMU REP VR PVOC 51V 2 I U ROV2 PTOV 59N 2 U0 PSP PPAM 78 Ucos IEC16000252 4 en vsdx S SIMG 63 S SIML 71 CV MMXN MET P Q ZMF PDIS 21 Z VDC PTOV 60 Ud STB PTOC 50STB 3I STB 12AI 6I...

Page 13: ...bed in this manual Main protection functions GUID F871E970 5508 43FE A2A8 68A4679BE52B v1 Table 2 Example of quantities 2 number of basic instances 0 3 option quantities 3 A03 optional function included in packages A03 refer to ordering details C30 1 2 CB application For the pre configured variants Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 Hitachi Energy 13 2017 2022 Hitac...

Page 14: ...L Line differential protection logic 0 1 1 LDRGFC 11REL Additional security logic for differential protection 1 1 1 1 1 Impedance protection ZMQPDIS ZMQAPDIS 21 Distance protection zone quadrilateral characteristic 0 7 ZDRDIR 21D Directional impedance quadrilateral 0 2 ZMCPDIS ZMCAPDIS 21 Distance measuring zone quadrilateral characteristic for series compensated lines 0 5 ZDSRDIR 21D Directional ...

Page 15: ...racteristic 0 1 1 B35 1 B35 1 B35 1 ZMFCPDIS 21 High speed distance protection for series comp lines quad and mho characteristic 0 1 PPLPHIZ Phase preference logic 0 1 PPL2PHIZ Phase preference logic 0 1 ZMBURPSB 68 Power swing detection blocking and unblocking 0 1 1 B35 1 B35 1 B35 1 PSLPSCH Power swing logic 0 1 1 B35 1 B35 1 B35 1 PSPPPAM 78 Poleslip out of step protection 0 1 1 B22 1 B22 1 B22...

Page 16: ...on one time constant Celsius 0 2 1 1 1 1 LFPTTR 26 Thermal overload protection one time constant Fahrenheit 0 2 1 1 1 1 CCRBRF 50BF Breaker failure protection 0 2 2 1 2 1 STBPTOC 50STB Stub protection 0 2 1B 1 B27 1 1B 1 B27 1 CCPDSC 52PD Pole discordance protection 0 2 2 1 2 1 GUPPDUP 37 Directional underpower protection 0 2 1 C35 1 C35 1 C35 1 C35 GOPPDOP 32 Directional overpower protection 0 2 ...

Page 17: ...tion 0 1 Frequency protection SAPTUF 81 Underfrequency protection 0 10 1B 3 E04 1B 3 E04 1B 3 E04 1B 3 E04 SAPTOF 81 Overfrequency protection 0 6 1B 3 E04 1B 3 E04 1B 3 E04 1B 3 E04 SAPFRC 81 Rate of change of frequency protection 0 6 1B 3 E04 1B 3 E04 1B 3 E04 1B 3 E04 Multipurpose protection CVGAPC General current and voltage protection 0 4 4 F01 4 F01 4 F01 4 F01 General calculation SMAIHPAC Mu...

Page 18: ...rotating switch for function selection and LHMI presentation 15 15 15 15 15 VSGAPC Selector mini switch 30 30 30 30 30 DPGAPC Generic communication function for Double Point indication 32 32 32 32 32 SPC8GAPC Single point generic control function 8 signals 5 5 5 5 5 AUTOBITS Automation bits command function for DNP3 0 3 3 3 3 3 SINGLECMD Single command 16 signals 8 8 8 8 8 I103CMD Function command...

Page 19: ...TMAGAPC Trip matrix logic 12 12 12 12 12 ALMCALH Logic for group alarm 5 5 5 5 5 WRNCALH Logic for group warning 5 5 5 5 5 INDCALH Logic for group indication 5 5 5 5 5 AND GATE INV LLD OR PULSETIMER RSMEMORY SRMEMORY TIMERSET XOR Basic configurable logic blocks see Table 3 40 420 40 420 40 420 40 420 40 420 ANDQT INDCOMBSPQT INDEXTSPQT INVALIDQT INVERTERQT ORQT PULSETIMERQT RSMEMORYQT SRMEMORYQT T...

Page 20: ... functions 10 10 10 10 10 INTSEL Analog input selector for integer values 5 5 5 5 5 LIMITER Definable limiter 20 20 20 20 20 ABS Absolute value 20 20 20 20 20 POL_REC Polar to rectangular converter 20 20 20 20 20 RAD_DEG Radians to degree angle converter 20 20 20 20 20 CONST_REAL Definable constant for logic functions 10 10 10 10 10 REALSEL Analog input selctor for real values 5 5 5 5 5 STOREINT S...

Page 21: ...edium 21 21 21 21 21 SSIML 71 Insulation supervision for liquid medium 3 3 3 3 3 SSCBR Circuit breaker condition monitoring 0 6 6 3 6 3 I103MEAS Measurands for IEC 60870 5 103 1 1 1 1 1 I103MEASUSR Measurands user defined signals for IEC 60870 5 103 3 3 3 3 3 I103AR Function status auto recloser for IEC 60870 5 103 1 1 1 1 1 I103EF Function status earth fault for IEC 60870 5 103 1 1 1 1 1 I103FLTP...

Page 22: ...cator 1 1 SMTRFLO Single and double ended fault locator 11 1 1 1 Metering PCFCNT Pulse counter logic 16 16 16 16 16 ETPMMTR Function for energy calculation and demand handling 6 6 6 6 6 1 Requires LDCM 2Mbps Table 3 Total number of instances for basic configurable logic blocks Basic configurable logic block Total number of instances AND 280 GATE 40 INV 420 LLD 40 OR 320 PULSETIMER 40 RSMEMORY 40 S...

Page 23: ...1 AB_TRAFO 1 SCSWI Switch controller 10 SXSWI Circuit switch 9 QCRSV Reservation function block for apparatus control 2 RESIN1 1 RESIN2 59 POS_EVAL Evaluation of position indication 10 XLNPROXY Proxy for signals from switching device via GOOSE 12 GOOSEXLNRCV GOOSE function block to receive a switching device 12 Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 Hitachi Energy 23 20...

Page 24: ...N2 59 POS_EVAL Evaluation of position indication 15 XLNPROXY Proxy for signals from switching device via GOOSE 20 GOOSEXLNRCV GOOSE function block to receive a switching device 20 Table 6 Total number of instances for configurable logic blocks Q T Configurable logic blocks Q T Total number of instances ANDQT 120 INDCOMBSPQT 20 INDEXTSPQT 20 INVALIDQT 22 INVERTERQT 120 ORQT 120 PULSETIMERQT 40 RSME...

Page 25: ...logic block Total number of instances AND 220 GATE 49 INV 220 LLD 49 OR 220 PULSETIMER 89 RSMEMORY 40 SLGAPC 74 SRMEMORY 130 TIMERSET 113 VSGAPC 120 XOR 89 Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 Hitachi Energy 25 2017 2022 Hitachi Energy All rights reserved ...

Page 26: ...nication protocol 1 1 1 1 1 MSTSER DNP3 0 serial master 1 1 1 1 1 MST1TCP MST2TCP MST3TCP MST4TCP DNP3 0 for TCP IP communication protocol 1 1 1 1 1 DNPFREC DNP3 0 fault records for TCP IP and EIA 485 communication protocol 1 1 1 1 1 IEC 61850 8 1 IEC 61850 1 1 1 1 1 GOOSEINTLKRCV Horizontal communication via GOOSE for interlocking 59 59 59 59 59 IEC 61850SIM IEC 61850 simulation mode 1 1 1 1 1 GO...

Page 27: ... 1 FSTACCS Field service tool access 1 1 1 1 1 IEC 61850 9 2 Process bus communication 8 merging units 0 1 1 P30 1 P30 1 P30 1 P30 ACTIVLOG Activity logging 1 1 1 1 1 ALTRK Service tracking 1 1 1 1 1 PRP IEC 62439 3 Parallel redundancy protocol 0 1 1 P23 1 P23 1 P23 1 P23 HSR IEC 62439 3 High availability seamless redundancy 0 1 1 P24 1 P24 1 P24 1 P24 RSTP IEC 62439 3 Rapid spanning tree protocol...

Page 28: ...SR2M_306 BSR2M_313 BSR2M_323 Binary signal transfer 2Mbit receive 1 1 1 1 1 BST2M_305 BST2M_312 BST2M_322 BST2M_306 BST2M_313 BST2M_323 Binary signal transfer 2Mbit transmit 1 1 1 1 1 LDCMTRN Transmission of analog data from LDCM 1 1 1 1 1 LDCMTRN_2M_305 LDCMTRN_2M_306 LDCMTRN_2M_312 LDCMTRN_2M_313 LDCMTRN_2M_322 LDCMTRN_2M_323 Transmission of analog data from LDCM 2Mbit 1 1 1 1 1 LDCMRecBinStat1 ...

Page 29: ...nt protection 0 1 1 C34 1 C34 1 C34 1 ECRWPSCH 85 Current reversal and weak end infeed logic for residual overcurrent protection 0 1 1 C34 1 C34 1 C34 1 DTT Direct transfer trip see Table 8 0 1 Table 8 Direct transfer trip DTT Function name Function description Total number of instances LAPPGAPC Low active power and power factor protection 1 COUVGAPC Compensated over and undervoltage protection 1 ...

Page 30: ...EE 1344 and IEC IEEE 60255 118 C37 118 phasors 1 8 1 ANALOGREPORT1 Protocol reporting of analog data via IEEE 1344 and IEC IEEE 60255 118 C37 118 analogs 1 8 1 BINARYREPORT1 Protocol reporting of binary data via IEEE 1344 and IEC IEEE 60255 118 C37 118 binary 1 8 1 SMAI1 SMAI12 Signal matrix for analog inputs 1 3PHSUM Summation block 3 phase 6 PMUSTATUS Diagnostics for IEC IEEE 60255 118 C37 118 2...

Page 31: ...nality CHNGLCK Change lock function TERMINALID IED identifiers PRODINF Product information SYSTEMTIME System time LONGEN LON communication RUNTIME IED Runtime component SMBI Signal matrix for binary inputs SMBO Signal matrix for binary outputs SMMI Signal matrix for mA inputs SMAI1 SMAI12 Signal matrix for analog inputs 3PHSUM Summation block 3 phase ATHSTAT Authority status ATHCHCK Authority chec...

Page 32: ...erential scheme are connected in parallel External series resistor and a voltage dependent resistor which are both mounted externally to the IED are also required The external resistor unit shall be ordered under IED accessories in the Product Guide HZPDIF can be used to protect tee feeders or busbars reactors motors auto transformers capacitor banks and so on One such function block is used for a...

