1MRK511404-BEN A en Product Guide Bay Control REC670 Version 2.2

—
R E L I O N ® 670 SERIES
Bay control REC670

Version 2.2
Product guide
1MRK 511 404-BEN A
Bay control REC670 2.2
Product version: 2.2.1
Contents
1. Application..................................................................... 3 14. Monitoring................................................................... 36

2. Available functions..........................................................9 15. Metering......................................................................38
3. Control......................................................................... 25 16. Human machine interface............................................39
4. Differential protection.................................................... 28 17. Basic IED functions..................................................... 39
5. Wide area measurement system...................................28 18. Ethernet...................................................................... 39
6. Current protection........................................................ 28 19. Station communication ...............................................40
7. Voltage protection........................................................ 30 20. Remote communication.............................................. 42
8. Frequency protection....................................................31 21. Hardware description.................................................. 42
9. Multipurpose protection................................................32 22. Connection diagrams.................................................. 45
10. General calculation...................................................... 32 23. Technical data............................................................. 46
11. Secondary system supervision.................................... 32 24. Ordering for customized IED......................................116
12. Scheme communication..............................................33 25. Ordering for pre-configured IED.................................127
13. Logic...........................................................................33 26. Ordering for Accessories........................................... 133
Disclaimer
The information in this document is subject to change without notice and should not be construed as a commitment by ABB. ABB assumes no responsibility for any
errors that may appear in this document. Drawings and diagrams are not binding.
© Copyright 2017 ABB.
All rights reserved.
Trademarks
ABB and Relion are registered trademarks of the ABB Group. All other brand or product names mentioned in this document may be trademarks or registered
trademarks of their respective holders.
2 ABB
1MRK 511 404-BEN A
Product version: 2.2.1 Issued: October 2017
Revision: A
1. Application Duplex communication channels for transfer of up to 192

M13637-3 v13
The Intelligent Electronic Device (IED) is used for the control, intertrip and binary signals are available on each remote-end
protection and monitoring of different types of bays in power data communication card (LDCM). Typical applications are
networks. The IED is especially suitable for applications in the communication between IEDs inside the station or with
control systems where the IEC 61850–8–1 Ed 1 or Ed 2 IEDs in a remote station as remote I/O.
station bus features of the IED can be fully utilized. It is used
for station-wide interlocking via GOOSE messages and The IED can be used in applications with the IEC/UCA
vertical client-server MMS communication to a local station or 61850-9-2LE process bus with up to eight Merging Units
remote SCADA operator workplace. This supports the (MU). Each MU has eight analogue channels, four current and
architecture with distributed control IEDs in all bays with high four voltages. Conventional input transformer module and
demands on reliability. Redundant communication is obtained Merging Unit channels can be mixed freely in your application.
through the built-in PRP and HSR features which can be used
Logic is prepared with a graphical tool. The advanced logic
in star or ringbus architectures. The IED can be used on all
capability allows special applications such as automatic
voltage levels. It is suitable for the control of all apparatuses
opening of disconnectors in multi-breaker arrangements,
in any type of switchgear arrangement.
closing of breaker rings, load transfer logics and so on. The
The control is performed from remote (SCADA/Station) graphical configuration tool ensures simple and fast testing
through the IEC 61850–8–1 Ed1 or Ed2 station and commissioning.
communication or from the built-in multi-display local HMI.
Forcing of binary inputs and outputs is a convenient way to
Cyber security measures are implemented to secure safe
test wiring in substations as well as testing configuration logic
autonomous operation of the protection and control functions
in the IEDs. Basically it means that all binary inputs and
even if simultaneous cyber attacks occur. For all common
outputs on the IED I/O modules (BOM, BIM, IOM & SOM) can
types of switchgear arrangements, there are different pre-
be forced to arbitrary values.
configurations for control and interlocking. One control IED
can be used for single bay or multi-bay applications. The Central Account Management is an authentication
control operation is based on the select-before-execute infrastructure that offers a secure solution for enforcing
principle to give highest possible security. There are access control to IEDs and other systems within a substation.
synchrocheck functions available to assist optimal breaker This incorporates management of user accounts, roles and
closing at the right instance in synchronous as well as certificates and the distribution of such, a procedure
asynchronous networks. completely transparent to the user.
A number of protection functions are available for flexibility in Flexible Product Naming allows the customer to use an IED-
use for different station types and busbar arrangements. To vendor independent IEC 61850 model of the IED. This
fulfil the user's application requirements, the IED features, for customer model will be used as the IEC 61850 data model,
example, up to six instantaneous phase and earth overcurrent but all other aspects of the IED will remain unchanged (e.g.,
functions, 4–step directional or non-directional delayed-phase names on the local HMI and names in the tools). This offers
and earth overcurrent functions, thermal overload and significant flexibility to adapt the IED to the customers'
frequency functions, two instances of 2–step under- and system and standard solution.
overvoltage functions, autorecloser functions and several SEMOD51278-4 v11
different measuring functions. This, together with the multi- Four packages have been defined for following applications:
display local HMI that can show one or more pages per
feeder allows using the IED for protection and control for up • Single breaker (double or single bus) arrangement (A30)
to six bays in a substation. • Double breaker arrangement (B30)
• 1 ½ breaker arrangement for a complete diameter (C30)
The auto-reclose for single-, two-, and/or three-phase reclose • Single breaker (double bus) arrangement with PMU
includes priority circuits for multi-breaker arrangements. It co- functionality (D30)
operates with the synchrocheck function with high-speed or
delayed reclosing. Several breaker failure functions are Optional functions are available in PCM600 Application
available to provide a breaker failure function independent Configuration Tool and can be configured by the user.
from the protection IEDs, also for a complete one- and a half Interface to analog and binary IO:s are configurable without
breaker diameter. need of configuration changes. Analog and control circuits
have been pre-defined. Other signals need to be applied as
Disturbance recording and fault locator are available to allow required for each application. The main differences between
independent post-fault analysis after primary disturbances in the packages above are the interlocking modules and the
case of a failure in the protection system. number of apparatuses to control.
ABB 3
1MRK 511 404-BEN A
Description of configuration A30

M15200-3 v7
WA1 REC670 A30 – Double busbar in single breaker arrangement 12AI (6I + 6U)
WA2 3 Control 3 Control 3 Control

S CILO S CSWI S XSWI
QB1 QB2
3 Control 3 Control 3 Control
WA2_VT MET UN
VN MMXU
QC1 WA1_VT 3 Control 3 Control 3 Control

QA1 3 Control 3 Control 3 Control MET UN 25 SC/VC

S CILO S CSWI S XCBR VN MMXU SES RSYN
QC2
LINE_CT Control
Control
Control MET I MET Isqi MET P/Q U>/I<
SSSCBR
S SCBR
SCBR C MMXU C MSQI CV MMXN FUF SPVC
3 Control 3 Control 3 Control MET W/Varh

S CILO S CSWI S XSWI ETP MMTR
QB9
3 Control 3 Control 3 Control 63 71
S CILO S CSWI S XSWI S SIMG S SIML
QC9
DFR/SER DR 3 Control 3 Control
LINE_VT DRP RDRE Q CBAY Q CRSV
MET U MET Usqi MET UN

