Page 1 ® Relion 670 SERIES Line differential protection RED670 Version 2.2 Product guide...
Page 2 (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 in this document may be trademarks or registered trademarks of their respective holders.
Page 3 This document has been carefully checked by Hitachi Energy but deviations cannot be completely ruled out. In case any errors are detected, the reader is kindly requested to notify the manufacturer. Other than under explicit contractual commitments, in no event shall Hitachi Energy be responsible or liable for any loss or damage resulting from the use of this manual or the application of the equipment.
Page 4 (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...
Page 5: Table Of Contents
25. Certification..............66 11. General calculation.............46 26. Technical data............67 12. Secondary system supervision........46 27. Ordering for customized IED........168 13. Control................47 28. Ordering for pre-configured IED....... 180 14. Scheme communication..........49 29. Ordering for Accessories..........187 15. Logic................51 Hitachi Energy...
Page 6: Document Revision History
SXSWI and SXCBR. Ordering section updated. 2021-06 2.2.5 Added note to Disturbance report and IEC 60870-5-103 protocol 2022-07 2.2.5.4 Introduced RIA600, which is a software implementation of the IED LHMI panel. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 7: Application
Disturbance recording and fault locator are available to etc. The graphical configuration tool ensures simple and allow independent post-fault analysis after primary fast testing and commissioning. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 8 (C42), see Figure 2.4 been connected in the special way. On request, Hitachi Power Grids is available to support the re-configuration Optional functions are not configured but a maximum work, either directly or to do the design checking.
Page 9 ZPC PSCH ZPCW PSCH Z< Zpsb ZCRW PSCH ZCV PSOF ZMF PDIS ZMBU RPSB ZCLC PSCH ZC PSCH IEC16000199-4-en.vsdx IEC16000199 V4 EN-US Figure 1. Block diagram for configuration A42 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 10 ZPCW PSCH ZCLC PSCH ZCRW PSCH VHM MHAI ZPC PSCH Z< Zpsb ZMF PDIS ZMBU RPSB ZCV PSOF IEC16000250-4-en.vsdx IEC16000250 V4 EN-US Figure 2. Block diagram for configuration B33 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 11 VR PVOC ZPC PSCH Zpsb Z< ZCRW PSCH ZCV PSOF ZMF PDIS ZMBU RPSB ZCLC PSCH ZC PSCH IEC16000251-4-en.vsdx IEC16000251 V4 EN-US Figure 3. Block diagram for configuration B42 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 12 S CSWI SDEPSDE S XSWI PSP PPAM VTHD UTHD 2(I>/U<) VHM MHAI VR PVOC ZPC PSCH ZPCW PSCH IEC16000252-4-en.vsdx IEC16000252 V4 EN-US Figure 4. Block diagram for configuration C42 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 13: Available Functions
= option quantities manual. 3-A03 = optional function included in packages A03 (refer to ordering details) =1/2 CB application. For the pre-configured variants Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 14 Full-scheme distance protection, mho characteristic ZMMPDIS, Full-scheme distance protection, ZMMAPDIS quadrilateral for earth faults ZDMRDIR Directional impedance element for mho characteristic ZDARDIR Additional distance protection directional function for earth faults Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 15 1-B35 1-B35 1-B35 PSPPPAM Poleslip/out-of-step protection 1-B22 1-B22 1-B22 1-B24 OOSPPAM Out-of-step protection 1-B22 1-B22 1-B22 ZCVPSOF Automatic switch onto fault logic, 1-B35 1-B35 1-B35 voltage and current based Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 16 67NT Average power transient earth 1-C54 1-C54 1-C54 1-C54 fault protection BRPTOC Overcurrent protection with binary release Voltage protection UV2PTUV Two step undervoltage protection OV2PTOV Two step overvoltage protection Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 17 Rate-of-change of frequency protection 3-E04 3-E04 3-E04 3-E04 Multipurpose protection CVGAPC General current and voltage 4-F01 4-F01 4-F01 4-F01 protection General calculation SMAIHPAC Multipurpose filter 67 requires voltage 67N requires voltage Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 18 IEC 60870-5-103 I103POSCMDV IED direct commands with position for IEC 60870-5-103 I103IEDCMD IED commands for IEC 60870-5-103 I103USRCMD Function commands user defined for IEC 60870-5-103 Secondary system supervision Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 19 AND, GATE, INV, Extension logic package (see LLD, OR, Table PULSETIMER, RSMEMORY, SLGAPC, SRMEMORY, TIMERSET, VSGAPC, XOR FXDSIGN Fixed signal function block B16I Boolean to integer conversion, 16 bit Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 20 Store value for real inputs DEG_RAD Degree to radians angle converter Monitoring CVMMXN Power system measurement CMMXU Current measurement VMMXU Voltage measurement phase- phase CMSQI Current sequence measurement VMSQI Voltage sequence measurement Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 21 60870-5-103 I103USRDEF Status for user defined signals for IEC 60870-5-103 L4UFCNT Event counter with limit supervision TEILGAPC Running hour meter PTRSTHR 51TF Through fault monitoring 2-M22 2-M22 2-M22 2-M22 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 22 Requires LDCM 2Mbps Table 3. Total number of instances for basic configurable