Page 33: ...l ends of the protected circuit L4CPDIF protects all electrical equipment such as power lines circuit breakers and small tap transformers that are within the protected zone The information on all locally measured currents is transmitted via communication channels to remote IEDs Then L4CPDIF compares these currents using a classical current differential principle supplemented by an additional advan...

Page 34: ...fferential protection Line differential protection 3 or 6 CT sets with in zone transformers LT3CPDIF LT6CPDIF M14932 3 v9 Two two winding power transformers or one three winding power transformer can be included in the line differential protection zone In such application the differential protection is based on the ampere turns balance between the transformer windings Both two and three winding tr...

Page 35: ... of networks different channel delay times are automatically compensated for and echo timing can be used Networks with unspecified route switching require that the line differential protection IED s built in GPS receiver PTP or IRIG B is used This way the protection function can operate correctly independent of the symmetric delays in communication channels The communication link is continuously m...

Page 36: ...tection function with three fault loops for phase to phase faults and three fault loops for phase to earth faults for each of the independent zones Individual settings for each zone in resistive and reactive reach gives flexibility for use as back up protection for transformer connected to overhead lines and cables of different types and lengths Distance measuring zone quadrilateral characteristic...

Page 37: ...r example difficulties to get permission to build new power lines The ability to accurately and reliably classify the different types of fault so that single pole tripping and autoreclosing can be used plays an important role in this matter Phase selection quadrilateral characteristic with fixed angle FDPSPDIS is designed to accurately select the proper fault loop in the distance function dependen...

Page 38: ...re 14 en05000034 vsd R X Forward operation Reverse operation IEC05000034 V1 EN US Figure 14 Typical quadrilateral distance protection zone with Phase selection quadrilateral characteristic with settable angle function FRPSPDIS activated The independent measurement of impedance for each fault loop together with a sensitive and reliable built in phase selection makes the function suitable in applica...

Page 39: ...ectional mode This makes them suitable together with different communication schemes for the protection of power lines and cables in complex network configurations such as parallel lines multi terminal lines and so on Phase selection quadrilateral characteristic with settable angle FRPSPDIS GUID 09D0E480 C003 424E BECD A82BCB0052CD v1 The operation of transmission networks today is in many cases c...

Page 40: ...ily loaded power lines there is an adaptive load compensation algorithm that prevents overreaching of the distance zones in the load exporting end improving the selectivity of the function This also reduces underreach in the importing end The ZMFCPDIS function has another directional element with phase segregated outputs STTDFwLx and STTDRVLx where x 1 3 based on the transient components It provid...

Page 41: ...tion on the preferred phase based on the selected phase preference scheme A number of different phase preference schemes are available PPL2PHIZ provides an additional phase selection criteria namely under voltage criteria suitable for phase selection during cross country faults In radial networks where there is no fault current in the phase with the external fault current or impedance based phase ...

Page 42: ...e set for the function and can be used to block each step individually Instantaneous residual overcurrent protection EFPIOC M12701 3 v16 The Instantaneous residual overcurrent protection EFPIOC has a low transient overreach and short tripping times to allow the use for instantaneous earth fault protection with the reach limited to less than the typical eighty percent of the line at minimum source ...

Page 43: ...se the own breaker fails to open CCRBRF measurement criterion can be current based CB position based or an adaptive combination of these two conditions A current based check with extremely short reset time is used as check criterion to achieve high security against inadvertent operation CB position check criteria can be used where the fault current through the breaker is small CCRBRF provides thre...

Page 44: ...ult Protection APPTEF GUID A16ED4BC 855F 4561 8512 B4F30775784F v1 The APPTEF Average Power Transient Earth Fault Protection function is a transient measuring directional earth fault protection Determination of the earth fault direction is based on the short term built up transient at the beginning of the earth fault This transient is to a large extent independent of the neutral point treatment Th...

Page 45: ... does not require scheme communication The PAPGAPC function performs phase selection using measured voltages Each phase voltage is compared to the opposite phase phase voltage A phase is deemed to have a fault if its phase voltage drops below a settable percentage of the opposite phase phase voltage The phase phase voltages include memory This memory function has a settable time constant The volta...

Page 46: ...hus it can for example be used to build sub synchronous resonance protection for synchronous generator 12 Secondary system supervision Current circuit supervision CCSSPVC M12444 3 v10 Open or short circuited current transformer cores can cause unwanted operation of many protection functions such as differential earth fault current and negative sequence current functions Current circuit supervision...

Page 47: ...time which improves the network stability Synchrocheck energizing check and synchronizing SESRSYN function checks that the voltages on both sides of the circuit breaker are in synchronism or with at least one side dead to ensure that closing can be done safely SESRSYN function includes a built in voltage selection scheme for double bus and 1 breaker or ring busbar arrangements Manual closing as we...

Page 48: ...output boards and to supervise the switching operation and position Circuit switch SXSWI M16492 3 v6 The purpose of Circuit switch SXSWI function is to provide the actual status of positions and to perform the control operations that is pass all the commands to primary apparatuses in the form of disconnectors or earthing switches via binary output boards and to supervise the switching operation an...

Page 49: ...d function block has outputs that can be used for example to control high voltage apparatuses or for other user defined functionality 14 Scheme communication Scheme communication logic for distance or overcurrent protection ZCPSCH M13860 3 v12 To achieve instantaneous fault clearance for all line faults scheme communication logic is provided All types of communication schemes for permissive underr...

Page 50: ...n time can be achieved This short operate time enables rapid autoreclosing function after the fault clearance The communication logic module for directional residual current protection enables blocking as well as permissive under overreaching and unblocking schemes The logic can also be supported by additional logic for weak end infeed and current reversal included in Current reversal and weak end...

Page 51: ...gative sequence overcurrent protection LCNSPTOC GUID C4F99554 88BC 4F11 9EFE 91BCA6ED1261 v2 Negative sequence components are present in all types of fault condition They can reach considerably high values during abnormal operation Zero sequence overcurrent protection LCZSPTOC GUID F0C38DA1 2F39 46DE AFFE F919E6CF4A57 v2 Zero sequence components are present in all abnormal conditions involving ear...

Page 52: ...ach block has two outputs where one is inverted The memory setting controls if after a power interruption the flip flop resets or returns to the state it had before the power interruption The SET input has priority TIMERSET function has pick up and drop out delayed outputs related to the input signal The timer has a settable time delay XOR is used to generate combinatory expressions with boolean v...

Page 53: ...nversion IB16 SEMOD158373 5 v7 Integer to boolean 16 conversion function IB16 is used to transform an integer into a set of 16 boolean logical signals Integer to Boolean 16 conversion with logic node representation ITBGAPC SEMOD158421 5 v9 Integer to boolean conversion with logic node representation function ITBGAPC is used to transform an integer which is transmitted over IEC 61850 and received b...

Page 54: ...ents CVMMXN CMMXU VNMMXU VMMXU CMSQI VMSQI M12024 3 v9 The measurement functions are used to get on line information from the IED These service values make it possible to display on line information on the local HMI and on the substation automation system about measured voltages currents frequency active reactive and apparent power and power factor measured analog values from merging units primary...

Page 55: ...o the Disturbance recorder function The result is magnitude and phase angle before and during the fault for each analog input signal The trip value recorder information is available for the disturbances locally in the IED The trip value recorder information is an integrated part of the disturbance record Comtrade file Disturbance recorder DRPRDRE M12156 3 v13 The Disturbance recorder function supp...

Page 56: ...C89768F3572 v6 The Limit counter L4UFCNT provides a settable counter with four independent limits where the number of positive and or negative flanks on the input signal are counted against the setting values for limits The output for each limit is activated when the counted value reaches that limit Overflow indication is included for each up counter Running hour meter TEILGAPC GUID 464FB24F B367 ...

Page 57: ...oint a weak spot on the line The fault locator is an impedance measuring function giving the distance to the fault in km miles or of line length The main advantage is the high accuracy achieved by compensating for load current and for the mutual zero sequence effect on double circuit lines The compensation includes setting of the remote and local sources and calculation of the distribution of faul...

Page 58: ...e controlled by inputs STARTACC and STOPACC and EnaAcc setting and it can be reset to initial values with RSTACC input The maximum demand for active and reactive powers are calculated for the set time interval tEnergy and these values are updated every minute through output channels The active and reactive maximum power demand values are calculated for both forward and reverse direction and these ...

Page 59: ...for denial of service To get this denial of service that is reported on the communication the DOSALARM output from these blocks must be connected to a communication function For RSTP the frame error rate on an individual link cannot be extrapolated accurately to that of which is received by the IED Hence the frame error rate on link A LCCH FerCh and the frame error rate on link B LCCH RedFerCh can...

Page 60: ...IED s with blank front panel By default AP1 is available for engineering and maintenance IEC 61850 quality expander QUALEXP GUID 9C5DC78E 041B 422B 9668 320E62B847A2 v1 The quality expander component is used to display the detailed quality of an IEC UCA 61850 9 2LE analog channel The component expands the channel quality output of a Merging Unit analog channel received in the IED as per the IEC 61...

Page 61: ...indications in monitor direction Each input on the function block is specific for a certain fault type and therefore must be connected to a correspondent signal present in the configuration For example 68_TRGEN represents the General Trip of the device and must be connected to the general trip signal SMPPTRC_TRIP or equivalent IED status for IEC 60870 5 103 I103IED GUID BA671CCE A19F 414B AE8A 851...

Page 62: ...t each IED is equipped with a Line Data Communication Module LDCM The LDCM then acts as an interface to 64 kbit s and 2Mbit s communication channels for duplex communication between the IEDs In 2Mbit s mode each LDCM can send and receive up to 9 analog and up to 192 binary signals simultaneously In 64kbit s mode the LDCM can be configured to work in either analog mode or binary mode In analog mode...

Page 63: ...ptical communication ports for plastic plastic plastic glass or glass glass fiber cables One port is used for serial communication SPA IEC 60870 5 103 or DNP3 port and the other port is used for LON communication Line data communication module LDCM M16075 3 v7 Each module has one optical port one for each remote end to which the IED communicates Alternative modules are Short range LDCM 820 nm mult...

Page 64: ... Figure 21 A 1 2 x 19 size IED side by side with RHGS6 M15243 12 v11 Table 12 Case dimensions Case size mm inches A B C D E F G H I 6U 1 2 x 19 265 9 10 47 223 7 8 81 247 5 9 74 255 0 10 04 205 8 8 10 190 5 7 50 466 5 18 36 232 5 9 15 482 6 19 6U 3 4 x 19 265 9 10 47 335 9 13 23 247 5 9 74 255 0 10 04 318 0 12 52 190 5 7 50 466 5 18 36 232 5 9 15 482 6 19 Line differential protection RED670 1MRK 5...