V MMXU V MSQI VN MMXU
Other Functions available from the function library
46 Iub> 52PD PD 87 INd/I 21FL FL 27 3U< 3 Control 94 1 0 84 84

BRC PTOC CC PDSC CCS SPVC LMB RFLO LOV PTUV R ESIN SMP PTRC TCL YLTC TCM YLTC
60 Ud>
VDC PTOV
Optional Functions
50BF 3I>BF 2(I>/U<) 85 85 50N IN>> 51N_67N 4(IN>) 32 P> 37 P< 87 Id>
CC RBRF CV GAPC EC PSCH ECRW PSCH EF PIOC EF4 PTOC GOP PDOP GUP PDUP HZ PDIF
26 θ> 26 θ> 46I2 4(I2>) 51_67 4(3I>) 59 2(3U>) 50 3I>> 59N 2(U0>) 81 df/dt<>
LC PTTR LF PTTR NS4 PTOC OC4 PTOC OV2 PTOV PH PIOC PMU REP ROV2 PTOV SA PFRC
81 f> 81 f< 67N IN> 79 5(0 1) 50STB 3I>STB 49 θ> 90 U↑↓ 90 U↑↓ 27 2(3U<)
SA PTOF SA PTUF SDE PSDE SMB RREC STB PTOC TR PTTR TR1 ATCC TR8 ATCC UV2 PTUV
60 Ud> 51V 2(I>/U<) 85 85

VD SPVC VR PVOC ZCLC PSCH ZC PSCH ZCRW PSCH
IEC05000837-5-en.vsd
IEC05000837 V5 EN-US
Figure 1. Configuration diagram for configuration A30
4 ABB
1MRK 511 404-BEN A
Description of configuration B30

M15200-12 v5
WA1
REC670 B30 - Double breaker arrangement 12AI (6I + 6U)
WA2

WA2_VT
QB1 QB2
3 Control 3 Control 3 Control MET UN 25 SC/VC
WA1_VT S CILO S CSWI S XSWI VN MMXU SES RSYN
3 Control 3 Control 3 Control MET UN 25 SC/VC

QA1 QA2
S CILO S CSWI S XCBR
LINE_CT1 Control
Control
Control
SSSSCBR
SCBR
SCBR
MET I MET Isqi U>/I<
LINE_CT2 C MMXU C MSQI FUF SPVC

Control
Control
Control
SSSSCBR
SCBR
SCBR
3 Control 3 Control 3 Control MET P/Q

QB61 QB62
S CILO S CSWI S XSWI CV MMXN



QB9 S CILO S CSWI S XSWI
QC9
DFR/SER DR 3 Control 3 Control 63 71
LINE_VT DRP RDRE Q CBAY Q CRSV S SIMG S SIML


BRC PTOC CC PSDC CCS SPVC LMB RFLO LOV PTUV R ESIN SMP PTRC TCL YLTC TCM YLTC
60 Ud>
VDC PTOV
Optional Functions
26 θ 26 θ 46I2 4(I2>) 51_67 4(3I>) 59 2(3U>) 50 3I>> 59N 2(U0>) 81 df/dt<>

LC PTTR LF PTTR NS4 PTOC OC4 PTOC OV2 PTOV PH PIOC PMU REP ROV2 PTOV SA PFRC
f> f< θ U↑↓ U↑↓ 2(3U<)

↓
81 81 67N IN> 79 5(0 1) 50STB 3I>STB 49 90 90 27

SA PTOF SA PTUF SDE PSDE SMB RREC STB PTOC TR PTTR TR1 ATCC TR8 ATCC UV2 PTUV
60 Ud> 51V 2(I>/U<) 85 85

VD SPVC VR PVOC ZCLC PSCH ZC PSCH ZCRW PSCH
=IEC05000838=5=en=Original.vsd
Figure 2. Configuration diagram for configuration B30
ABB 5
1MRK 511 404-BEN A
Description of configuration C30

M15200-24 v5
WA1
REC670C30 – Complete one-and a half breaker diameter arrangement 24AI (6I + 6U, 6I+6U)
QB1 3 Control 3 Control 3 Control

WA1_VT
WA1_QA1 3 Control 3 Control 3 Control MET UN 25 SC

25 SC
25 SC/VC
SES RSYN
SES RSYN
WA1_CT Control
Control
Control
SSSCBR
S SCBR
SCBR
MET I MET Isqi MET P/Q U>/I<
Σ
C MMXU C MSQI CV MMXN FUF SPVC
Control
Control
Control
WA1_QB6
SSSCBR
S SCBR
SCBR
LINE1_QB9

QB61 S CILO S CSWI S XSWI
LINE1_QC9
LINE1_VT
TIE_QA1
3 Control 3 Control 3 Control MET U MET Usqi MET UN
S CILO S CSWI S XCBR V MMXU V MSQI VN MMXU
TIE_CT
MET I MET Isqi MET P/Q U>/I<
Control
Control
Σ
Control C MMXU C MSQI CV MMXN FUF SPVC
QB62
SSSCBR
S SCBR
SCBR
LINE2_QB9
WA2_QB6 S CILO S CSWI S XSWI

WA2_CT
LINE2_QC9
3 Control 3 Control 3 Control DFR/SER DR
LINE2_VT S CILO S CSWI S XSWI DRP RDRE
3 Control 3 Control 3 Control MET U MET Usqi MET UN

S CILO S CSWI S XSWI V MMXU V MSQI VN MMXU
3 Control 3 Control 3 Control 63 71

WA2_QA1 S CILO S CSWI S XCBR S SIMG S SIML
WA2_VT
3 Control 3 Control 3 Control MET UN

S CILO S CSWI S XSWI VN MMXU
QB2
3 Control 3 Control
WA2 Q CBAY Q CRSV

46 Iub> 52PD PD 87 INd/I 21FL FL 27 3U< 3 Control 94 1 0 84 84 60 Ud>
BRC PTOC CC PDSC CCS SPVC LMB RFLO LOV PTUV R ESIN SMP PTRC TCL YLTC TCM YLTC VDC PTOV
Optional Functions
50BF 3I>BF U</I> 85 85 50N IN>> 51N_67N 4(IN>) 32 P> 37 P< 87 Id> 26 θ>
CC RBRF CV GAPC EC PSCH ECRW PSCH EF PIOC EF4 PTOC GOP PDOP GUP PDUP HZ PDIF LC PTTR
26 θ> 46I2 4(I2>) 51_67 4(3I>) 59 2(3U>) 50 3I>> 59N 2(U0>) 81 df/dt<> 81 f> 81 f<
LF PTTR NS4 PTOC OC4 PTOC OV2 PTOV PH PIOC PMU REP ROV2 PTOV SA PFRC SA PTOF SA PTUF
67N IN> 79 5(0 1) 50STB 3I>STB 49 θ> 90 U↑↓ 90 U↑↓ 27 2(3U<) 60 Ud> 51V 2(I>/U<)
↓
SDE PSDE SMB RREC STB PTOC TR PTTR TR1 ATCC TR8 ATCC UV2 PTUV VD SPVC VR PVOC ZCLC PSCH
85 85
ZC PSCH ZCRW PSCH
Figure 3. Configuration diagram for configuration C30
6 ABB
1MRK 511 404-BEN A
Description of configuration D30