logic blocks Basic configurable logic block Total number of instances GATE PULSETIMER RSMEMORY SRMEMORY TIMERSET Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 23 Reservation function block for apparatus control RESIN1 RESIN2 POS_EVAL Evaluation of position indication XLNPROXY Proxy for signals from switching device via GOOSE GOOSEXLNRCV GOOSE function block to receive a switching device Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 24 Table 6. Total number of instances for configurable logic blocks Q/T Configurable logic blocks Q/T Total number of instances ANDQT INDCOMBSPQT INDEXTSPQT INVALIDQT INVERTERQT ORQT PULSETIMERQT RSMEMORYQT SRMEMORYQT TIMERSETQT XORQT Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 25 1MRK 505 379-BEN R Version 2.2 Table 7. Total number of instances for extended logic package Extended configurable logic block Total number of instances GATE PULSETIMER RSMEMORY SLGAPC SRMEMORY TIMERSET VSGAPC Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 26 GOOSE function block to receive an integer value GOOSEMVRCV GOOSE function block to receive a measurand value GOOSESPRCV GOOSE function block to receive a single point value ALGOS Supervision of GOOSE subscription Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 27 (see Table PHASORREPORT1, ANALOGREPORT1, BINARYREPORT1, SMAI1 - SMAI12, 3PHSUM, PMUSTATUS AP_1-AP_6 AccessPoint_ABS AP_FRONT Access point front Precision time protocol ROUTE_1-ROUTE_6 Route_ABS1-Route_ABS6 FRONTSTATUS Access point diagnostic for front Ethernet port Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 28 LDCM LDCMRecBinStat2 Receive binary status from LDCM LDCM2M_305 Receive binary status from LDCM2M_312 LDCM, 2Mbit LDCM2M_322 LDCM2M_306 Receive binary status from LDCM2M_313 remote LDCM, 2Mbit LDCM2M_323 Scheme communication Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 29 Carrier receive logic LCNSPTOV Negative sequence overvoltage protection LCZSPTOV Zero sequence overvoltage protection LCNSPTOC Negative sequence overcurrent protection LCZSPTOC Zero sequence overcurrent protection LCP3PTOC Three phase overcurrent LCP3PTUC Three phase undercurrent Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 30 Protocol reporting of binary data via IEEE 1344 and IEC/IEEE 60255-118 (C37.118) , binary 1-8 SMAI1–SMAI12 Signal matrix for analog inputs 3PHSUM Summation block 3 phase PMUSTATUS Diagnostics for IEC/IEEE 60255-118 (C37.118) 2011 and IEEE1344 protocol Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 31 SPA communication mapping SPATD Date and time via SPA protocol BCSCONF Basic communication system GBASVAL Global base values for settings PRIMVAL Primary system values SAFEFILECOPY Safe file copy function Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 32: Differential Protection
Figure 5. on. One such function block is used for a high-impedance restricted earth fault protection. Three such function blocks are used to form three-phase, phase-segregated differential protection. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 33 Figure 6. Example of application on a conventional two-terminal line L6CPDIF is used for conventional two-terminal lines with 1½ circuit breaker arrangements in both ends, as well as multi- terminal lines with up to five terminals. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 34 IEDs. The Master- channel is needed between every IED included in the same Slave condition for the differential function appears line differential protection zone. In the latter, current Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 35 It helps to reduce the probability for mal-operation of • Low voltage criterion the protection. LDRGFC is more sensitive than the main • Low current criterion protection logic to always release operation for all faults Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 36: Impedance Protection
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. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 37 Phase selection, quadrilateral characteristic with fixed angle FDPSPDIS M13139-3 v9 The operation of transmission networks today is in many cases close to the stability limit. Due to environmental Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 38 The ability to accurately and reliably classify different types of fault so that single phase tripping and autoreclosing can be used plays an important roll in today's power systems. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 39 The independent measurement of impedance for each fault phase-to-phase loops. Out of the seven zones, one zone loop together with a sensitive and reliable built-in phase has fixed directionality to reverse, one zone has fixed Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 41: Wide Area Measurement System
60255-118 (C37.118) as well as IEEE 1344 protocols. operation on the preferred phase based on the selected phase preference scheme. A number of different phase preference schemes are available. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 42: Current Protection
A second harmonic blocking level can be set for the function NS4PTOC can be set directional or non-directional and can be used to block each step individually. independently for each of the steps. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 43 DFT, Peak, and Peak-to-peak tripping of the surrounding breakers in case the own can be selected for the BRPTOC operation. breaker fails to open. CCRBRF measurement criterion can Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 44: Voltage Protection