Page 65: ...Mounting alternatives M16079 3 v14 19 rack mounting kit Flush mounting kit with cut out dimensions 1 2 case size h 254 3 mm 10 01 w 210 1 mm 8 27 3 4 case size h 254 3 mm 10 01 w 322 4 mm 12 69 1 1 case size h 254 3 mm 10 01 w 434 7 mm 17 11 Wall mounting kit See ordering for details about available mounting alternatives Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 Hitachi En...

Page 66: ...ist of certification for Relion 670 series UL certification for Relion 670 series E502400 IEC 60255 1 Environmental functional issued by DNV GL 1418 18 1446 18 G3 Compliance Certificate Sulphur dioxide test for contacts and connections Hydrogen sulphide test for contacts and connections Flowing mixed gas corrosion test IEC 60068 2 42 2003 IEC 60068 2 43 2003 IEC 60068 2 60 2015 IEC 61850 Ed2 level...

Page 67: ...ent are only valid under the following circumstances 1 Main current transformers with 1 A or 2 A secondary rating are wired to the IED 1 A rated CT inputs 2 Main current transformer with 5 A secondary rating are wired to the IED 5 A rated CT inputs 3 CT and VT ratios in the IED are set in accordance with the associated main instrument transformers Note that for functions which measure an analogue ...

Page 68: ...r 1 min 4 Ir continuously Dynamic withstand 250 Ir one half wave Burden 20 mVA at Ir 1 A 150 mVA at Ir 5 A max 350 A for 1 s when COMBITEST test switch is included Voltage inputs Rated voltage Ur 110 or 220 V Operating range 0 340 V Thermal withstand 450 V for 10 s 420 V continuously Burden 20 mVA at 110 V 80 mVA at 220 V all values for individual voltage inputs Note All current and voltage data a...

Page 69: ...0 mVA at 110 V 80 mVA at 220 V all values for individual voltage inputs Note All current and voltage data are specified as RMS values at rated frequency M6389 1 v5 Table 15 MIM mA input module Quantity Rated value Nominal range Input resistance Rin 194 Ohm Input range 5 10 20 mA 0 5 0 10 0 20 4 20 mA Power consumption each mA board each mA input 2 W 0 1 W Auxiliary DC voltage IP15843 1 v3 M12286 1...

Page 70: ...ilter time setting of 5 ms is required M50609 2 v10 Table 18 BIM Binary input module with enhanced pulse counting capabilities Quantity Rated value Nominal range Binary inputs 16 DC voltage RL 24 30 V 48 60 V 110 125 V 220 250 V RL 20 RL 20 RL 20 RL 20 Power consumption 24 30 V 48 60 V 110 125 V 220 250 V max 0 05 W input max 0 1 W input max 0 2 W input max 0 4 W input Counter input frequency 10 p...

Page 71: ...nput max 0 2 W input max 0 4 W input max 0 5 W input Counter input frequency 10 pulses s max Oscillating signal discriminator Blocking settable 1 40 Hz Release settable 1 30 Hz Debounce filter Settable 1 20 ms Binary input operate time Debounce filter set to 0 ms 3 ms Note For compliance with surge immunity a debounce filter time setting of 5 ms is required Line differential protection RED670 1MRK...

Page 72: ... A Breaking capacity for AC cos φ 0 4 250 V 8 0 A 250 V 8 0 A Breaking capacity for DC with L R 40 ms According to IEC 61810 1 48 V 1 A 110 V 0 4 A 125 V 0 35 A 220 V 0 2 A 250 V 0 15 A 48 V 1 A 110 V 0 4 A 125 V 0 35 A 220 V 0 2 A 250 V 0 15 A Breaking capacity for DC with L R 100ms 110 V 0 3 A 110 V 0 3 A Breaking capacity for DC with resistive load 48 V 2 A 110 V 0 5 A 125 V 0 45 A 220 V 0 35 A...

Page 73: ... 0 4 A 110 125 V 0 4 A 48 60 V 0 2 A 24 30 V 0 1 A Breaking capacity for AC cos j 0 4 250 V 8 0 A 250 V 8 0 A Breaking capacity for DC with L R 40 ms According to IEC 61810 1 48 V 1 A 110 V 0 4 A 220 V 0 2 A 250 V 0 15 A 48 V 1 A 110 V 0 4 A 220 V 0 2 A 250 V 0 15 A Breaking capacity for DC with L R 100ms 110 V 0 3 A 110 V 0 3 A Breaking capacity for DC with resistive load 48 V 2 A 110 V 0 5 A 125...

Page 74: ... A 20 A Breaking capacity for DC with L R 40 ms Auto reclose scheme On 0 2 s 0 2 s on 0 2 s off 0 2 s on 20 s off 0 2 s on 30 s off 0 2 s on 120 s off for thermal dissipation 24 60 V 30 A 110 125 V 20 A 220 250 V 10 A Breaking capacity for DC with L R 40 ms According to IEC 61810 1 4 operations min and 2 min pause for thermal dissipation 6 A Breaking capacity for DC with L R 100ms 110 V 0 3 A Brea...

Page 75: ...s 30 A 10 A Making capacity at resistive load 0 2 s 1 0 s 30 A 10 A Breaking capacity for AC cos ϕ 0 4 250 V 8 A Breaking capacity for DC with L R 40 ms According to IEC 61810 1 48 V 1 A 110 V 0 4 A 125 V 0 35 A 220 V 0 2 A 250 V 0 15 A Max operations with inductive load L R 40 ms 1 000 Breaking capacity for DC with L R 100ms 110 V 0 3 A Breaking capacity for DC with resistive load 48 V 2 A 110 V ...

Page 76: ...stive load 2000 Max operations with load 1000 Max operations with no load 10000 Making capacity for DC with L R 10 ms 0 2 s 1 0 s 30 A 10 A Making capacity at resistive load 0 2 s 1 0 s 30 A 10 A Breaking capacity for AC cos j 0 4 250 V 8 0 A Breaking capacity for DC with L R 40 ms 48 V 1 A 110 V 0 4 A 125 V 0 35 A 220 V 0 2 A 250 V 0 15 A Breaking capacity for DC with L R 100ms 110 V 0 3 A Breaki...

Page 77: ...A Breaking capacity for DC with L R 40 ms According to IEC 61810 1 48 V 1 A 110 V 0 4 A 125 V 0 35 A 220 V 0 2 A 250 V 0 15 A Breaking capacity for DC with L R 100 ms 110 V 0 3 A Breaking capacity for DC with resistive load 48 V 2 A 110 V 0 5 A 125 V 0 45 A 220 V 0 35 A 250 V 0 3 A Max operations with inductive load L R 40 ms 1000 Max operations with resistive load 2000 Max operations with no load...

Page 78: ...minal range Influence Frequency dependence operate value fr 2 5 Hz for 50 Hz fr 3 0 Hz for 60 Hz 1 0 Hz Frequency dependence for distance protection operate value fr 2 5 Hz for 50 Hz fr 3 0 Hz for 60 Hz 2 0 Hz Harmonic frequency dependence 20 content 2nd 3rd and 5th harmonic of fr 2 0 Harmonic frequency dependence for distance protection 10 content 2nd 3rd and 5th harmonic of fr 10 0 Harmonic freq...

Page 79: ...B Power frequency immunity test 150 300 V 50 Hz IEC 60255 26 Zone A Conducted common mode immunity test 30 3 V 15 150 Hz IEC 61000 4 16 Level 4 Power frequency magnetic field test 1000 A m 3 s 100 A m cont IEC 61000 4 8 Level 5 Pulse magnetic field immunity test 1000 A m IEC 61000 4 9 Level 5 Damped oscillatory magnetic field test 100 A m IEC 61000 4 10 Level 5 Radiated electromagnetic field distu...

Page 80: ... 70 C IEC 60068 2 14 Damp heat test steady state Test Ca for 56 days at 40 C and humidity 93 IEC 60068 2 78 Damp heat test cyclic Test Db for 6 cycles at 25 to 55 C and humidity 93 to 95 1 cycle 24 hours IEC 60068 2 30 Table 33 CE compliance Test According to Electromagnetic compatibility EMC EN 60255 26 Low voltage LVD EN 60255 27 Table 34 Mechanical tests Test Type test values Reference standard...

Page 81: ...Accuracy Operate voltage 10 900 V I U R 1 0 of Ir at I Ir 1 0 of I at I Ir Reset ratio 95 at 30 900 V Maximum continuous power See1 Operate time at 0 to 10 x Ud Min 5 ms Max 15 ms Reset time at 10 x Ud to 0 Min 75 ms Max 95 ms Critical impulse time 2 ms typically at 0 to 10 x Ud Operate time at 0 to 2 x Ud Min 25 ms Max 35 ms Reset time at 2 x Ud to 0 Min 50 ms Max 70 ms Critical impulse time 15 m...

Page 82: ...mpensation On Off LT3CPDIF and LT6CPDIF With in zone transformer enabled and tIdMinHigh set to 0 Operate time restrained function at 0 to 10 x IdMin Min 25 ms Max 35 ms Reset time restrained function at 10 x IdMinto 0 Min 5 ms Max 15 ms Operate time unrestrained function at 0 to 10 x IdUnre Min 5 ms Max 15 ms Reset time unrestrained function at 10 x IdUnreto 0 Min 15 ms Max 30 ms Operate time unre...

Page 83: ... a single IED with two local current input groups Note Data obtained with single three phase input current group Note Data obtained with two three phase input current groups The rated symmetrical currents are applied on both sides as pre and post fault currents The fault is performed by increasing one phase current to double on one side and decreasing same phase current to zero on the other side L...

Page 84: ...n On Off LT3CPDIF and LT6CPDIF With in zone transformer enabled and tIdMinHigh set to 0 Operate time restrained function at 0 to 10 x IdMin Min 30 ms Max 50 ms Reset time restrained function at 10 x IdMinto 0 Min 10 ms Max 25 ms Operate time unrestrained function at 0 to 10 x IdUnre Min 10 ms Max 25 ms Reset time unrestrained function at 10 x IdUnreto 0 Min 20 ms Max 40 ms Operate time unrestraine...

Page 85: ... loop back mode Note Data obtained with single three phase input current group The operate and reset times for L3CPDIF are valid for the static output from SOM Note Data obtained with two three phase input current groups The rated symmetrical currents are applied on both sides as pre and post fault currents The fault is performed by increasing one phase current to double on one side and decreasing...