GUID-15D86A4C-4D37-432E-8DC2-518814830097 v1
WA1 REC670 D30 – Double busbar in single breaker arrangement with PMU functionality
12AI (6I + 6U)
WA2 3 Control 3 Control 3 Control

QB1 QB2
WA2_VT MET UN
VN MMXU
QC1 WA1_VT 3 Control 3 Control 3 Control
QA1 3 Control 3 Control 3 Control MET UN 25 SC/VC

QC2
LINE_CT Control
Control
Control MET I MET Isqi MET P/Q U>/I<
SSCBR
S
S SCBR
SCBR C MMXU C MSQI CV MMXN FUF SPVC

QB9

QC9 Pha sor data
DFR/SER DR 3 Control 3 Control IEEE Std 1344
LINE_VT DRP RDRE Q CBAY Q CRSV PMU REP IEEE Std C37.118


BRC PTOC CC PDSC CCS SPVC LMB RFLO LOV PTUV R ESIN SMP PTRC TCL YLTC TCM YLTC
60 Ud>
VDC PTOV
Optional Functions
26 θ> 26 θ> 46I2 4(I2>) 51_67 4(3I>) 59 2(3U>) 50 3I>> 59N 2(U0>) 81 df/dt<> 81 f>
LC PTTR LF PTTR NS4 PTOC OC4 PTOC OV2 PTOV PH PIOC ROV2 PTOV SA PFRC SA PTOF
81 f< 67N IN> 79 5(0 1) 50STB 3I>STB 49 θ> 90 U↑↓ 90 U↑↓ 27 2(3U<) 60 Ud>
SA PTUF SDE PSDE SMB RREC STB PTOC TR PTTR TR1 ATCC TR8 ATCC UV2 PTUV VD SPVC
51V 2(I>/U<) 85 85
VR PVOC ZCLC PSCH ZC PSCH ZCRW PSCH
IEC16000194=IEC16000194=1=en=Original
.vsdx
Figure 4. Configuration diagram for configuration D30
GUID-79B8BC84-4AAB-44E7-86CD-FF63098B009D v2
ABB 7
1MRK 511 404-BEN A
The basic delivery includes one binary input module and one are specific to the system, object or application. Optional
binary output module, which is sufficient for the default functions and optional IO ordered will not be configured at
configured IO to trip and close circuit breaker. All IEDs can be delivery. It should be noted that the standard only includes
reconfigured with the help of the application configuration tool one binary input and one binary output module and only the
in PCM600. The IED can be adapted to special applications key functions such as tripping are connected to the outputs
and special logic can be developed, such as logic for in the signal matrix tool. The required total IO must be
automatic opening of disconnectors and closing of ring bays, calculated and specified at ordering.
automatic load transfer from one busbar to the other, and so
on. The configurations are as far as found necessary provided
with application comments to explain why the signals have
The basic IED configuration is provided with the signal matrix, been connected in the special way. On request, ABB is
single line diagram and the application configuration prepared available to support the re-configuration work, either directly
for the functions included in the product by default. All or to do the design checking.
parameters should be verified by the customer, since these
8 ABB
1MRK 511 404-BEN A
2. Available functions
GUID-F5776DD1-BD04-4872-BB89-A0412B4B5CC3 v1
are not exposed to the user or do not need
to be configured are not described in this
The following tables list all the functions manual.
available in the IED. Those functions that
Main protection functions

GUID-66BAAD98-851D-4AAC-B386-B38B57718BD2 v13
Table 1. Example of quantities
2 = number of basic instances

0-3 = option quantities
3-A03 = optional function included in packages A03 (refer to ordering details)
IEC 61850 or ANSI Function description Bay control

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
Differential protection
HZPDIF 87 High impedance differential protection, 0-6 3-A02 3-A02 6-A07 3-A02
single phase
ABB 9
1MRK 511 404-BEN A
Back-up protection functions

GUID-A8D0852F-807F-4442-8730-E44808E194F0 v13

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
Current protection
PHPIOC 50 Instantaneous phase overcurrent 0-6 1-C51 2-C52 2-C53 1-C51

protection
OC4PTOC 51_671) Directional phase overcurrent protection, 0-6 1-C51 2-C52 2-C53 1-C51
four steps
EFPIOC 50N Instantaneous residual overcurrent 0-6 1-C51 2-C52 2-C53 1-C51
protection
EF4PTOC 51N Directional residual overcurrent 0-6 1-C51 2-C52 2-C53 1-C51
67N2) protection, four steps
NS4PTOC 46I2 Four step directional negative phase 0-6 1-C51 2-C52 2-C53 1-C51
sequence overcurrent protection
SDEPSDE 67N Sensitive directional residual overcurrent 0-6 1-C16 1–C16 1-C16 1-C16
and power protection
LCPTTR 26 Thermal overload protection, one time 0-6 1-C51 1-C52 2-C53 1-C51
constant, Celsius
LFPTTR 26 Thermal overload protection, one time 0-6 1-C51 1-C52 2-C53 1-C51
constant, Fahrenheit
TRPTTR 49 Thermal overload protection, two time 0-6 1-C51 1-C52 2-C53 1-C51
constants
CCRBRF 50BF Breaker failure protection 0-6 1-C51 2-C52 3-C53 1-C51
STBPTOC 50STB Stub protection 0-6 1-B27 2-B25 2-B25 1-B27
CCPDSC 52PD Pole discordance protection 0-6 1 2 3 1
GUPPDUP 37 Directional underpower protection 0-2 1-C35 1-C35 1-C35 1-C35
GOPPDOP 32 Directional overpower protection 0-2 1-C35 1-C35 1-C35 1-C35
BRCPTOC 46 Broken conductor check 0-1 1 1 1 1
CBPGAPC Capacitor bank protection 0-3
VRPVOC 51V Voltage restrained overcurrent protection 0-3 1-C35 1-C35 1-C35 1-C35
Voltage protection
UV2PTUV 27 Two step undervoltage protection 0-2 2-D02 2-D02 2-D02 2-D02
OV2PTOV 59 Two step overvoltage protection 0-2 2-D02 2-D02 2-D02 2-D02
ROV2PTOV 59N Two step residual overvoltage protection 0-2 2-D02 2-D02 2-D02 2-D02
VDCPTOV 60 Voltage differential protection 0-6 2 2 2 2
LOVPTUV 27 Loss of voltage check 0-2 1 1 2 1
Frequency protection
10 ABB
1MRK 511 404-BEN A

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
SAPTUF 81 Underfrequency protection 0-6 6-E01 6-E01 6-E01 6-E01
SAPTOF 81 Overfrequency protection 0-6 6-E01 6-E01 6-E01 6-E01
SAPFRC 81 Rate-of-change of frequency protection 0-6 6-E01 6-E01 6-E01 6-E01
FTAQFVR 81A Frequency time accumulation protection 0-12
Multipurpose protection
CVGAPC General current and voltage protection 0-9 4-F01 4-F01 4-F01 4-F01
General calculation
SMAIHPAC Multipurpose filter 0-6
1) 67 requires voltage
2) 67N requires voltage
ABB 11
1MRK 511 404-BEN A
Control and monitoring functions