When triggered, the function will cause functionality for overcurrent protection with undervoltage an alarm, switch in reactors, or switch out capacitor banks. seal-in. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 45: Frequency Protection
For fast tripping, scheme frequency. communication is required. Delayed tripping does not require scheme communication. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 46: Multipurpose Protection
Fuse failure supervision VDSPVC GUID-6AF2219A-264F-4971-8D03-3B8A9D0CB284 v5 Different protection functions within the protection IED operates on the basis of measured voltage at the relay point. Some example of protection functions are: Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 47: Control
• Block/deblock of updating of position indications closing time, which improves the network stability. • Substitution of position and quality indications Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 48 HMI or from an external hardware switch connected via apparatuses in the form of circuit breakers via binary output binary inputs. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 50 This short operate time enables rapid • Definite time stage for low power factor protection autoreclosing function after the fault clearance. • Individual enabling of Low active power and Low power factor functions Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 51: Logic
M15321-3 v14 The trip matrix logic (TMAGAPC) function is used to route during abnormal operation. trip signals and other logical output signals to different output contacts on the IED. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 52 • SRMEMORY function block is a flip-flop that can set or has two outputs where one is inverted. The memory reset an output from two inputs respectively. Each block Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 53 Boolean to integer conversion with logical node set in the PST. If the input is outside the set range then the representation, 16 bit (BTIGAPC) is used to transform a set Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 54: Monitoring
HMI and the standard COMTRADE format. In the COMTRADE1999 on the substation automation system about: format it is saved as a header file HDR, a configuration file Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 55 It can also be used inside the same IED, to The Trip value recorder calculates the values of all selected analog input signals connected to the Disturbance recorder Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 56 All calculations in the harmonic monitoring with four independent limits where the number of positive function are based on IEEE 1459 and IEEE 519-2014 and/or negative flanks on the input signal are counted standards. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 57: Metering
M13394-3 v7 Pulse-counter logic (PCFCNT) function counts externally point a weak spot on the line. generated binary pulses, for instance pulses coming from Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 58: Human Machine Interface
IEDs within a station automation system and in between sub-stations. A common source shall be used for IED and Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 59: Ethernet
SCHLCCH is used for communication over the rear Ethernet ports, RCHLCCH is used for redundant communications over the rear Ethernet ports and FRONTSTATUS is used for communication over the front port. All access point function Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 60: Station Communication
MMS or FTP. and is only supported in Ed. 2 mode. IEC/UCA 61850-9-2LE communication protocol GUID-C3AA21B4-730F-4327-943A-3C77102A80A0 v4 Optical Ethernet port communication standard IEC/UCA 61850-9-2LE for process bus is supported. IEC/UCA Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 61 SPA communication protocol monitor direction. This block uses the parameter SEMOD120134-5 v2 A single glass or plastic port is provided for the Hitachi FunctionType; the information number parameter is defined Power Grids SPA protocol. This allows extensions of simple for each input signal.
Page 62: Remote Communication
The LDCM then acts as an interface to 64 kbit/s and 2Mbit/s be ordered. communication channels for duplex communication between the IEDs. In 2Mbit/s mode, each LDCM can send and Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 63 SLM has two optical 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. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 64 10.47 8.81 9.74 10.04 8.10 7.50 18.36 9.15 6U, 3/4 x 19” 265.9/ 335.9/ 247.5/ 255.0/ 318.0/ 190.5/ 466.5/ 232.5/ 482.6/ 10.47 13.23 9.74 10.04 12.52 7.50 18.36 9.15 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 65 – 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 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 66: Connection Diagrams
DNP 3.0 certificate issued by 10021419-OPE/INC 16-2532 DNV GL IEEE Synchrophasor certificate IEC/IEEE 60255-118-1:2018, issued by IEEE SA Test report no.: 2020004393 * Valid for IEDs produced at factory in Sweden. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 67: Technical Data