Page 86: ...tion On Off LT3CPDIF and LT6CPDIF With in zone transformer enabled and tIdMinHigh set to 0 Operate time restrained function at 0 to 10 x IdMin Min 25 ms Max 40 ms Reset time restrained function at 10 x IdMinto 0 Min 5 ms Max 20 ms Operate time unrestrained function at 0 to 10 x IdUnre Min 5 ms Max 20 ms Reset time unrestrained function at 10 x IdUnreto 0 Min 15 ms Max 35 ms Operate time unrestrain...

Page 87: ...le IED with 2 Mbits s communication in loop back mode Note Data obtained with single three phase input current group Note Data obtained with two three phase input current groups The rated symmetrical currents are applied on both sides as pre and post fault currents The fault is performed by increasing one phase current to double on one side and decreasing same phase current to zero on the other si...

Page 88: ... 50 Hz system 2 Min 10 ms Max 20 ms Operate time restrained function at 0 to 10 x IdMin in a 60 Hz system 2 Min 8 ms Max 17 ms Reset time restrained function at 10 x IdMin to 0 2 Min 45 ms Max 65 ms Operate time unrestrained function at 0 to 10 x IdUnre 2 Min 5 ms Max 17 ms Reset time unrestrained function at 10 x IdUnre to 0 2 Min 45 ms Max 65 ms The data in the table are valid for single IED wit...

Page 89: ...se 0 5 of Ur Independent time delay zero sequence current at 0 to 2 x Iset 0 000 60 000 s 0 2 or 35 ms whichever is greater Independent time delay low current operation at 2 x Iset to 0 0 000 60 000 s 0 2 or 35 ms whichever is greater Independent time delay low voltage operation at 2 x Uset to 0 0 000 60 000 s 0 2 or 35 ms whichever is greater Reset time delay for startup signal at 0 to 2 x Uset 0...

Page 90: ...and 85 degrees Positive sequence resistance 0 01 1000 00 Ω phase Zero sequence reactance 0 10 9000 00 Ω phase Zero sequence resistance 0 01 3000 00 Ω phase Fault resistance phase to earth 0 10 9000 00 Ω loop Fault resistance phase to phase 0 10 3000 00 Ω loop Dynamic overreach 5 at 85 degrees measured with CVT s and 0 5 SIR 30 Definite time delay Ph Ph and Ph E operation 0 000 60 000 s 0 2 or 40 m...

Page 91: ...ime 25 ms typically IEC 60255 121 Reset ratio 105 typically Reset time at 0 1 x Zreach to 2 x Zreach Min 20 ms Max 50 ms M16024 1 v12 Table 44 Phase selection quadrilateral characteristic with fixed angle FDPSPDIS Function Range or value Accuracy Minimum operate current 5 500 of IBase 1 0 of Ir at I Ir 1 0 of I at I Ir Reactive reach positive sequence 0 50 3000 00 Ω phase 2 5 static accuracy 2 0 d...

Page 92: ...to 1 5 x Zreach Min 30 ms Max 50 ms SEMOD173249 2 v8 Table 46 Full scheme distance protection quadrilateral for earth faults ZMMPDIS Function Range or value Accuracy Number of zones Max 5 with selectable direction Minimum operate current 10 30 of IBase Positive sequence reactance 0 50 3000 00 W phase 2 0 static accuracy 2 0 degrees static angular accuracy Conditions Voltage range 0 1 1 1 x Ur Curr...

Page 93: ...se Positive sequence reactance 0 10 3000 00 Ω phase 2 0 static accuracy 2 0 degrees static angular accuracy Conditions Voltage range 0 1 1 1 x Ur Current range 0 5 30 x Ir Angle at 0 degrees and 85 degrees Positive sequence resistance 0 01 1000 00 Ω phase Zero sequence reactance 0 10 9000 00 Ω phase Zero sequence resistance 0 01 3000 00 Ω phase Fault resistance phase to earth 0 10 9000 00 Ω loop F...

Page 94: ...onditions Voltage range 0 1 1 1 x Ur Current range 0 5 30 x Ir Angle at 0 degrees and 85 degrees Resistive reach positive sequence 0 10 1000 00 Ω phase Reactive reach zero sequence 0 50 9000 00 Ω phase Resistive reach zero sequence 0 50 3000 00 Ω phase Fault resistance Ph E faults forward and reverse 1 00 9000 00 Ω loop Fault resistance Ph Ph faults forward and reverse 0 50 3000 00 Ω loop Reset ra...

Page 95: ...ce reach Ph E and Ph Ph 0 01 9000 00 ohm l Dynamic overreach 5 at 85 degrees measured with CVTs and 0 5 SIR 30 IEC 60255 121 Reset ratio 105 typically Directional blinders Forward 15 120 degrees Reverse 165 60 degrees Pseudo continuous ramp 2 0 degrees IEC 60255 121 Resistance determining the load impedance area forward 0 01 5000 00 ohm p Pseudo continuous ramp 2 0 of set value Conditions Tested a...

Page 96: ...e with detected difference in operating time 0 000 60 0000 s 0 2 or 15 ms whichever is greater Conditional timer for sending the CS at power swings 0 000 60 0000 s 0 2 or 15 ms whichever is greater Conditional timer for tripping at power swings 0 000 60 0000 s 0 2 or 15 ms whichever is greater Timer for blocking the overreaching zones trip 0 000 60 0000 s 0 2 or 15 ms whichever is greater GUID 88E...

Page 97: ...1321c Acyclic 123a 132a 213a 231a 312a 321a GUID 42119BFF 1756 431C A5A1 0AB637213E96 v2 Table 56 Phase preference logic PPL2PHIZ Function Range or value Accuracy Operate value phase to phase and phase to neutral undervoltage UPN and UPP 10 90 of UBase 0 5 of Ur Reset ratio undervoltage 105 Operate value residual voltage 3U0 10 300 of UBase 0 5 of Ur at U Ur 0 5 of U at U Ur Reset ratio residual v...

Page 98: ...o fault function 0 03 120 00 s 0 2 or 30 ms whichever is greater Time delay for UI detection 0 000 60 000 s 0 2 or 30 ms whichever is greater Delay time for activation of dead line detection 0 000 60 000 s 0 2 or 30 ms whichever is greater Drop off delay time of switch onto fault function 0 000 60 000 s 0 2 or 30 ms whichever is greater Line differential protection RED670 1MRK 505 379 BEN R Versio...

Page 99: ...ignal frequency 0 1 x fr 1 0 TVE Signal magnitude Voltage phasor Current phasor 0 1 1 2 x Ur 0 5 2 0 x Ir Phase angle 180 Harmonic distortion 10 from 2nd 50th Interfering signal Magnitude Minimum frequency Maximum frequency 10 of fundamental signal 0 1 x fr 1000 Hz Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 Hitachi Energy 99 2017 2022 Hitachi Energy All rights reserved ...

Page 100: ...2 x Iset Min 15 ms Max 25 ms Reset time at 2 x Iset to 0 Min 15 ms Max 30 ms Critical impulse time 10 ms typically at 0 to 2 x Iset Operate time at 0 to 10 x Iset Min 5 ms Max 15 ms Reset time at 10 x Iset to 0 Min 25 ms Max 40 ms Critical impulse time 2 ms typically at 0 to 10 x Iset Dynamic overreach 5 at t 100 ms Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 100 Hitachi Ene...

Page 101: ...r inverse curves step 1 4 0 000 60 000 s 0 2 or 35 ms whichever is greater Inverse time characteristics see table 215 table 217 and table 219 16 curve types See table 215 table 217 and table 219 Operate time start non directional at 0 to 2 x Iset Min 15 ms Max 30 ms Reset time start non directional at 2 x Iset to 0 Min 15 ms Max 30 ms Operate time start non directional at 0 to 10 x Iset Min 5 ms M...

Page 102: ... Min 15 ms Max 25 ms Reset time at 2 x Iset to 0 Min 15 ms Max 25 ms Critical impulse time 10 ms typically at 0 to 2 x Iset Operate time at 0 to 10 x Iset Min 5 ms Max 15 ms Reset time at 10 x Iset to 0 Min 25 ms Max 35 ms Critical impulse time 2 ms typically at 0 to 10 x Iset Dynamic overreach 5 at t 100 ms Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 102 Hitachi Energy 2017...

Page 103: ...19 Second harmonic blocking 5 100 of fundamental 2 0 of Ir Minimum polarizing voltage 1 100 of UBase 0 5 of Ur Minimum polarizing current 2 100 of IBase 1 0 of Ir Real part of source Z used for current polarization 0 50 1000 00 W phase Imaginary part of source Z used for current polarization 0 50 3000 00 W phase Operate time start non directional at 0 to 2 x Iset Min 15 ms Max 30 ms Reset time sta...

Page 104: ...degrees 2 0 degrees Operate current for directional release 1 100 of IBase For RCA 60 degrees 2 5 of Ir at I Ir 2 5 of I at I Ir Minimum polarizing voltage 1 100 of UBase 0 5 of Ur Real part of negative sequence source impedance used for current polarization 0 50 1000 00 W phase Imaginary part of negative sequence source impedance used for current polarization 0 50 3000 00 W phase Operate time sta...

Page 105: ... for non directional residual overcurrent at 0 to 2 x Iset Min 40 ms Max 65 ms Reset time for non directional residual overcurrent at 2 x Iset to 0 Min 40 ms Max 65 ms Operate time for directional residual overcurrent at 0 to 2 x Iset Min 110 ms Max 160 ms Reset time for directional residual overcurrent at 2 x Iset to 0 Min 20 ms Max 60 ms Independent time delay for non directional residual overvo...

Page 106: ...io phase current 95 Operate residual current 2 200 of lBase 1 0 of Ir at I Ir 1 0 of I at I Ir Reset ratio residual current 95 Phase current level for blocking of contact function 5 200 of lBase 1 0 of Ir at I Ir 1 0 of I at I Ir Reset ratio 95 Operate time for current detection 10 ms typically Reset time for current detection 10 ms maximum Time delay for retrip at 0 to 2 x Iset 0 000 60 000 s 0 2...

Page 107: ...v10 Table 68 Pole discordance protection CCPDSC Function Range or value Accuracy Operate current 0 100 of IBase 1 0 of Ir Independent time delay between trip condition and trip signal 0 000 60 000 s 0 2 or 30 ms whichever is greater SEMOD175152 2 v11 Table 69 Directional underpower protection GUPPDUP Function Range or value Accuracy Power level for Step 1 and Step 2 0 0 500 0 of SBase 1 0 of Sr at...

Page 108: ...and k 0 000 0 01 6000 00 s 0 2 or 40 ms whichever is greater SEMOD175200 2 v9 Table 71 Broken conductor check BRCPTOC Function Range or value Accuracy Minimum phase current for operation 5 100 of IBase 1 0 of Ir Unbalance current operation 50 90 of maximum current 1 0 of Ir Independent operate time delay 0 050 60 000 s 0 2 or 45 ms whichever is greater Independent reset time delay 0 010 60 000 s 0...