GUID-E3777F16-0B76-4157-A3BF-0B6B978863DE v15

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
Control
SESRSYN 25 Synchrocheck, energizing check and synchronizing 0-6 1 2 3 1
SMBRREC 79 Autorecloser 0-6 1-H04 2-H05 3-H06 1-H04
APC10 3 Control functionality for a single bay, max 10 objects 0-1 1 1

(1CB), including interlocking (see Table 3)
APC15 3 Control functionality for a single bay, max 15 objects 0-1 1

(2CB), including interlocking (see Table 4)
APC30 3 Control functionality for up to 6 bays, max 30 objects 0-1 1

(6CBs), including interlocking (see Table 5)
QCBAY Bay control 1+5/APC30 1 1 1+5/ 1

APC30
LOCREM Handling of LR-switch positions 1+5/APC30 1 1 1+5/ 1

APC30
LOCREMCTRL LHMI control of PSTO 1 1 1 1 1
SXCBR Circuit breaker 18 3 6 18 3
TR1ATCC 90 Automatic voltage control for tap changer, single control 0-4 1-H11 1-H11 2-H16 1-H11
TR8ATCC 90 Automatic voltage control for tap changer, parallel 0-4 1-H15 1-H15 2-H18 1-H15
control
TCMYLTC 84 Tap changer control and supervision, 6 binary inputs 0-4 4 4 4 4
TCLYLTC 84 Tap changer control and supervision, 32 binary inputs 0-4 4 4 4 4
SLGAPC Logic rotating switch for function selection and LHMI 15 15 15 15 15

presentation
VSGAPC Selector mini switch 30 30 30 30 30
DPGAPC Generic communication function for Double Point 16 16 16 16 16

indication
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 4 4 4 4 4
I103CMD Function commands for IEC 60870-5-103 1 1 1 1 1
I103GENCMD Function commands generic for IEC 60870-5-103 50 50 50 50 50
I103POSCMD IED commands with position and select for IEC 50 50 50 50 50

60870-5-103
I103POSCMDV IED direct commands with position for IEC 60870-5-103 50 50 50 50 50
I103IEDCMD IED commands for IEC 60870-5-103 1 1 1 1 1
I103USRCMD Function commands user defined for IEC 60870-5-103 4 4 4 4 4
Secondary system
supervision
12 ABB
1MRK 511 404-BEN A

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
CCSSPVC 87 Current circuit supervision 0-6 1 2 3 1
FUFSPVC Fuse failure supervision 0-4 3 3 3 3
VDSPVC 60 Fuse failure supervision based on voltage difference 0-2 1-G03 1-G03 1-G03 1-G03
Logic
SMPPTRC 94 Tripping logic 12 12 12 12 12
SMAGAPC General start matrix block 12 12 12 12 12
STARTCOMB Start combinator 32 32 32 32 32
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, Basic configurable logic blocks (see Table 2) 40-420 40-420 40-420 40-420 40-420
LLD, OR,
PULSETIMER,
RSMEMORY,
SRMEMORY,
TIMERSET, XOR
ANDQT, Configurable logic blocks Q/T (see Table 6) 0-1 1 1 1 1

INDCOMBSPQT,
INDEXTSPQT,
INVALIDQT,
INVERTERQT,
ORQT,
PULSETIMERQT,
RSMEMORYQT,
SRMEMORYQT,
TIMERSETQT,
XORQT
AND, GATE, INV, Extension logic package (see Table 7) 0-1

LLD, OR,
PULSETIMER,
RSMEMORY,
SLGAPC,
SRMEMORY,
TIMERSET,
VSGAPC, XOR
FXDSIGN Fixed signal function block 1 1 1 1 1
B16I Boolean to integer conversion, 16 bit 18 18 18 18 18
BTIGAPC Boolean to integer conversion with logical node 16 16 16 16 16

representation, 16 bit
IB16 Integer to Boolean 16 conversion 18 18 18 18 18
ITBGAPC Integer to Boolean 16 conversion with Logic Node 16 16 16 16 16

representation
ABB 13
1MRK 511 404-BEN A

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
TEIGAPC Elapsed time integrator with limit transgression and 12 12 12 12 12

overflow supervision
INTCOMP Comparator for integer inputs 30 30 30 30 30
REALCOMP Comparator for real inputs 30 30 30 30 30
Table 2. 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 298
PULSETIMER 40
RSMEMORY 40
SRMEMORY 40
TIMERSET 60
XOR 40
14 ABB
1MRK 511 404-BEN A
Table 3. Number of function instances in APC10
Function name Function description Total number of instances
SCILO Interlocking 10
BB_ES 3
A1A2_BS 2
A1A2_DC 3
ABC_BC 1
BH_CONN 1
BH_LINE_A 1
BH_LINE_B 1
DB_BUS_A 1
DB_BUS_B 1
DB_LINE 1
ABC_LINE 1
AB_TRAFO 1
SCSWI Switch controller 10
SXSWI Circuit switch 9
QCRSV Apparatus control 2
RESIN1 1
RESIN2 59
POS_EVAL Evaluation of position indication 10
XLNPROXY Proxy for signals from switching device via 12

GOOSE
GOOSEXLNRCV GOOSE function block to receive a switching 12

device
ABB 15
1MRK 511 404-BEN A
BB_ES 3
A1A2_BS 2
A1A2_DC 3
ABC_BC 1
BH_CONN 1
BH_LINE_A 1
BH_LINE_B 1
DB_BUS_A 1
DB_BUS_B 1
DB_LINE 1
ABC_LINE 1
AB_TRAFO 1
RESIN1 1
RESIN2 59

GOOSE

device
16 ABB
1MRK 511 404-BEN A
BB_ES 6
A1A2_BS 4
A1A2_DC 6
ABC_BC 2
BH_CONN 2
BH_LINE_A 2
BH_LINE_B 2
DB_BUS_A 3
DB_BUS_B 3
DB_LINE 3
ABC_LINE 6
AB_TRAFO 4
RESIN1 1
RESIN2 59
QCBAY Bay control 5
LOCREM Handling of LR-switch positions 5

GOOSE

device
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
RSMEMORYQT 40
SRMEMORYQT 40
TIMERSETQT 40
XORQT 40
ABB 17
1MRK 511 404-BEN A
Table 7. Total number of instances for extended logic package
Extended configurable logic block Total number of instances
AND 180
GATE 49
INV 180
LLD 49
OR 180
PULSETIMER 89
RSMEMORY 40
SLGAPC 74
SRMEMORY 130
TIMERSET 109
VSGAPC 120
XOR 89
18 ABB
1MRK 511 404-BEN A

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
Monitoring
CVMMXN Power system measurement 6 6 6 6 6
CMMXU Current measurement 10 10 10 10 10
VMMXU Voltage measurement phase-phase 6 6 6 6 6
CMSQI Current sequence measurement 6 6 6 6 6
VMSQI Voltage sequence measurement 6 6 6 6 6
VNMMXU Voltage measurement phase-earth 6 6 6 6 6
AISVBAS General service value presentation of analog inputs 1 1 1 1 1
EVENT Event function 20 20 20 20 20
DRPRDRE, Disturbance report 1 1 1 1 1