= √3 × U × I 8. For operate and reset time testing, the default setting values of the function and BOM module are used if not explicitly stated otherwise. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 68 < 20 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 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 69 EL = (24-60) V EL ±20% EL = (90-250) V Power consumption 50 W typically Auxiliary DC power in-rush < 10 A during 0.1 s Supply interruption bridging time < 50 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 70 Binary input operate time 3 ms (Debounce filter set to 0 ms) * Note: For compliance with surge immunity a debounce filter time setting of 5 ms is required. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 71 Binary input operate time 3 ms (Debounce filter set to 0 ms) * Note: For compliance with surge immunity a debounce filter time setting of 5 ms is required. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 72 Max operations with resistive load 2000 Max operations with no load 10000 Operating time < 6 ms <= 1 ms These reed relays have been excluded from UL evaluation. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 73 Max operations with inductive load L/R ≤ 40 ms 1000 Max operations with resistive load 2000 Max operations with no load 10000 Operating time < 6 ms <= 1 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 74 Max operations with inductive load L/R ≤ 40 ms 1000 Max operations with resistive load 2000 Max operations with resistive load (On ≤ 0.2 s) 10000 Max operations with no load 10000 Operating time < 1 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 75 220 V / 0.35 A 250 V / 0.3 A Max operations with resistive load 2 000 Max operations with no load 10 000 Operating time < 6 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 77 IP15846-1 v1 Table 26. Temperature and humidity influence Parameter Reference value Nominal range Influence Ambient temperature, operate +20±5°C -25°C to +55°C 0.02%/°C value Relative humidity 45-75% 10-90% Operative range 0-95% Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 78 Harmonic frequency dependence for high impedance differential ±10.0% , 3rd and 5 harmonic of f protection (10% content) Harmonic frequency dependence for overcurrent protection ±3.0% and 5 harmonic of f Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 79 - X.21-LDCM Impulse voltage test 5 kV, 1.2/50ms, 0.5 J 1 kV, 1.2/50 ms 0.5 J: -SFP galvanic RJ45 - X.21-LDCM Insulation resistance > 100 MW at 500 VDC Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 80 Class I: Rack, flush and wall mount IEC 60255-21-2 Bump test Class I: Rack, flush and wall mount IEC 60255-21-2 Seismic test Class II: Rack mount IEC 60255-21-3 Class I: Flush and wall mount Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 81 Trip/ R should always be lower than Stabilizing resistor thermal rating to allow continuous activation during testing. If this value is exceeded, testing should be done with a transient faults. Typical value for the thermal rating of the resistor is 100W. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 83 **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. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 85 **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. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 87 **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. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 88 The fault is performed by simultaneously increasing one group's currents to 10 x I and decreasing the other group's currents to 0. dMin This data is obtained by applying one three-phase input group's currents only. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 89 (0.000-60.000) s ±0.2% or ±35 ms whichever is greater Reset time delay for startup signal at 0 to 2 x U (0.000-60.000) s ±0.2% or ±35 ms whichever is greater Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 90 Operate time 25 ms typically IEC 60255-121 Reset ratio 105% typically Reset time at 0.1 x Zreach to 2 x Min. = 20 ms Zreach Max. = 50 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 91 Fault resistance, phase-to-phase (0.50–3000.00) Ω/loop faults, forward and reverse Load encroachment criteria: Load resistance, forward and (1.00–3000.00) Ω/phase reverse (5-70) degrees Safety load impedance angle Reset ratio 105% typically Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 92 Operate time 25 ms typically IEC 60255-121 Reset ratio 105% typically Reset time at 0.1 x Zreach to 2 x Min. = 20 ms Zreach Max. = 50 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 93 Operate time 25 ms typically IEC 60255-121 Reset ratio 105% typically Reset time at 0.1 x Zreach to 2 x Min. = 20 ms Zreach Max. =50 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 94 Angle: at 0 degrees and 85 degrees Resistive reach, zero sequence (0.50–3000.00) Ω/phase Fault resistance, Ph-E faults, (1.00–9000.00) Ω/loop forward and reverse Fault resistance, Ph-Ph faults, (0.50–3000.00) Ω/loop forward and reverse Reset ratio 105% typically Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 95 ±0.2% of set value or ±35 ms whichever is greater and Ph-Ph operation Operate time 16 ms typically, IEC 60255-121 Reset time at 0.1 to 2 x Zreach Min. = 20 ms Max. = 35 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 96 ±2.0% of U Rotor start angle (90.0 - 130.0) degrees ±5.0 degrees Rotor trip angle (15.0 - 90.0) degrees ±5.0 degrees Zone 1 and Zone 2 trip counters (1 - 20) Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 97 ±0.2% or ±25 ms whichever is greater voltage at 