Page 109: ... Peak 0 2 or 20 ms whichever is greater Operate time start at 0 to 1 2 x Iset DFT Min 15 ms Max 30 ms Peak to peak Min 10 ms Max 25 ms Peak Min 5 ms Max 20 ms Reset time start at 1 2 x Iset to 0 60 ms Operate time start at 0 to 2 x Iset DFT Min 10 ms Max 25 ms Peak to peak Min 5 ms Max 20 ms Peak Min 5 ms Max 15 ms Reset time start at 2 x Iset to 0 60 ms Operate time start at 0 to 5 x Iset DFT Min...

Page 110: ... 2 or 35 ms whichever is greater Inverse time characteristics see tables 215 and 217 13 curve types See tables 215 and 217 Minimum operate time for inverse time characteristics 0 00 60 00 s 0 2 or 35 ms whichever is greater High voltage limit voltage dependent operation 30 0 100 0 of UBase 1 0 of Ur Start undervoltage 2 0 100 0 of UBase 0 5 of Ur Reset ratio undervoltage 105 Operate time start und...

Page 111: ...0 2 or 25 ms whichever is greater Minimum pulse length duration for trip and or start outputs tPulseMin 0 02 1 00 s 0 2 or 10 ms whichever is greater Operate 3Io current level for cross country fault detection CrossCntry_IN 20 1000 of lBase 1 0 of Ir at I Ir 1 0 of I at I Ir Time delay to activate cross country fault detection tCC at 0 to 2 x Iset 0 02 1 00 s 0 2 or 25 ms whichever is greater Drop...

Page 112: ...hever is greater Definite time delay step 2 at 1 2 x Uset to 0 0 000 60 000 s 0 2 or 40ms whichever is greater Minimum operate time inverse characteristics 0 000 60 000 s 0 5 or 40ms whichever is greater Operate time start at 2 x Uset to 0 Min 15 ms Max 30 ms Reset time start at 0 to 2 x Uset Min 15 ms Max 30 ms Operate time start at 1 2 x Uset to 0 Min 5 ms Max 25 ms Reset time start at 0 to 1 2 ...

Page 113: ...te time delay high step step 2 at 0 to 1 2 x Uset 0 000 60 000 s 0 2 or 45 ms whichever is greater Minimum operate time Inverse characteristics 0 000 60 000 s 0 2 or 45 ms whichever is greater Operate time start at 0 to 2 x Uset Min 15 ms Max 30 ms Reset time start at 2 x Uset to 0 Min 15 ms Max 30 ms Operate time start at 0 to 1 2 x Uset Min 20 ms Max 35 ms Reset time start at 1 2 x Uset to 0 Min...

Page 114: ...Uset Min 20 ms Max 35 ms Reset time start at 1 2 x Uset to 0 Min 5 ms Max 25 ms Critical impulse time 10 ms typically at 0 to 2 x U set Impulse margin time 15 ms typically M13338 2 v12 Table 78 Overexcitation protection OEXPVPH Function Range or value Accuracy Operate value start 100 180 of UBase frated 0 5 of U Operate value alarm 50 120 of start level 0 5 of Ur at U Ur 0 5 of U at U Ur Operate v...

Page 115: ...ue Accuracy Voltage difference for alarm and trip 2 0 100 0 of UBase 0 5 of Ur Under voltage level 1 0 100 0 of UBase 0 5 of Ur Independent time delay for voltage differential alarm at 0 8 x UDAlarm to 1 2 x UDAlarm 0 000 60 000 s 0 2 or 40 ms whichever is greater Independent time delay for voltage differential trip at 0 8 x UDTrip to 1 2 x UDTrip 0 000 60 000 s 0 2 or 40 ms whichever is greater L...

Page 116: ...low 0 000 60 000 s 0 2 or 35 ms whichever is greater GUID C172D5EB 51E8 4FC9 B2E7 EF976872FD7E v6 Table 81 Radial feeder protection PAPGAPC Function Range or value Accuracy Residual current detection 10 150 of IBase 1 0 of Ir at I Ir 1 0 of I at I Ir Reset ratio 95 at 50 150 of IBase Operate time residual current detection at 0 to 2 x Iset Min 15 ms Max 30 ms Independent time delay to operate resi...

Page 117: ... with frequency ramp Min 75 ms Max 100 ms fr 60 Hz Start time measurement with sudden frequency change Min 20 ms Max 30 ms Start time measurement with frequency ramp Min 65 ms Max 90 ms Operate time delay tDelay 1 fr 50 Hz 0 000 60 000 s 0 2 or 200 ms whichever is greater fr 60 Hz 0 2 or 175 ms whichever is greater Voltage dependent time delay Settings UNom 50 150 of UBase UMin 50 150 of UBase Exp...

Page 118: ...Disengaging time 1 fr 50 Hz Start time measurement with sudden frequency change Min 20 ms Max 30 ms Start time measurement with frequency ramp Min 75 ms Max 100 ms fr 60 Hz Start time measurement with sudden frequency change Min 20 ms Max 30 ms Start time measurement with frequency ramp Min 65 ms Max 90 ms Operate time delay tDelay 1 fr 50 Hz 0 000 60 000 s 0 2 or 200 ms whichever is greater fr 60...

Page 119: ...rement with sudden frequency change from RestoreFreq 0 02 Hz to RestoreFreq 0 02 Hz fr 60 Hz 0 2 or 100 ms whichever is greater Start time fr 50 Hz Gs 0 05 0 50 Hz s Tested frequency slope 1 2 2 0 5 0 10 0 x Gs Min 110 ms Max 290 ms Gs 1 00 Hz s Tested frequency slope 1 2 2 0 5 0 x Gs Min 180 ms Max 300 ms Gs 3 00 6 00 10 00 Hz s Tested frequency slope 1 2 2 0 x Gs Min 300 ms Max 390 ms fr 60 Hz G...

Page 120: ...z s Test points 10 20 30 50 and 100 of the time delay setting range fr 50 Hz 0 000 60 000 s 0 2 or 220 ms whichever is greater fr 60 Hz 0 2 or 180 ms whichever is greater Reset time delay tReset Test conditions Gs 0 2 Hz s Frequency slope 0 4 Hz s fr 50 Hz 0 000 60 000 s 0 2 or 220 ms whichever is greater fr 60 Hz 0 2 or 180 ms whichever is greater The settings and test conditions are in accordanc...

Page 121: ...tep 1 2 0 00 6000 00 s 0 2 or 35 ms whichever is greater Overcurrent non directional Start time at 0 to 2 x Iset Min 15 ms Max 30 ms Reset time at 2 x Iset to 0 Min 15 ms Max 30 ms Start time at 0 to 10 x Iset Min 5 ms Max 20 ms Reset time at 10 x Iset to 0 Min 20 ms Max 35 ms Undercurrent Start time at 2 x Iset to 0 Min 15 ms Max 30 ms Reset time at 0 to 2 x Iset Min 15 ms Max 30 ms Overcurrent I...

Page 122: ...ristics see table 230 3 curve types See table 230 High and low voltage limit voltage dependent operation step 1 2 1 0 200 0 of UBase 1 0 of Ur at U Ur 1 0 of U at U Ur Directional function Settable NonDir forward and reverse Relay characteristic angle 180 to 180 degrees 2 0 degrees Relay operate angle 1 to 90 degrees 2 0 degrees Reset ratio overcurrent 95 Reset ratio undercurrent 105 Reset ratio o...

Page 123: ...on Range or value Accuracy Undervoltage Critical impulse time 10 ms typically at 1 2 x Uset to 0 8 x Uset Impulse margin time 15 ms typically Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 Hitachi Energy 123 2017 2022 Hitachi Energy All rights reserved ...

Page 124: ... Ur Operate phase current 1 100 of IBase 0 5 of Ir Operate phase dead line voltage 1 100 of UBase 0 5 of Ur Operate phase dead line current 1 100 of IBase 0 5 of Ir Operate time start 1 ph at 1 x Ur to 0 Min 10 ms Max 25 ms Reset time start 1 ph at 0 to 1 x Ur Min 15 ms Max 30 ms GUID E2EA8017 BB4B 48B0 BEDA E71FEE353774 v5 Table 88 Fuse failure supervision VDSPVC Function Range or value Accuracy ...

Page 125: ...es Vector shift mode 60ms GUID ED3FE722 1F29 4340 94E9 6C907C4474F2 v3 Table 90 Current based delta supervision DELISPVC Function Range or value Accuracy Minimum current 5 0 50 0 of IBase 1 0 of Ir at I Ir 1 0 of I at I Ir DelI 10 0 500 0 of IBase Instantaneous 1 cycle Instantaneous 2 cycle mode 20 of Ir at I Ir 20 of I at I Ir RMS DFT Mag mode 10 of Ir at I Ir 10 of I at I Ir Second harmonic bloc...

Page 126: ...onizing 15 30 degrees 2 0 degrees Breaker closing pulse duration 0 050 1 000 s 0 2 or 15 ms whichever is greater tMaxSynch which resets synchronizing function if no close has been made before set time 0 000 6000 00 s 0 2 or 35 ms whichever is greater Minimum time to accept synchronizing conditions 0 000 60 000 s 0 2 or 35 ms whichever is greater Voltage high limit for energizing check 50 0 120 0 o...

Page 127: ... Circuit breaker closing pulse duration tPulse 0 000 60 000 s 0 2 or 15 ms whichever is greater Reclaim time tReclaim 0 00 6000 00 s 0 2 or 15 ms whichever is greater Maximum wait time for release from master tWaitForMaster 0 00 6000 00 s 0 2 or 15 ms whichever is greater Reset time for reclosing inhibit tInhibit 0 000 60 000 s 0 2 or 45 ms whichever is greater Wait time after close command before...

Page 128: ...8 Table 94 Phase segregated scheme communication logic for distance protection ZPCPSCH Function Range or value Accuracy Scheme type Intertrip Permissive UR Permissive OR Blocking Co ordination time for blocking communication scheme 0 000 60 000 s 0 2 or 15 ms whichever is greater Minimum duration of a carrier send signal 0 000 60 000 s 0 2 or 15 ms whichever is greater M16039 1 v16 Table 95 Curren...

Page 129: ...A7 v1 Table 98 Local acceleration logic ZCLCPSCH Function Range or value Accuracy Operate current LoadCurr 1 100 of IBase 1 0 of Ir Operate current MinCurr 1 100 of IBase 1 0 of Ir Delay time on pick up for current release 0 000 60 000 s 0 2 or 35 ms whichever is greater Delay time on drop off for current release 0 000 60 000 s 0 2 or 35 ms whichever is greater Delay time on pick up for MinCurr va...