A4RADR,
SPGAPC Generic communication function for Single Point 64 64 64 64 64

indication
SP16GAPC Generic communication function for Single Point 24 24 24 24 24

indication 16 inputs
MVGAPC Generic communication function for measured values 24 24 24 24 24
BINSTATREP Logical signal status report 3 3 3 3 3
RANGE_XP Measured value expander block 66 66 66 66 66
SSIMG 63 Insulation supervision for gas medium 21 21 21 21 21
SSIML 71 Insulation supervision for liquid medium 3 3 3 3 3
SSCBR Circuit breaker condition monitoring 0-18 3 6 9 3
LMBRFLO Fault locator 0-1 1 1 1 1
LOLSPTR 26/49 Transformer insulation loss of life monitoring 0-4 4-M21 4-M21 4-M21 4-M21
HS
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
I103FLTPROT Function status fault protection for IEC 60870-5-103 1 1 1 1 1
I103IED IED status for IEC 60870-5-103 1 1 1 1 1
I103SUPERV Supervison status for IEC 60870-5-103 1 1 1 1 1
I103USRDEF Status for user defined signals for IEC 60870-5-103 20 20 20 20 20
L4UFCNT Event counter with limit supervision 30 30 30 30 30
TEILGAPC Running hour meter 6 6 6 6 6
ABB 19
1MRK 511 404-BEN A

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
Metering
PCFCNT Pulse-counter logic 16 16 16 16 16
ETPMMTR Function for energy calculation and demand handling 6 6 6 6 6
20 ABB
1MRK 511 404-BEN A
Communication
GUID-5F144B53-B9A7-4173-80CF-CD4C84579CB5 v15

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
Station communication
LONSPA, SPA SPA communication protocol 1 1 1 1 1
ADE LON communication protocol 1 1 1 1 1
HORZCOMM Network variables via LON 1 1 1 1 1
RS485GEN RS485 1 1 1 1 1
DNPGEN DNP3.0 communication general protocol 1 1 1 1 1
CHSERRS485 DNP3.0 for EIA-485 communication 1 1 1 1 1

protocol
CH1TCP, CH2TCP, DNP3.0 for TCP/IP communication protocol 1 1 1 1 1

CH3TCP, CH4TCP
CHSEROPT DNP3.0 for TCP/IP and EIA-485 1 1 1 1 1

communication protocol
MSTSER DNP3.0 serial master 1 1 1 1 1
MST1TCP, DNP3.0 for TCP/IP communication protocol 1 1 1 1 1

MST2TCP,
MST3TCP, MST4TCP
DNPFREC DNP3.0 fault records for TCP/IP and 1 1 1 1 1

EIA-485 communication protocol
IEC 61850-8-1 IEC 61850 1 1 1 1 1
GOOSEINTLKRCV Horizontal communication via GOOSE for 59 59 59 59 59

interlocking
GOOSEBINRCV GOOSE binary receive 16 16 16 16 16
GOOSEDPRCV GOOSE function block to receive a double 64 64 64 64 64

point value
GOOSEINTRCV GOOSE function block to receive an integer 32 32 32 32 32

value
GOOSEMVRCV GOOSE function block to receive a 60 60 60 60 60

measurand value
GOOSESPRCV GOOSE function block to receive a single 64 64 64 64 64

point value
VCTRSEND Horizontal communication via GOOSE for 1 1 1 1 1

VCTR
GOOSEVCTRRCV Horizontal communication via GOOSE for 7 7 7 7 7

VCTR
GOOSEVCTRCONF GOOSE VCTR configuration for send and 1 1 1 1 1

receive
MULTICMDRCV, Multiple command and transmit 60/10 60/10 60/10 60/10 60/10
MULTICMDSND
ABB 21
1MRK 511 404-BEN A

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
OPTICAL103 IEC 60870-5-103 Optical serial 1 1 1 1 1

communication
RS485103 IEC 60870-5-103 serial communication for 1 1 1 1 1

RS485
AGSAL Generic security application component 1 1 1 1 1
LD0LLN0 IEC 61850 LD0 LLN0 1 1 1 1 1
SYSLLN0 IEC 61850 SYS LLN0 1 1 1 1 1
LPHD Physical device information 1 1 1 1 1
PCMACCS IED configuration protocol 1 1 1 1 1
SECALARM Component for mapping security events on 1 1 1 1 1

protocols such as DNP3 and IEC103
FSTACCS Field service tool access 1 1 1 1 1
IEC 61850-9-2 Process bus 0-1 1-P30 1-P30 1-P30 1-P30

communication, 8 merging units
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 0-1 1-P24 1-P24 1-P24 1-P24
redundancy
PMUCONF, Synchrophasor report, 8 phasors (see 0-1 1-P32 1-P32 1-P32 1

PMUREPORT, Table 8)
PHASORREPORT1,
ANALOGREPORT1
BINARYREPORT1,
SMAI1 - SMAI12
3PHSUM
PMUSTATUS
PTP Precision time protocol 1 1 1 1 1
FRONTSTATUS Access point diagnostic for front Ethernet 1 1 1 1 1

port
SCHLCCH Access point diagnostic for non-redundant 6 6 6 6 6

Ethernet port
RCHLCCH Access point diagnostic for redundant 3 3 3 3 3

Ethernet ports
DHCP DHCP configuration for front access point 1 1 1 1 1
QUALEXP IEC 61850 quality expander 96 96 96 96 96
Remote communication
BinSignRec1_1 Binary signal transfer receive 3/3/6 3/3/6 3/3/6 3/3/6 3/3/6
BinSignRec1_2
BinSignReceive2
22 ABB
1MRK 511 404-BEN A

function name
REC670 (C30)
REC670 (D30)
REC670 (B30)
REC670 (A30)
REC670
(Customized)
BinSignTrans1_1 Binary signal transfer transmit 3/3/6 3/3/6 3/3/6 3/3/6 3/3/6
BinSignTrans1_2
BinSignTransm2
BinSigRec1_12M Binary signal transfer, 2Mbit receive/ 3 3 3 3 3

BinSigRec1_22M transmit
BinSigTran1_12M
BinSigTran1_22M
LDCMTRN Transmission of analog data from LDCM 1 1 1 1 1
LDCMTRN_2M Transmission of analog data from LDCM, 6 6 6 6 6

2Mbit
LDCMRecBinStat1 Receive binary status from remote LDCM 6/3/3 6/3/3 6/3/3 6/3/3 6/3/3
LDCMRecBinStat2
LDCMRecBinStat3
LDCMRecBinS2_2M Receive binary status from LDCM, 2Mbit 3 3 3 3 3
LDCMRecBinS3_2M Receive binary status from remote LDCM, 3 3 3 3 3