1.2 to 0.8 x U , tOffUN Operating mode No Filter, NoPref Cyclic: 1231c, 1321c Acyclic: 123a, 132a, 213a, 231a, 312a, 321a Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 98 Delay time for activation of dead line (0.000-60.000) s ±0.2% or ±30 ms whichever is greater detection Drop-off delay time of switch onto fault (0.000-60.000) s ±0.2% or ±30 ms whichever is greater function Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 99 (0.5–2.0) x I Phase angle ± 180° Harmonic distortion 10% from 2nd – 50th Interfering signal: Magnitude 10% of fundamental signal Minimum frequency 0.1 x f Maximum frequency 1000 Hz Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 101 Critical impulse time 10 ms typically at 0 to 2 x I Impulse margin time 15 ms typically Operate frequency, directional 38-83 Hz overcurrent Operate frequency, non-directional 10-90 Hz overcurrent Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 103 10 ms typically at 0 to 2 x I Impulse margin time 15 ms typically *Note: Operate time and reset time are only valid if harmonic blocking is turned off for a step. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 104 Max. = 35 ms Critical impulse time 10 ms typically at 0 to 2 x I Impulse margin time 15 ms typically Transient overreach <10% at τ = 100 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 105 See Table 224, Table and Table Table and Table Relay characteristic angle (RCADir) (-179 to 180) degrees ±2.0 degrees Relay operate angle (ROADir) (0 to 90) degrees ±2.0 degrees Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 106 (0.000-60.000) s ±0.2% or ±15 ms whichever is greater Minimum trip pulse duration (0.010-60.000) s ±0.2% or ±5 ms whichever is greater * Valid for product version 2.2.3 or later Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 107 Independent time delay to operate for Step 1 (0.01-6000.00) s ±0.2% or ±40 ms whichever is greater and Step 2 at 2 x S to 0.5 x S and k=0.000 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 108 Start time at current change from I to 0 Min. = 80 ms Max. = 95 ms Reset time at current change from 0 to I Min. = 5 ms Max. = 20 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 110 10 ms typically at 0 to 2 x I Impulse margin time 15 ms typically Undervoltage: Critical impulse time 10ms typically at 2 x U to 0 Impulse margin time 15 ms typically Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 111 "tCircIN" at 0 to 2 x I Drop off time delay to de-activate circulating Fixed 0.5 s ±0.2% or ±25 ms whichever is greater current detection at 2 x I to 0 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 112 Reset time, start at 0 to 1.2 x U Min. = 15 ms Max. = 35 ms Critical impulse time 5 ms typically at 1.2 x U to 0 Impulse margin time 15 ms typically Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 113 Reset time, start at 1.2 x U to 0 Min. = 5 ms Max. = 25 ms Critical impulse time 10 ms typically at 0 to 2 x U Impulse margin time 15 ms typically Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 114 ±1.0% or ±45 ms, whichever is greater function Maximum time delay for inverse (0.00–9000.00) s ±1.0% or ±45 ms, whichever is greater function Alarm time delay (0.00–9000.00) ±1.0% or ±45 ms, whichever is greater Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 115 0.8 x UDAlarm to 1.2 x UDAlarm Independent time delay for voltage differential (0.000–60.000)s ±0.2% or ±40 ms whichever is greater trip at 0.8 x UDTrip to 1.2 x UDTrip Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 116 Max. = 30 ms Independent time delay to operate, voltage- (0.000 – 60.000) s ±0.2% or ±40 ms whichever is greater based phase selection at 1.2 x U to 0.8 x Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 117 Note: The stated accuracy is valid for the voltage range 50 V – 250 V secondary. The settings and test conditions are in accordance with IEC 60255-181 standard (section 6.2 – 6.7). Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 118 Note: The stated accuracy is valid for the voltage range 50 V – 250 V secondary. The settings and test conditions are in accordance with IEC 60255-181 standard (section 6.2 – 6.7). Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 119 Max. = 240 ms 1.2, 2.0, 5.0 x Gs Gs: ±3.00, ±6.00 & ±10.00 Min. = 180 ms Hz/s Max. = 300 ms Tested frequency slope: 1.2, 2.0 x Gs Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 120 Note! The stated accuracy is valid for phase-to-earth voltage range from 50 V to 250 V secondary. During testing three phase-to-earth voltages with magnitude of 110/sqrt(3)=63.5 V were always used. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 122 10 ms typically at 2 x I to 0 Impulse margin time 15 ms typically Overvoltage: Critical impulse time 10 ms typically at 0.8 x U to 1.2 x Impulse margin time 15 ms typically Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 123 Table 85. General current and voltage protection CVGAPC, continued Function Range or value Accuracy Undervoltage: Critical impulse time 10 ms typically at 1.2 x U to 0.8 x Impulse margin time 15 ms typically Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 125 Operate time for changeat Ir to (Ir + 2 x DelI>)at Ir to Instantaneous 1 cycle & Instantaneous 2 cycle mode - (Ir + 5 x DelI>) <20ms RMS & DFT Mag mode - <30ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 126 “PhaseDiff” + 2 degrees to “PhaseDiff” - 2 Max. = 30 ms degrees Operate time for energizing