Page 130: ...voltage 10 ms typically at 1 2 x Uset to 0 8 x Uset Impulse margin time undervoltage 15 ms typically Operate value overvoltage 1 200 of UBase 0 5 of Ur at U Ur 0 5 of U at U Ur Critical impulse time overvoltage 10 ms typically at 0 8 x Uset to 1 2 x Uset Impulse margin time overvoltage 15 ms typically Independent time delay for undervoltage functionality at 1 2 x Uset to 0 8 x Uset 0 000 60 000 s ...

Page 131: ...is greater The stated accuracy is valid for voltage levels up to 300V secondary GUID 7A8E7F49 F079 42A0 8685 20288FAD5982 v5 Table 105 Zero sequence overvoltage protection LCZSPTOV Function Range or value Accuracy Operate value zero sequence overvoltage 1 200 of UBase 0 5 of Ur at U Ur 0 5 of U at U Ur Reset ratio zero sequence overvoltage 95 at 10 200 of UBase Operate time start at 0 to 2 x Uset ...

Page 132: ...whichever is greater Transient overreach start function 10 at τ 100 ms GUID 9F739808 04CA 4988 ABBC 1A444297FDB5 v5 Table 107 Zero sequence overcurrent protection LCZSPTOC Function Range or value Accuracy Operate value zero sequence overcurrent 3 2500 of IBase 1 0 of Ir at I Ir 1 0 of I at I Ir Reset ratio zero sequence overcurrent 95 at 50 2500 of IBase Operate time start at 0 to 2 x Iset Min 15 ...

Page 133: ...x Iset 0 000 60 000 s 0 2 or 30 ms whichever is greater GUID CE2C6F0A DF49 4AAF 80F0 9CDCBB08E755 v5 Table 109 Three phase undercurrent LCP3PTUC Function Range or value Accuracy Operate value undercurrent 1 00 100 00 of IBase 1 0 of Ir Reset ratio undercurrent 105 at 50 00 100 00 of IBase Start time at 2 x Iset to 0 Min 15 ms Max 30 ms Reset time at 0 to 2 x Iset Min 10 ms Max 25 ms Critical impul...

Page 134: ...UID 3AB1EE95 51BF 4CC4 99BD F4ECDAACB75A v3 Table 113 Number of TMAGAPC instances Function Quantity with cycle time 3 ms 8 ms 100 ms TMAGAPC 6 6 GUID A05AF26F DC98 4E62 B96B E75D19F20767 v2 Table 114 Number of ALMCALH instances Function Quantity with cycle time 3 ms 8 ms 100 ms ALMCALH 5 GUID 70B7357D F467 4CF5 9F73 641A82D334F5 v2 Table 115 Number of WRNCALH instances Function Quantity with cycle...

Page 135: ...h cycle time Range or Value Accuracy 3 ms 8 ms 100 ms PULSETIMER 10 10 20 0 000 90000 000 s 0 5 10 ms GUID BE6FD540 E96E 4F15 B2A2 12FFAE6C51DB v2 Table 123 Number of RSMEMORY instances Logic block Quantity with cycle time 3 ms 8 ms 100 ms RSMEMORY 10 10 20 GUID 7A0F4327 CA83 4FB0 AB28 7C5F17AE6354 v2 Table 124 Number of SRMEMORY instances Logic block Quantity with cycle time 3 ms 8 ms 100 ms SRME...

Page 136: ...block Quantity with cycle time 3 ms 8 ms 100 ms INVERTERQT 20 100 GUID 88B27B3C 26D2 47AF 9878 CC19018171B1 v1 Table 132 Number of ORQT instances Logic block Quantity with cycle time 3 ms 8 ms 100 ms ORQT 20 100 GUID 61263951 53A8 4113 82B5 3DB3BF0D9449 v1 Table 133 Number of PULSETIMERQT instances Logic block Quantity with cycle time Range or Value Accuracy 3 ms 8 ms 100 ms PULSETIMERQT 10 30 0 0...

Page 137: ...ND 80 40 100 OR 80 40 100 PULSETIMER 20 20 49 GATE 49 TIMERSET 34 30 49 XOR 10 10 69 LLD 49 SRMEMORY 10 10 110 INV 80 40 100 RSMEMORY 10 10 20 GUID 65A2876A F779 41C4 ACD7 7662D1E7F1F2 v4 Table 139 Number of B16I instances Function Quantity with cycle time 3 ms 8 ms 100 ms B16I 6 4 8 GUID 3820F464 D296 4CAD 8491 F3F997359D79 v2 Table 140 Number of BTIGAPC instances Function Quantity with cycle tim...

Page 138: ...GAPC 4 4 4 GUID CEA332FF 838D 42B7 AEFC C1E87809825E v4 Table 145 Number of INTCOMP instances Function Quantity with cycle time 3 ms 8 ms 100 ms INTCOMP 10 10 10 GUID 3FDD7677 1D86 42AD A545 B66081C49B47 v4 Table 146 Number of REALCOMP instances Function Quantity with cycle time 3 ms 8 ms 100 ms REALCOMP 10 10 10 GUID A05B5CAE 209B 4564 9125 D45EC28CDB95 v1 Table 147 Number of HOLDMINMAX instances...

Page 139: ... ms 8 ms 100 ms POL_REC 20 Table 154 Number of RAD_DEG instances Function Quantity with cycle time 3 ms 8 ms 100 ms RAD_DEG 20 Table 155 Number of CONST_REAL instances Function Quantity with cycle time 3 ms 8 ms 100 ms CONST_REAL 10 Table 156 Number of REALSEL instances Function Quantity with cycle time 3 ms 8 ms 100 ms REALSEL 5 Table 157 Number of STOREINT instances Function Quantity with cycle ...

Page 140: ...le time 3 ms 8 ms 100 ms STOREREAL 10 Table 159 Number of DEG_RAD instances Function Quantity with cycle time 3 ms 8 ms 100 ms DEG_RAD 20 Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 140 Hitachi Energy 2017 2022 Hitachi Energy All rights reserved ...

Page 141: ...10 to 300 V 0 1 4 0 x Ir 0 5 of Sr at S 0 5 x Sr 0 5 of S at S 0 5 x Sr 100 to 220 V 0 5 2 0 x Ir 0 2 of S Power factor cos φ 10 to 300 V 0 1 4 0 x Ir 0 02 100 to 220 V 0 5 2 0 x Ir 0 01 GUID 5E04B3F9 E1B7 4974 9C0B DE9CD4A2408F v6 Table 161 Current measurement CMMXU Function Range or value Accuracy Current at symmetrical load 0 1 4 0 Ir 0 3 of Ir at I 0 5 Ir 0 3 of I at I 0 5 Ir Phase angle at sy...

Page 142: ... I 4 0 Ir GUID 47094054 A828 459B BE6A D7FA1B317DA7 v6 Table 165 Voltage sequence measurement VMSQI Function Range or value Accuracy Voltage positive sequence U1 10 to 300 V 0 5 of U at U 50 V 0 2 of U at U 50 V Voltage zero sequence 3U0 10 to 300 V 0 5 of U at U 50 V 0 2 of U at U 50 V Voltage negative sequence U2 10 to 300 V 0 5 of U at U 50 V 0 2 of U at U 50 V Phase angle 10 to 300 V 0 5 degre...

Page 143: ... SSIMG Function Range or value Accuracy Pressure alarm level 1 00 100 00 10 0 of set value or 0 2 whichever is greater Pressure lockout level 1 00 100 00 10 0 of set value or 0 2 whichever is greater Temperature alarm level 40 00 200 00 2 5 of set value or 1 whichever is greater Temperature lockout level 40 00 200 00 2 5 of set value or 1 whichever is greater Time delay for pressure alarm 0 000 60...

Page 144: ... greater GUID B6799420 D726 460E B02F C7D4F1937432 v9 Table 170 Circuit breaker condition monitoring SSCBR Function Range or value Accuracy Alarm level for open and close travel time 0 200 ms 3 ms Alarm level for number of operations 0 9999 Independent time delay for spring charging time alarm 0 00 60 00 s 0 2 or 30 ms whichever is greater Independent time delay for gas pressure alarm 0 00 60 00 s...

Page 145: ...240 security events Table 176 Event counter with limit supervision L4UFCNT Function Range or value Accuracy Counter value 0 65535 Max count up speed 30 pulses s 50 duty cycle GUID F5E124E3 0B85 41AC 9830 A2362FD289F2 v1 Table 177 Running hour meter TEILGAPC Function Range or value Accuracy Time limit for alarm supervision tAlarm 0 99999 9 hours 0 1 of set value Time limit for warning supervision t...

Page 146: ... 0 at I Ir 5 0 of ITDD at I Ir Total Harmonic Distortion ITHD 0 2 to 2 X Ir 2nd order to 9th order 0 1 0 5 X Ir 5 0 GUID 2068BBA0 9026 48D0 9DEB 301BCB3C600C v3 Table 180 Voltage harmonic monitoring VHMMHAI 50 60 Hz Function Range or value Accuracy Fundamental Harmonic Frequency 0 95 to 1 05 X fr 2nd order to 9th order 0 1 0 5 X UF 2 mHz True RMS 10 to 150 V None 0 5 of U 10 to 150 V 2nd order to ...

Page 147: ...alue or range Accuracy Reactive and resistive reach 0 001 1500 000 Ω phase 2 0 static accuracy Conditions Voltage range 0 1 1 1 x Ur Current range 0 5 30 x Ir Phase selection According to input signals Table 184 Fault locator SMTRFLO Two ended Function Value or range Accuracy Fault distance 0 5 399 9 km Two ended 1 2 static accuracy or 1000 metres whichever is maximum Reactive and resistive reach ...

Page 148: ... value 1 3600 s SEMOD153707 2 v6 Table 186 Function for energy calculation and demand handling ETPMMTR Function Range or value Accuracy Energy metering kWh Export Import kvarh Export Import Input from CVMMXN No extra error at steady load Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 148 Hitachi Energy 2017 2022 Hitachi Energy All rights reserved ...

Page 149: ...C 4DC2 8AB1 3FA77343A4DE v2 Table 188 IEC 61850 9 2 communication protocol Function Value Protocol IEC 61850 9 2 Communication speed for the IEDs 100BASE FX M11927 1 v2 Table 189 LON communication protocol Function Value Protocol LON Communication speed 1 25 Mbit s M11901 1 v2 Table 190 SPA communication protocol Function Value Protocol SPA Communication speed 300 1200 2400 4800 9600 19200 or 3840...