2Mbit
Scheme communication
ZCPSCH 85 Scheme communication logic with delta 0-1 1-K01 1-K01 1-K01 1-K01
based blocking scheme signal transmit
ZCRWPSCH 85 Current reversal and weak-end infeed logic 0-1 1-K01 1-K01 1-K01 1-K01
for distance protection
ZCLCPSCH Local acceleration logic 0-1 1-K01 1-K01 1-K01 1-K01
ECPSCH 85 Scheme communication logic for residual 0-1 1-C51 1-C52 1-C53 1-C51
overcurrent protection
ECRWPSCH 85 Current reversal and weak-end infeed logic 0-1 1-C51 1-C52 1-C53 1-C51
for residual overcurrent protection
Table 8. Number of function instances in Synchrophasor report, 8 phasors
Function name Function description Number of instances
PMUCONF Configuration parameters for C37.118 2011 and IEEE1344 protocol 1
PMUREPORT Protocol reporting via IEEE 1344 and C37.118 1
PHASORREPORT1 Protocol reporting of phasor data via IEEE 1344 and C37.118, phasors 1-8 1
ANALOGREPORT1 Protocol reporting of analog data via IEEE 1344 and C37.118, analogs 1-8 1
BINARYREPORT1 Protocol reporting of binary data via IEEE 1344 and C37.118, binary 1-8 1
SMAI1–SMAI12 Signal matrix for analog inputs 1
3PHSUM Summation block 3 phase 6
PMUSTATUS Diagnostics for C37.118 2011 and IEEE1344 protocol 1
ABB 23
1MRK 511 404-BEN A
Basic IED functions

GUID-C8F0E5D2-E305-4184-9627-F6B5864216CA v12
Table 9. Basic IED functions
IEC 61850 or function Description

name
INTERRSIG Self supervision with internal event list
TIMESYNCHGEN Time synchronization module
BININPUT, SYNCHCAN, Time synchronization

SYNCHGPS,
SYNCHCMPPS,
SYNCHLON,
SYNCHPPH,
SYNCHPPS, SNTP,
SYNCHSPA
PTP Precision time protocol
TIMEZONE Time synchronization
IRIG-B Time synchronization
SETGRPS Number of setting groups
ACTVGRP Parameter setting groups
TESTMODE Test mode functionality
CHNGLCK Change lock function
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 check
AUTHMAN Authority management
FTPACCS FTP access with password
GBASVAL Global base values for settings
ALTMS Time master supervision
ALTIM Time management
COMSTATUS Protocol diagnostic
24 ABB
1MRK 511 404-BEN A
Table 10. Local HMI functions
IEC 61850 or function ANSI Description

name
LHMICTRL Local HMI signals
LANGUAGE Local human machine language
SCREEN Local HMI Local human machine screen behavior
FNKEYTY1–FNKEYTY5 Parameter setting function for HMI in PCM600

FNKEYMD1–
FNKEYMD5
LEDGEN General LED indication part for LHMI
OPENCLOSE_LED LHMI LEDs for open and close keys
GRP1_LED1– Basic part for CP HW LED indication module

GRP1_LED15
GRP2_LED1–
GRP2_LED15
GRP3_LED1–
GRP3_LED15
3. Control • high-speed and/or delayed auto reclosing

• single and/or three phase auto reclosing
Synchrocheck, energizing check, and synchronizing • support for single or multi-breaker applications.
SESRSYN
M12480-3 v16
The Synchronizing function allows closing of asynchronous
networks at the correct moment including the breaker closing The auto recloser can be used for delayed busbar restoration.
time, which improves the network stability.
Up to five reclosing shots can be performed. The first shot
Synchrocheck, energizing check, and synchronizing can be single-, two-, and /or three-phase depending on the
(SESRSYN) function checks that the voltages on both sides of type of the fault and the selected auto reclosing mode.
the circuit breaker are in synchronism, or with at least one
Several auto reclosing functions can be provided for multi-
side dead to ensure that closing can be done safely.
breaker arrangements. A priority circuit allows one circuit
SESRSYN function includes a built-in voltage selection breaker to reclose first and the second will only close if the
scheme for double bus and 1½ breaker or ring busbar fault proved to be transient.
arrangements.
Each auto reclosing function can be configured to co-operate
Manual closing as well as automatic reclosing can be with the synchrocheck function.
checked by the function and can have different settings.
Apparatus control APC
M13444-3 v15
For systems, which can run asynchronously, a synchronizing The apparatus control functions are used for control and
feature is also provided. The main purpose of the supervision of circuit breakers, disconnectors and earthing
synchronizing feature is to provide controlled closing of circuit switches within a bay. Permission to operate is given after
breakers when two asynchronous systems are in phase and evaluation of conditions from other functions such as
can be connected. The synchronizing feature evaluates interlocking, synchrocheck, operator place selection and
voltage difference, phase angle difference, slip frequency and external or internal blockings.
frequency rate of change before issuing a controlled closing
Apparatus control features:
of the circuit breaker. Breaker closing time is a setting.
• Select-Execute principle to give high reliability
Autorecloser SMBRREC • Selection function to prevent simultaneous operation
M12390-3 v16
The auto reclosing function provides: • Selection and supervision of operator place
• Command supervision
• Block/deblock of operation
• Block/deblock of updating of position indications
ABB 25
1MRK 511 404-BEN A
• Substitution of position and quality indications Each apparatus control function has interlocking modules
• Overriding of interlocking functions included for different switchyard arrangements, where each
• Overriding of synchrocheck function handles interlocking of one bay. The interlocking
• Operation counter function is distributed to each IED and is not dependent on
• Suppression of mid position any central function. For the station-wide interlocking, the
IEDs communicate via the system-wide interbay bus (IEC
61850-8-1) or by using hard wired binary inputs/outputs. The
Two types of command models can be used:
interlocking conditions depend on the circuit configuration
• Direct with normal security
and apparatus position status at any given time.
• SBO (Select-Before-Operate) with enhanced security
For easy and safe implementation of the interlocking function,
Normal security means that only the command is evaluated the IED is delivered with standardized and tested software
and the resulting position is not supervised. Enhanced interlocking modules containing logic for the interlocking
security means that the command is evaluated with an conditions. The interlocking conditions can be altered, to
additional supervision of the status value of the control meet the customer’s specific requirements, by adding
object. The command sequence with enhanced security is configurable logic by means of the graphical configuration
always terminated by a CommandTermination service tool.
primitive and an AddCause telling if the command was
The following interlocking modules are available:
successful or if something went wrong.
• Line for double and transfer busbars, ABC_LINE
Control operation can be performed from the local HMI with
• Bus coupler for double and transfer busbars, ABC_BC
authority control if so defined.
• Transformer bay for double busbars, AB_TRAFO
M16909-3 v3
Features of the apparatus control function are: • Bus-section breaker for double busbars, A1A2_BS
• Bus-section disconnector for double busbars, A1A2_DC
• Operation of primary apparatuses • Busbar earthing switch, BB_ES
• Select-Execute principle to give high reliability • Double CB Bay, DB_BUS_A, DB_LINE, DB_BUS_B
• Selection and reservation function to prevent • 1 1/2-CB diameter, BH_LINE_A, BH_CONN, BH_LINE_B
simultaneous operation
• Selection and supervision of operator place
Switch controller SCSWI
• Command supervision M13486-3 v8
The Switch controller (SCSWI) initializes and supervises all
• Block/deblock of operation
functions to properly select and operate switching primary
• Block/deblock of updating of position indications
apparatuses. The Switch controller may handle and operate
• Substitution of position indications
on one multi-phase device or up to three one-phase devices.
• Overriding of interlocking functions
• Overriding of synchrocheck Circuit breaker SXCBR
• Pole discordance supervision
M13489-3 v6
The purpose of Circuit breaker (SXCBR) is to provide the
• Operation counter actual status of positions and to perform the control
operations, that is, pass all the commands to primary
The apparatus control function is realized by means of a
apparatuses in the form of circuit breakers via binary output
number of function blocks designated:
boards and to supervise the switching operation and position.
• Bay control QCBAY
Circuit switch SXSWI
• Switch controller SCSWI M16492-3 v6
The purpose of Circuit switch (SXSWI) function is to provide
• Circuit breaker SXCBR
the actual status of positions and to perform the control
• Circuit switch SXSWI
operations, that is, pass all the commands to primary
The three latter functions are logical nodes according to IEC apparatuses in the form of disconnectors or earthing switches
61850-8-1. To realize the reservation function also the via binary output boards and to supervise the switching
function blocks Reservation input (RESIN) and Bay reserve operation and position.
(QCRSV) are included in the apparatus control function.
Reservation function QCRSV
M13506-3 v4
Interlocking The purpose of the reservation function is primarily to transfer