function when voltage jumps from 0 to 90% Min. = 70 ms – of Urated Max. = 90 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 127 (0.000-60.000) s ±0.2% or ±50 ms whichever is greater Maximum wait time for circuit breaker closing before indicating unsuccessful “tUnsucCl” (0.00-6000.00) s ±0.2% or ±45 ms whichever is greater Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 128 Delay time for current reversal (0.000-60.000) s ±0.2% or ±15 ms whichever is greater Coordination time for weak-end (0.000-60.000) s ±0.2% or ±15 ms whichever is greater infeed logic Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 129 Delay time for current reversal (0.000-60.000) s ±0.2% or ±30 ms whichever is greater Coordination time for weak-end (0.000–60.000) s ±0.2% or ±30 ms whichever is greater infeed logic Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 130 Table 103. Carrier receive logic LCCRPTRC Function Range or value Accuracy Operation mode 1 Out Of 2 2 Out Of 2 Independent time delay (0.000-60.000) s ±0.2% or ±35 ms whichever is greater Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 131 Impulse margin time, zero sequence 15 ms typically overvoltage Independent time delay to operate at 0 to (0.000-120.000) s ±0.2% or ±40 ms whichever is greater 1.2 x U Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 132 2 ms typically at 0 to 10 x I Impulse margin time, zero sequence 15 ms typically overcurrent Independent time delay at 0 to 2 x I (0.000-60.000) s ±0.2% or ±35 ms whichever is greater Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 133 10 ms typically at 2 x I to 0 Impulse margin time, undercurrent 10 ms typically Independent time delay to operate at 2 x I (0.000-60.000) s ±0.2% or ±45 ms whichever is greater Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 134 Quantity with cycle time 3 ms 8 ms 100 ms INDCALH GUID-D1179280-1D99-4A66-91AC-B7343DBA9F23 v3 Table 117. Number of AND instances Logic block Quantity with cycle time 3 ms 8 ms 100 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 135 8 ms 100 ms TIMERSET (0.000–90000.000) s ±0.5% ±10 ms GUID-0B07F78C-10BD-4070-AFF0-6EE36454AA03 v2 Table 126. Number of XOR instances Logic block Quantity with cycle time 3 ms 8 ms 100 ms Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 136 3 ms 8 ms 100 ms RSMEMORYQT GUID-341562FB-6149-495B-8A63-200DF16A5590 v1 Table 135. Number of SRMEMORYQT instances Logic block Quantity with cycle time 3 ms 8 ms 100 ms SRMEMORYQT GUID-B6231B97-05ED-40E8-B735-1E1A50FDB85F v1 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 137 Quantity with cycle time 3 ms 8 ms 100 ms BTIGAPC GUID-B45901F4-B163-4696-8220-7F8CAC84D793 v3 Table 141. Number of IB16 instances Function Quantity with cycle time 3 ms 8 ms 100 ms IB16 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 138 Quantity with cycle time 3 ms 8 ms 100 ms INT_REAL Table 149. Number of CONST_INT instances Function Quantity with cycle time 3 ms 8 ms 100 ms CONST_INT Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 139 Quantity with cycle time 3 ms 8 ms 100 ms REALSEL Table 157. Number of STOREINT instances Function Quantity with cycle time 3 ms 8 ms 100 ms STOREINT Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 140 Quantity with cycle time 3 ms 8 ms 100 ms STOREREAL Table 159. Number of DEG_RAD instances Function Quantity with cycle time 3 ms 8 ms 100 ms DEG_RAD Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 142 Min current of transducer to (-20.00 to +20.00) mA input Alarm level for input (-20.00 to +20.00) mA Warning level for input (-20.00 to +20.00) mA Alarm hysteresis for input (0.0-20.0) mA Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 143 Reset time delay for temperature alarm (0.000-60.000) s ±0.2% or ±250 ms whichever is greater Time delay for temperature lockout (0.000-60.000) s ±0.2% or ±250 ms whichever is greater Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 144 1 ms Accuracy Depending on time synchronizing M13765-1 v6 Table 172. Indications Function Value Buffer capacity Maximum number of indications presented for single disturbance Maximum number of recorded disturbances Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 145 Accuracy Operate current (50-1000)% of IBase ±1.0% of I at I ≤ I ±1.0% of I at I > I Reset ratio > 95% at (50-1000)% of IBase – Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 146 (0.1 - 0.5) X U Distortion (VTHD) Note: - Applied Voltage Fundamental - Applied Voltage Harmonic (of respective harmonics) U - Actual Voltage = RMS (U and U Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 147 • Voltage range: (0.1-1.1) x U • Current range: (0.5-30) x I • The accuracy of fault locator depends on the accuracy of line parameters in case of EnParamCor = SET mode. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 148 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 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 149 300, 1200, 2400, 4800, 9600, 19200 or 38400 Bd Slave number 1 to 899 M11921-1 v4 Table 191. IEC 60870-5-103 communication protocol Function Value Protocol IEC 60870-5-103 Communication speed 9600, 19200 Bd Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 150 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-TX Type of cable Cat5e FTP Connector Type RJ45 Communication Speed Fast Ethernet 100 Mbit/s Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 151 GUID-48F45DA2-B92E-4977-B9B8-C2FCE8091624 v1 The recovery time of a link failure on RSTP with the IEDs that are using Galvanic ports is higher than the IEDs with the Optical ports. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 152 Micro D-sub, 15-pole male, 1.27 mm (0.050") pitch Connector, ground selection 2 pole screw terminal Standard CCITT X21 Communication speed 64 kbit/s Insulation 1 kV Maximum cable length 10 m Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 153 Screw compression type 250 V AC 2.5 mm (AWG14) 2 × 1 mm (2 x AWG18) Terminal blocks suitable for ring lug terminals 300 V AC 3 mm (AWG14) Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 154 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 2 Ethernet Ports Ethernet connection type SFP Optical LC or Galvanic RJ45 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 155 26 db @ 1.6 GHz Antenna cable impedance 50 ohm Lightning protection Must be provided externally Antenna cable connector SMA in receiver end TNC in antenna end Accuracy +/-1μs Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 156 +/-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 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 157 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 Inverse A=0.086, B=0.185, P=0.02, tr=4.6 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 158 The parameter setting Characteristn = Reserved (where, n = 1 - 4) shall not be used, since this parameter setting is for future use and not implemented yet. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 159 0.236 0.339 EQUATION1137-SMALL V1 EN-US I = I measured RD type logarithmic inverse characteristic æ ö ç × ÷ 1.35 è ø EQUATION1138-SMALL V1 EN-US I = I measured Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 160 A=0.0515, B=0.1140, P=0.02, tr=4.85 ANSI Long Time Extremely Inverse A=64.07, B=0.250, P=2.0, tr=30 ANSI Long Time Very Inverse A=28.55, B=0.712, P=2.0, tr=13.46 ANSI Long Time Inverse A=0.086, B=0.185, P=0.02, tr=4.6 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 161 I = I measured RD type logarithmic inverse characteristic k = (0.05-999) in steps of 0.01 æ ö ç × ÷ 1.35 è ø EQUATION1138-SMALL V1 EN-US I = I measured Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 162 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 Inverse A=0.086, B=0.185, P=0.02, tr=4.6 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 163 0.236 0.339 EQUATION1137-SMALL V1 EN-US I = I measured RD type logarithmic inverse characteristic æ ö ç × ÷ 1.35 è ø EQUATION1138-SMALL V1 EN-US I = I measured Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 164 IEC Normal Inverse A=0.14, P=0.02 IEC Very inverse A=13.5, P=1.0 IEC Inverse A=0.14, P=0.02 IEC Extremely inverse A=80.0, P=2.0 IEC Short time inverse A=0.05, P=0.04 IEC Long time inverse A=120, P=1.0 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 165 C = (0.0-1.0) in steps of 0.1 æ ö > ç × ÷ D = (0.000-60.000) in steps of 0.001 è ø > P = (0.000-3.000) in steps of 0.001 EQUATION1439-SMALL V1 EN-US Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 167 C = (0.0-1.0) in steps of 0.1 æ ö > D = (0.000-60.000) in steps of 0.001 ç × ÷ è ø > P = (0.000-3.000) in steps of 0.001 EQUATION1439-SMALL V1 EN-US Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 168: Ordering For Customized Ied
Table 235. Product definition ordering codes Product RED670* Product version Configuration alternative Line differential protection RED670 ACT configuration No ACT configuration downloaded Ordering number Line differential protection RED670 1MRK002810-AG Table 236. Differential protection Position Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 169 Additional security logic for differential protection LDRGFC 1MRK005904-TA Only one PDIF must be ordered. L4CPDIF requires line data communication in 2Mbps mode. Required with L3CPDIF, L6CPDIF, LT3CPDIF or LT6CPDIF Table 238. Impedance protection Position Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 170 Automatic switch onto fault logic, voltage and current based ZCVPSOF 1MRK005908-AA Power swing logic PSLPSCH 1MRK005907-VA PoleSlip/Out-of-step protection PSPPPAM 1MRK005908-CB Out-of-step protection OOSPPAM 1MRK005908-GA Table 240. Current protection Position Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 171 Ordering no Position Available Selected Notes and rules identification Underfrequency protection SAPTUF 1MRK005914-AC 00-10 Overfrequency protection SAPTOF 1MRK005914-BB Rate-of-change of frequency protection SAPFRC 1MRK005914-CB Table 247. Multipurpose protection Position Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 172 1MRK005917-DZ including interlocking Control functionality for a single bay, max 15 objects (2CB), APC15 1MRK005917-EZ including interlocking Only one APC type can be ordered. Table 255. Scheme communication Position Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 173 PRP, HSR and RSTP require two SFPs placed in pairs. This functionality requires accurate time synchronization, therefore either ‘Precision Time Protocol (PTP) Time synch or GTM or IRIG-B will be required. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 174 Additional local HMI user dialogue language No additional HMI language HMI language, English US 1MRK002920-UB Selected Additional 2nd languages are continuously being added. Please get in touch with local Hitachi Power Grids sales contact. Table 264. Casing selection Casing Ordering no Selection Notes and rules 1/2 x 19"...