Page 150: ...ue Communication speed 2400 19200 bauds External connectors RS 485 6 pole connector Soft ground 2 pole connector SEMOD55310 2 v15 Table 195 SFP Optical ethernet port Quantity Rated value Number of channels Up to 6 single or 3 redundant or a combination of single and redundant links for communication using any protocol Standard IEEE 802 3u 100BASE FX Type of fiber 62 5 125 mm 50 125 mm multimode OM...

Page 151: ...g tree protocol RSTP Function Value Protocol IEEE 802 1D Rapid spanning tree protocol RSTP Communication speed 100Base FX Connectors Optical type LC or Galvanic type RJ45 Supported topologies Star Ring Ring and star Maximum number of nodes in a ring 39 IEDs Performance measurements Recovery time from single link failure for 9 IEDs 1 switch is 45 ms and for 39 IEDs 1 switch is 185 ms in ring topolo...

Page 152: ...chronous Transmission rate Data rate 2 Mbit s 64 kbit s 2 Mbit s 64 kbit s 2 Mbit s 64 kbit s Clock source Internal or derived from received signal Internal or derived from received signal Internal or derived from received signal 1 depending on optical budget calculation 2 Applicable for revision r11 of MR LDCM and later 3 C37 94 originally defined just for multi mode using same header configurati...

Page 153: ...t class I protective earthed Overvoltage category III Pollution degree 2 normally only non conductive pollution occurs except that occasionally a temporary conductivity caused by condensation is to be expected Connection system SEMOD53371 1 v1 SEMOD53376 2 v6 Table 205 CT and VT circuit connectors Connector type Rated voltage and current Maximum conductor area Screw compression type 250 V AC 20 A ...

Page 154: ...ble 207 NUM Communication ports NUM 4 Ethernet ports 1 Basic 3 Optional Ethernet connection type SFP Optical LC or Galvanic RJ45 Carrier modules supported OEM LDCM GUID 4876834C CABB 400B B84B 215F65D8AF92 v3 Table 208 OEM Number of Ethernet ports OEM 2 Ethernet Ports Ethernet connection type SFP Optical LC or Galvanic RJ45 Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 154 Hit...

Page 155: ...nsparent Clock TC Accuracy According to standard IEC IEEE 61850 9 3 Number of nodes According to standard IEC IEEE 61850 9 3 Ports supported All rear Ethernet ports SEMOD55660 2 v3 Table 212 GPS time synchronization module GTM Function Range or value Accuracy Receiver 1µs relative UTC Time to reliable time reference with antenna in new position or after power loss longer than 1 month 30 minutes Ti...

Page 156: ...igh level 1 3 Vpp 3 x low level max 9 Vpp Supported formats IRIG B 00x IRIG B 12x Accuracy 10μs for IRIG B 00x and 100μs for IRIG B 12x Input impedance 100 k ohm Optical connector Optical connector IRIG B Type ST Type of fiber 62 5 125 μm multimode fiber Supported formats IRIG B 00x Accuracy 1μs Line differential protection RED670 1MRK 505 379 BEN R Version 2 2 156 Hitachi Energy 2017 2022 Hitachi...

Page 157: ...6 Long Time Inverse A 0 086 B 0 185 P 0 02 tr 4 6 Table 216 ANSI Inverse time characteristics for Line differential protection Function Range or value Accuracy Operating characteristic 1 P A t B k I EQUATION1249 SMALL V3 EN US Reset characteristic 2 1 tr t k I EQUATION1250 SMALL V1 EN US I Imeasured Iset 0 05 k 1 10 ANSI IEEE C37 112 5 0 or 40 ms whichever is greater ANSI Extremely Inverse A 28 2 ...

Page 158: ...perate characteristic æ ö ç ç è ø P A t B k I C EQUATION1370 SMALL V1 EN US Reset characteristic PR TR t k I CR EQUATION1253 SMALL V1 EN US I Imeasured Iset k 0 05 999 in steps of 0 01 A 0 005 200 000 in steps of 0 001 B 0 00 20 00 in steps of 0 01 C 0 1 10 0 in steps of 0 1 P 0 005 3 000 in steps of 0 001 TR 0 005 100 000 in steps of 0 001 CR 0 1 10 0 in steps of 0 1 PR 0 005 3 000 in steps of 0 ...

Page 159: ...ATION1253 SMALL V1 EN US I Imeasured Iset k 0 05 1 10 in steps of 0 01 A 0 005 200 000 in steps of 0 001 B 0 00 20 00 in steps of 0 01 C 0 1 10 0 in steps of 0 1 P 0 005 3 000 in steps of 0 001 TR 0 005 100 000 in steps of 0 001 CR 0 1 10 0 in steps of 0 1 PR 0 005 3 000 in steps of 0 001 Table 219 RI and RD type inverse time characteristics Function Range or value Accuracy RI type inverse charact...

Page 160: ...acy Operating characteristic 1 P A t B k I EQUATION1249 SMALL V3 EN US Reset characteristic 2 1 tr t k I EQUATION1250 SMALL V1 EN US I Imeasured Iset k 0 05 2 00 in steps of 0 01 ANSI IEEE C37 112 5 0 or 40 ms whichever is greater ANSI Extremely Inverse A 28 2 B 0 1217 P 2 0 tr 29 1 ANSI Very inverse A 19 61 B 0 491 P 2 0 tr 21 6 ANSI Normal Inverse A 0 0086 B 0 0185 P 0 02 tr 0 46 ANSI Moderately...

Page 161: ... steps of 0 001 B 0 00 20 00 in steps of 0 01 C 0 1 10 0 in steps of 0 1 P 0 005 3 000 in steps of 0 001 TR 0 005 100 000 in steps of 0 001 CR 0 1 10 0 in steps of 0 1 PR 0 005 3 000 in steps of 0 001 The parameter setting Characterist1 and 4 Reserved shall not be used since this parameter setting is for future use and not implemented yet Table 223 RI and RD type inverse time characteristics for L...

Page 162: ...20 x Iset ANSI IEEE C37 112 5 0 or 160 ms whichever is greater ANSI Extremely Inverse A 28 2 B 0 1217 P 2 0 tr 29 1 ANSI Very inverse A 19 61 B 0 491 P 2 0 tr 21 6 ANSI Normal Inverse A 0 0086 B 0 0185 P 0 02 tr 0 46 ANSI Moderately Inverse A 0 0515 B 0 1140 P 0 02 tr 4 85 Long Time Extremely Inverse A 64 07 B 0 250 P 2 0 tr 30 Long Time Very Inverse A 28 55 B 0 712 P 2 0 tr 13 46 Long Time Invers...

Page 163: ...N1253 SMALL V1 EN US I Imeasured Iset k 0 05 2 00 in steps of 0 01 A 0 005 200 000 in steps of 0 001 B 0 00 20 00 in steps of 0 01 C 0 1 10 0 in steps of 0 1 P 0 005 3 000 in steps of 0 001 TR 0 005 100 000 in steps of 0 001 CR 0 1 10 0 in steps of 0 1 PR 0 005 3 000 in steps of 0 001 Table 226 RI and RD type inverse time characteristics for Sensitive directional residual overcurrent and power pro...

Page 164: ... P 0 02 tr 4 85 Long Time Extremely Inverse A 64 07 B 0 250 P 2 0 tr 30 Long Time Very Inverse A 28 55 B 0 712 P 2 0 tr 13 46 Long Time Inverse A 0 086 B 0 185 P 0 02 tr 4 6 Table 228 IEC Inverse time characteristics for Voltage restrained time overcurrent protection Function Range or value Accuracy Operating characteristic 1 æ ö ç ç è ø P A t k I EQUATION1251 SMALL V1 EN US I Imeasured Iset 0 05 ...

Page 165: ...S k 0 05 1 10 in steps of 0 01 Type C curve 3 0 480 0 035 32 0 5 n k t U U U æ ö ç è ø IECEQUATION2421 V1 EN US k 0 05 1 10 in steps of 0 01 Programmable curve æ ö ç è ø P k A t D U U B C U EQUATION1439 SMALL V1 EN US k 0 05 1 10 in steps of 0 01 A 0 005 200 000 in steps of 0 001 B 0 50 100 00 in steps of 0 01 C 0 0 1 0 in steps of 0 1 D 0 000 60 000 in steps of 0 001 P 0 000 3 000 in steps of 0 0...

Page 166: ...ON1432 SMALL V1 EN US U Uset U Umeasured k 0 05 1 10 in steps of 0 01 Programmable curve é ù ê ú ê ú ê ú æ ö ê ú ç ëè ø û P k A t D U U B C U EQUATION1433 SMALL V1 EN US U Uset U Umeasured k 0 05 1 10 in steps of 0 01 A 0 005 200 000 in steps of 0 001 B 0 50 100 00 in steps of 0 01 C 0 0 1 0 in steps of 0 1 D 0 000 60 000 in steps of 0 001 P 0 000 3 000 in steps of 0 001 Line differential protecti...

Page 167: ... k 0 05 1 10 in steps of 0 01 Type C curve 3 0 480 32 0 5 0 035 t k U U U EQUATION1438 SMALL V2 EN US k 0 05 1 10 in steps of 0 01 Programmable curve æ ö ç è ø P k A t D U U B C U EQUATION1439 SMALL V1 EN US k 0 05 1 10 in steps of 0 01 A 0 005 200 000 in steps of 0 001 B 0 50 100 00 in steps of 0 01 C 0 0 1 0 in steps of 0 1 D 0 000 60 000 in steps of 0 001 P 0 000 3 000 in steps of 0 001 Line di...

Page 168: ...ferential protection RED670 2 2 F00 X00 A 0 0 0 0 0 0 0 0 Impedance protection B 0 0 0 0 Current protection C 00 0 00 1 0 0 0 0 0 Voltage protection Unbalance protection Frequency protection Multipurpose protection General calculation D 0 1 T 0 0 0 0 E 00 F S Secondary system supervision Control G H 0 0 0 0 0 0 0 Scheme communication Logic Monitoring Station communication K L 0 0 M 1 0 P 0 0 0 0 0...

Page 169: ...904 PC 11 0 1 Line differential protection for 6 CT sets 3 5 line ends inzone transformer LT6CPDIF 1MRK005904 RC 12 0 1 High speed line differential protection for 4 CT sets 2 3 line ends L4CPDIF 1MRK005905 NB 13 0 1 Line differential protection logic LDLPSCH 1MRK005904 SA 14 0 1 2 Additional security logic for differential protection LDRGFC 1MRK005904 TA 15 0 1 1 Only one PDIF must be ordered L4C...