interlocking information between IEDs in a safe way and to
M13531-3 v4
The interlocking function blocks the possibility to operate
primary switching devices, for instance when a disconnector prevent double operation in a bay, switchyard part, or
is under load, in order to prevent material damage and/or complete substation.
accidental human injury.
26 ABB
1MRK 511 404-BEN A
Voltage control includes many extra features such as the

Reservation input RESIN possibility to avoid simultaneous tapping of parallel
M16501-3 v5
The Reservation input (RESIN) function receives the transformers, hot stand by regulation of a transformer in a
reservation information from other bays. The number of group which regulates it to a correct tap position even though
instances is the same as the number of involved bays (up to the LV CB is open, compensation for a possible capacitor
60 instances are available). bank on the LV side bay of a transformer, extensive tap
changer monitoring including contact wear and hunting
Bay control QCBAY
M13447-3 v8
detection, monitoring of the power flow in the transformer so
The Bay control (QCBAY) function is used together with Local
that, for example, the voltage control can be blocked if the
remote and local remote control functions to handle the
power reverses, etc.
selection of the operator place per bay. QCBAY also provides
blocking functions that can be distributed to different Logic rotating switch for function selection and LHMI
apparatuses within the bay. presentation SLGAPC
SEMOD114908-4 v10
The logic rotating switch for function selection and LHMI
Proxy for signals from switching device via GOOSE
presentation (SLGAPC) (or the selector switch function block)
XLNPROXY
GUID-11F9CA1C-8E20-489B-822B-34DACC59553A v1
is used to get an enhanced selector switch functionality
The proxy for signals from switching device via GOOSE
compared to the one provided by a hardware selector switch.
(XLNPROXY) gives an internal representation of the position
Hardware selector switches are used extensively by utilities,
status and control response for a switch modelled in a
in order to have different functions operating on pre-set
breaker IED. This representation is identical to that of an
values. Hardware switches are however sources for
SXCBR or SXSWI function.
maintenance issues, lower system reliability and an extended
GOOSE function block to receive a switching device purchase portfolio. The selector switch function eliminates all
GOOSEXLNRCV these problems.
GUID-5AC7DE11-CB95-4565-A8AE-FB23D59FD717 v1
The GOOSE XLN Receive component is used to collect
Selector mini switch VSGAPC
information from another device’s XCBR/XSWI logical node SEMOD158756-5 v9
The Selector mini switch (VSGAPC) function block is a
sent over process bus via GOOSE. The GOOSE XLN Receive
multipurpose function used for a variety of applications, as a
component includes 12 different outputs (and their respective
general purpose switch.
channel valid bits) with defined names to ease the 61850
mapping of the GOOSE signals in the configuration process. VSGAPC can be controlled from the menu, from a symbol on
the single line diagram (SLD) on the local HMI or from Binary
Local remote LOCREM/Local remote control LOCREMCTRL
M17086-3 v8
inputs
The signals from the local HMI or from an external local/
remote switch are connected via the function blocks Generic communication function for Double Point indication
LOCREM and LOCREMCTRL to the Bay control QCBAY DPGAPC
function block. The parameter ControlMode in function block SEMOD55850-5 v7
Generic communication function for Double Point indication
LOCREM is set to choose if the switch signals are coming (DPGAPC) function block is used to send double point
from the local HMI or from an external hardware switch position indications to other systems, equipment or functions
connected via binary inputs. in the substation through IEC 61850-8-1 or other
communication protocols. It is especially intended to be used
Voltage control TR1ATCC/TR8ATCC , TCMYLTC/TCLYLTC
M5864-3 v12
in the interlocking station-wide logics.
Automatic voltage control for tap changer, single control
(TR1ATCC), Automatic voltage control for tap changer, Single point generic control 8 signals SPC8GAPC
parallel control (TR8ATCC), Tap changer control and The Single point generic control 8 signals (SPC8GAPC)
SEMOD176462-4 v10
supervision, 6 binary inputs (TCMYLTC) and Tap changer function block is a collection of 8 single point commands that
control and supervision, 32 binary inputs (TCLYLTC) are used can be used for direct commands for example reset of LEDs
for control of power transformers with an on-load tap or putting IED in "ChangeLock" state from remote. In this
changer. The functions provide automatic regulation of the way, simple commands can be sent directly to the IED
voltage on the secondary side of transformers or alternatively outputs, without confirmation. Confirmation (status) of the
on a load point further out in the network. result of the commands is supposed to be achieved by other
means, such as binary inputs and SPGAPC function blocks.
Control of a single transformer, as well as control of up to
The commands can be pulsed or steady with a settable pulse
eight transformers in parallel is possible. For parallel control of
time.
power transformers, three alternative methods are available:
the master-follower method, the circulating current method Automation bits, command function for DNP3.0 AUTOBITS
and the reverse reactance method. The first two methods SEMOD158591-5 v8
Automation bits function for DNP3 (AUTOBITS) is used within
require exchange of information between the parallel PCM600 to get into the configuration of the commands
transformers and this is provided for within IEC 61850-8-1. coming through the DNP3 protocol. The AUTOBITS function
ABB 27
1MRK 511 404-BEN A
plays the same role as functions GOOSEBINRCV (for IEC GUID-8DF29209-252A-4E51-9F4A-B14B669E71AB v4
61850) and MULTICMDRCV (for LON). The phasor measurement reporting block moves the phasor
calculations into an IEEE C37.118 and/or IEEE 1344
Single command, 16 signals synchrophasor frame format. The PMUREPORT block
M12446-6 v5
The IEDs can receive commands either from a substation contains parameters for PMU performance class and
automation system or from the local HMI. The command reporting rate, the IDCODE and Global PMU ID, format of the
function block has outputs that can be used, for example, to data streamed through the protocol, the type of reported
control high voltage apparatuses or for other user defined synchrophasors, as well as settings for reporting analog and
functionality. digital signals.
The message generated by the PMUREPORT function block