Page 175 TRM 3IM 5A + 4IP 5A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-ED Selected Only valid if IEC 61850-9-2 Process bus communication is selected. Maximum qty = 1 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 176 1/2 x 19” rack casing, 1, possible location: P3 one (1) TRM *) Including a combination of maximum four modules of type BOM or SOM and six modules of type MIM. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 177 1MRK000173-GD 24-30 VDC, 50mA, 10+2 output relays IOM 8 inputs, RL 1MRK000173-AE 48-60 VDC, 50mA, 10+2 output relays IOM 8 inputs, RL 1MRK000173-BE 110-125 VDC, 50mA, 10+2 output relays Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 178 SOM must not be placed in the following positions: 1/2 case slot P5, 3/4 case 1 TRM slot P10, 3/4 case 2 TRM slot P7, 1/1 case 2 TRM slot P13, 1/1 case, 1 TRM slot P16. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 179 Max 4 LDCMs can be ordered. Always place LDCM modules on the same board to support redundant communication: in P30:5 and P30:6, P31:2 and P31:3 or P32:2 and P32:3. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 180: Ordering For Pre-Configured Ied
Line differential protection, Multi breaker, 1/3 phase tripping, 2-3 line ends 1MRK004810-HG Line differential protection, Single breaker, 1/3 phase tripping, with distance protection 1MRK004810-KG ACT configuration Hitachi Power Grids standard configuration Selection for position #2 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 181 HMI language, English US 1MRK002920-UB Selection for position #4 Additional 2nd languages are continuously being added. Please get in touch with local Hitachi Power Grids sales contact. Casing Ordering no Notes and rules 1/2 x 19" rack casing, 1 TRM 1MRK000151-VA 3/4 x 19"...
Page 182 1MRK000030-CA 1/1 x 19”, IEC 1MRK000030-BA Blank front, ANSI symbols 1/2 x 19", ANSI 1MRK000030-AB 3/4 x 19”, ANSI 1MRK000030-CB 1/1 x 19”, ANSI 1MRK000030-BB Selection for position #8 Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 183 TRM 3I 5A + 3I 1A + 6U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AF Selection for position #9 Only valid if IEC 61850-9-2 Process bus communication is selected. Second TRM is optional. Only for A42/C42. Second TRM is optional. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 184 1MRK000173-GD 24-30 VDC, 50mA, 10+2 output relays IOM 8 inputs, RL 1MRK000173-AE 48-60 VDC, 50mA, 10+2 output relays IOM 8 inputs, RL 1MRK000173-BE 110-125 VDC, 50mA, 10+2 output relays Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 185 SOM must not to be placed in position nearest to NUM: 1/2 case slot P5, 3/4 case 1 TRM slot P10, 3/4 case 2 TRM slot P7, 1/1 case 2 TRM slot P13, 1/1 case, 1 TRM slot P16. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 186 Max 4 LDCMs can be ordered. Always place LDCM modules on the same board to support redundant communication: P30:5, P30:6, P31:2, P31:3 or P32:2 and P32:3. For A42/B42/C42, only 2Mbps is allowed. For B33, select either 64kbps or 2Mbps; default is 64kbps. Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 187: Ordering For Accessories
AK). Please refer to Section Related documents for references to corresponding documents. Single breaker/Single or Three Phase trip with external neutral on current circuits (ordering number RK926 315- AC). Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 188 Installation manual, Commissioning manual, Application manual and Getting started guide), Connectivity packages and LED label template is always included for each IED. Specify additional quantity of IED Connect USB flash drive requested. Quantity: 1MRK 002 290-AE Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 189 1MRK 511 397-UUS Operation manual Quantity: 1MRK 500 127-UEN ANSI Quantity: 1MRK 500 127-UUS Installation manual Quantity: 1MRK 514 026-UEN ANSI Quantity: 1MRK 514 026-UUS Engineering manual Quantity: 1MRK 511 398-UEN Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 190 1MRK 511 399-UEN guideline Connection and Installation 1MRK 513 003-BEN components Test system, COMBITEST 1MRK 512 001-BEN Application guide, 1MRK 505 382-UEN Communication set-up User guide, RIA600 1MRK 511 619-UEN Hitachi Energy © 2017 - 2022 Hitachi Energy. All rights reserved...
Page 192 Hitachi Energy Sweden AB Grid Automation Products SE-721 59 Västerås, Sweden Phone +46 (0) 10 738 00 00 Scan this QR code to visit our website https://hitachienergy.com/protection-control © 2017 - 2022 Hitachi Energy. All rights reserved...

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