Page 170: ...ilateral ZDRDIR 1MRK005907 BA 2 0 2 Distance measuring zone quad characteristic separate Ph Ph and Ph E settings ZMRPDIS ZMRAPDIS 1MRK005907 NA 12 0 5 Phase selection quadrilateral characteristic with settable angle FRPSPDIS 1MRK005907 PA 13 0 2 Alternative 5 High speed distance protection quadrilateral and mho High speed distance protection quad and mho characteristic ZMFPDIS 1MRK005907 SG 14 0 1...

Page 171: ...on VRPVOC 1MRK005910 XC 21 0 3 Average power transient earth fault protection APPTEF 1MRK006940 LA 24 0 1 Overcurrent protection with binary release BRPTOC 1MRK005910 NG 25 0 3 Table 242 Voltage protection Position 1 2 3 4 5 6 7 8 D 0 1 Table 243 Voltage functions Function Function identification Ordering no Position Available qty Selected qty Notes and rules Two step undervoltage protection UV2PT...

Page 172: ...2 Fuse failure supervision FUFSPVC 1MRK005916 BA 2 0 3 Fuse failure supervision based on voltage difference VDSPVC 1MRK005916 CA 3 0 2 Table 253 Control Position 1 2 3 4 5 6 7 8 9 10 11 H 0 0 0 0 0 0 0 Table 254 Control functions Function Function identification Ordering no Position Available qty Selected qty Notes and rules Synchrocheck energizing check and synchronizing SESRSYN 1MRK005917 AC 1 0...

Page 173: ...Function identification Ordering no Position Available qty Selected qty Notes and rules Circuit breaker condition monitoring SSCBR 1MRK005924 HA 1 00 06 Fault locator LMBRFLO 1MRK005925 XC 2 1 1 Through fault monitoring PTRSTHR 1MRK005924 TA 4 0 2 Current harmonic monitoring 3 phase CHMMHAI 1MRK005924 QB 5 0 3 Voltage harmonic monitoring 3 phase VHMMHAI 1MRK005924 SB 6 0 3 Single and double ended ...

Page 174: ...2420 CA C Wall mounting kit 1MRK002420 DA D 1 Flush mounting kit 1MRK002420 PA E Flush mounting kit IP54 mounting seal 1MRK002420 NA F Selected 1 Wall mounting not recommended with communication modules with fiber connection Table 266 Power supply module selection Power supply module Ordering no Selection Notes and rules Compression terminals 1MRK002960 GA C Ringlug terminals 1MRK002960 HA R Power...

Page 175: ...irst TRM 3IM 5A 4IP 5A 5U 110 220V 50 60Hz 1MRK002247 EB A18 A18 TRM 12I 1A 50 60Hz ring lug terminals 1MRK002247 CC B1 B1 TRM 12I 5A 50 60Hz ring lug terminals 1MRK002247 CD B2 B2 TRM 9I 1A 3U 110 220V 50 60Hz ring lug terminals 1MRK002247 BC B3 B3 TRM 9I 5A 3U 110 220V 50 60Hz ring lug terminals 1MRK002247 BD B4 B4 TRM 5I 1A 4I 5A 3U 110 220V 50 60Hz ring lug terminals 1MRK002247 BF B5 B5 TRM 6I...

Page 176: ... 3 Including a combination of maximum four modules of type BOM or SOM and six modules of type MIM Max 2 SOM possible Table 270 Maximum quantity of I O modules with ringlug terminals Note Only every second slot can be used Case sizes BIM IOM BOM SOM MIM Maximum in case 1 1 x 19 rack casing one 1 TRM 7 6 4 6 7 possible locations P3 P5 P7 P9 P11 P13 P15 1 1 x 19 rack casing two 2 TRM 5 5 4 5 5 possib...

Page 177: ...BIM 16 inputs RL220 220 250VDC 50mA 1MRK000508 CD E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 BIM 16 inputs RL220 220 250VDC 120mA 1MRK000508 CE E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 BIM 16 inputs RL24 24 30VDC 50mA enhanced pulse counting 1MRK000508 HA F F F F F F F F F F F F F F BIM 16 inputs RL48 48 60VDC 50mA enhanced pulse counting 1MRK000508 EA G G G G G G G G G G G G G G BIM 16 inputs RL1...

Page 178: ...00173 BD W W W W W W W W W W W W W W IOM with MOV 8 inputs RL 220 250 VDC 50mA 10 2 output relays 1MRK000173 CD Y Y Y Y Y Y Y Y Y Y Y Y Y Y mA input module MIM 6 channels 1MRK000284 AB R R R R R R R R R R R R R R SOM static output module 6 heavy duty static outputs 250 VDC 6 output relays 1MRK002614 CA T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 3 Selected 1 These black marks indicate the maximum numbe...

Page 179: ...ace 1MRK001608 CB N Galvanic RS485 communication module 1MRK002309 AA G G G 4 Optical short range LDCM 820 nm 1MRK002122 AB A A A A A A 5 Optical medium range LDCM 1310 nm 1MRK002311 AA B B B B B B Optical long range LDCM 1550 nm 1MRK002311 BA C C C C C C Galvanic X21 line data communication module 1MRK002307 AA E E E E Line data communication default 64kbps mode X Allow line data communication in...

Page 180: ...re options 1 2 3 RED670 2 2 Language Casing and Mounting Power supply HMI Analog system 4 5 6 7 8 9 Binary input output modules Station communication remote end serial communication and time synchronization 10 11 Position Product version 1 Notes and rules Version no 2 2 Selection for position 1 2 2 Configuration alternatives Ordering no 2 Notes and rules Line differential protection Multi breaker ...

Page 181: ...001 PP P23 11 IEC 62439 3 High availability seamless redundancy 1MRK004001 PR P24 Rapid spanning tree protocol 1MRK004001 PY P25 IEC 61850 9 2 Process Bus communication 8 merging units 1MRK004001 PT P30 Synchrophasor report 8 phasors 1MRK004001 PV P32 12 Selection for position 3 1 All fields in the ordering form do not need to be filled in 2 Only one Line differential protection has to be selected...

Page 182: ...ls 1MRK002960 HA R Power supply module 24 60 VDC 1MRK002239 AB A Power supply module 90 250 VDC 1MRK002239 BB B Selection for position 7 Human machine hardware interface Case size Ordering no 8 Notes and rules Medium size graphic display IEC keypad symbols 1 2 x 19 IEC 1MRK000028 AA B 3 4 x 19 IEC 1MRK000028 CA 1 1 x 19 IEC 1MRK000028 BA Medium size graphic display ANSI keypad symbols 1 2 x 19 ANS...

Page 183: ...RK002247 AR A13 TRM 3I 5A 3I 1A 6U 110 220V 50 60Hz compression terminals 1MRK002247 AE A16 A16 3 TRM 9I 1A 3U 110 220V 50 60Hz ring lug terminals 1MRK002247 BC B3 TRM 9I 5A 3U 110 220V 50 60Hz ring lug terminals 1MRK002247 BD B4 TRM 5I 1A 4I 5A 3U 110 220V 50 60Hz ring lug terminals 1MRK002247 BF B5 TRM 6I 1A 6U 110 220V 50 60Hz ring lug terminals 1MRK002247 AC B6 B6 2 TRM 6I 5A 6U 110 220V 50 60...

Page 184: ...mA 1MRK000508 BD D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 BIM 16 inputs RL220 220 250VDC 50mA 1MRK000508 CD E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 BIM 16 inputs RL220 220 250VDC 120mA 1MRK000508 CE E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 BIM 16 inputs RL24 24 30VDC 50mA enhanced pulse counting 1MRK000508 HA F F F F F F F F F F F F BIM 16 inputs RL48 48 60VDC 50mA enhanced pulse counting 1MRK000508 EA...

Page 185: ...25 VDC 50mA 10 2 output relays 1MRK000173 BD W W W W W W W W W W W W IOM with MOV 8 inputs RL 220 250 VDC 50mA 10 2 output relays 1MRK000173 CD Y Y Y Y Y Y Y Y Y Y Y Y mA input module MIM 6 channels 1MRK000284 AB R R R R R R R R R R R R 3 SOM static output module 6 heavy duty static outputs 250 VDC 6 output relays 1MRK002614 CA T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 4 Selection for position 10 C 1 These...

Page 186: ...CM 1550 nm C C C C C C Line data communication default 64kbps mode X 9 Allow line data communication in 2Mbps mode 1MRK007002 AA Y GPS time module 1MRK002282 AB S S S S IRIG B time synchronization module with PPS 1MRK002305 AA F F F F Selection for position 11 1 The maximum number and type of LDCM modules supported depend on the total amount of I O and communication modules in the IED 2 Max 2 LDCM...

Page 187: ... arrangements shown in the reference documentation However our proposals for suitable variants are Single breaker Single or Three Phase trip with internal neutral on current circuits ordering number RK926 315 AK Single breaker Single or Three Phase trip with external neutral on current circuits ordering number RK926 315 AC Multi breaker Single or Three Phase trip with internal neutral on current c...

Page 188: ... v1 Key switch for settings SEMOD130356 4 v7 Key switch for lock out of settings via LHMI Quantity 1MRK 000 611 A Note To connect the key switch leads with 10 A Combiflex socket on one end must be used SEMOD130267 5 v8 Mounting kit Side by side mounting kit Quantity 1MRK 002 420 Z Configuration and monitoring tools IP15162 1 v2 M15042 3 v5 Front connection cable between LHMI and PC Quantity 1MRK 0...

Page 189: ...UEN Communication protocol manual IEC 60870 5 103 IEC Quantity 1MRK 511 394 UEN Communication protocol manual LON IEC Quantity 1MRK 511 395 UEN Communication protocol manual SPA IEC Quantity 1MRK 511 396 UEN Communication protocol manual DNP ANSI Quantity 1MRK 511 391 UUS Point list manual DNP ANSI Quantity 1MRK 511 397 UUS Operation manual IEC Quantity 1MRK 500 127 UEN ANSI Quantity 1MRK 500 127 ...

Page 190: ...al IEC 1MRK 500 127 UEN ANSI 1MRK 500 127 UUS Engineering manual IEC 1MRK 511 398 UEN ANSI 1MRK 511 398 UUS Installation manual IEC 1MRK 514 026 UEN ANSI 1MRK 514 026 UUS Communication protocol manual DNP3 1MRK 511 391 UUS Communication protocol manual IEC 60870 5 103 1MRK 511 394 UEN Communication protocol manual IEC 61850 Edition 1 1MRK 511 392 UEN Communication protocol manual IEC 61850 Edition...

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Page 192: ... AB Grid Automation Products SE 721 59 Västerås Sweden Phone 46 0 10 738 00 00 https hitachienergy com protection control Scan this QR code to visit our website 1MRK 505 379 BEN 2017 2022 Hitachi Energy All rights reserved ...

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