4. Differential protection is set in accordance with the IEEE C37.118 and/or IEEE 1344
standards.
High impedance differential protection, single phase HZPDIF
M13071-3 v13
High impedance differential protection, single phase (HZPDIF) There are settings for Phasor type (positive sequence,
functions can be used when the involved CT cores have the negative sequence or zero sequence in case of 3-phase
same turns ratio and similar magnetizing characteristics. It phasor and L1, L2 or L3 in case of single phase phasor),
utilizes an external CT secondary current summation by PMU's Service class (Protection or Measurement), Phasor
wiring. Actually all CT secondary circuits which are involved in representation (polar or rectangular) and the data types for
the differential scheme are connected in parallel. External phasor data, analog data and frequency data.
series resistor, and a voltage dependent resistor which are
both mounted externally to the IED, are also required. Synchrophasor data can be reported to up to 8 clients over
TCP and/or 6 UDP group clients for multicast or unicast
The external resistor unit shall be ordered under IED transmission of phasor data from the IED. More information
accessories in the Product Guide. regarding synchrophasor communication structure and
TCP/UDP configuration is available in Application Manual
HZPDIF can be used to protect tee-feeders or busbars,
under section C37.118 Phasor Measurement Data Streaming
reactors, motors, auto-transformers, capacitor banks and so
Protocol Configuration.
on. One such function block is used for a high-impedance
restricted earth fault protection. Three such function blocks Multiple PMU functionality can be configured in the IED,
are used to form three-phase, phase-segregated differential which can stream out same or different data at different
protection. reporting rates or different performance (service) classes.
5. Wide area measurement system 6. Current protection
Synchrophasor report, 8 phasors Instantaneous phase overcurrent protection PHPIOC

GUID-7539462D-A3D6-492D-9926-E67C5B7C72D9 v1
M12910-3 v13
The instantaneous three phase overcurrent function has a low
Configuration parameters for IEEE1344 and C37.118 protocol
transient overreach and short tripping time to allow use as a
PMUCONF
GUID-33694C62-A109-4D8F-9063-CEFA5D0E78BC v4 high set short-circuit protection function.
The IED supports the following IEEE synchrophasor
standards: Directional phase overcurrent protection, four steps
• IEEE 1344-1995 (Both measurements and data OC4PTOC
communication) Directional phase overcurrent protection, four steps
M12846-3 v17
• IEEE Std C37.118-2005 (Both measurements and data (OC4PTOC) has an inverse or definite time delay for each
communication) step.
• IEEE Std C37.118.1–2011 and C37.118.1a-2014
(Measurements) All IEC and ANSI inverse time characteristics are available
• IEEE Std C37.118.2-2011 (Data communication) together with an optional user defined time characteristic.
The directional function needs voltage as it is voltage

PMUCONF contains the PMU configuration parameters for polarized with memory. The function can be set to be
both IEEE C37.118 and IEEE 1344 protocols. This means all directional or non-directional independently for each of the
the required settings and parameters in order to establish and steps.
define a number of TCP and/or UDP connections with one or
more PDC clients (synchrophasor client). This includes port A second harmonic blocking level can be set for the function
numbers, TCP/UDP IP addresses, and specific settings for and can be used to block each step individually.
IEEE C37.118 as well as IEEE 1344 protocols.
Protocol reporting via IEEE 1344 and C37.118 PMUREPORT
28 ABB
1MRK 511 404-BEN A
NS4PTOC can also be used to provide a system backup for

Instantaneous residual overcurrent protection EFPIOC example, in the case of the primary protection being out of
M12701-3 v16
The Instantaneous residual overcurrent protection (EFPIOC) service due to communication or voltage transformer circuit
has a low transient overreach and short tripping times to failure.
allow the use for instantaneous earth-fault protection, with the
reach limited to less than the typical eighty percent of the line Directional operation can be combined together with
at minimum source impedance. EFPIOC is configured to corresponding communication logic in permissive or blocking
measure the residual current from the three-phase current teleprotection scheme. The same logic as for directional zero
inputs and can be configured to measure the current from a sequence current can be used. Current reversal and weak-
separate current input. end infeed functionality are available.
Directional residual overcurrent protection, four steps Sensitive directional residual overcurrent and power
EF4PTOC protection SDEPSDE
M13667-3 v19 SEMOD171438-5 v6
Directional residual overcurrent protection, four steps In isolated networks or in networks with high impedance
(EF4PTOC) can be used as main protection for phase-to- earthing, the earth fault current is significantly smaller than
earth faults. It can also be used to provide a system back-up, the short circuit currents. In addition to this, the magnitude of
for example, in the case of the primary protection being out of the fault current is almost independent on the fault location in
service due to communication or voltage transformer circuit the network. The protection can be selected to use either the
failure. residual current or residual power component 3U0·3I0·cos j,
for operating quantity with maintained short circuit capacity.
EF4PTOC has an inverse or definite time delay independent There is also available one nondirectional 3I0 step and one
for each step. 3U0 overvoltage tripping step.
All IEC and ANSI time-delayed characteristics are available No specific sensitive current input is needed. Sensitive
together with an optional user-defined characteristic. directional residual overcurrent and power protection
(SDEPSDE) can be set as low 0.25% of IBase.
EF4PTOC can be set to be directional or non-directional
independently for each step. Thermal overload protection, one time constant LCPTTR/
LFPTTR
IDir, UPol and IPol can be independently selected to be either M12020-4 v14
The increasing utilization of the power system closer to the
zero sequence or negative sequence.
thermal limits has generated a need of a thermal overload
A second harmonic blocking can be set individually for each protection for power lines.
step.
A thermal overload will often not be detected by other
Directional operation can be combined together with the protection functions and the introduction of the thermal
corresponding communication logic in permissive or blocking overload protection can allow the protected circuit to operate
teleprotection scheme. The current reversal and weak-end closer to the thermal limits.
infeed functionality are available as well.
The three-phase current measuring protection has an I 2 t
The residual current can be calculated by summing the three- characteristic with settable time constant and a thermal
phase currents or taking the input from the neutral CT. memory. The temperature is displayed in either Celsius or
Fahrenheit, depending on whether the function used is
Four step directional negative phase sequence overcurrent Thermal overload protection (LCPTTR) (Celsius) or (LFPTTR)
protection NS4PTOC (Fahrenheit).
GUID-485E9D36-0032-4559-9204-101539A32F47 v6
Four step directional negative phase sequence overcurrent
protection (NS4PTOC) has an inverse or definite time delay An alarm level gives early warning to allow operators to take
independent for each step separately. action well before the line is tripped.
All IEC and ANSI time delayed characteristics are available Estimated time to trip before operation, and estimated time to
together with an optional user defined characteristic. reclose after operation are presented.
The directional function is voltage polarized. Thermal overload protection, two time constants TRPTTR
M13243-3 v11
If a power transformer reaches very high temperatures the
NS4PTOC can be set directional or non-directional equipment might be damaged. The insulation within the
independently for each of the steps. transformer will experience forced ageing. As a consequence
of this the risk of internal phase-to-phase or phase-to-earth
NS4PTOC can be used as main protection for unsymmetrical
faults will increase.
fault; phase-phase short circuits, phase-phase-earth short
circuits and single phase earth faults.
ABB 29
1MRK 511 404-BEN A
The thermal overload protection estimates the internal heat Normally the own breaker is tripped to correct such a
content of the transformer (temperature) continuously. This situation. If the situation persists the surrounding breakers
estimation is made by using a thermal model of the should be tripped to clear the unsymmetrical load situation.
transformer with two time constants, which is based on
current measurement. The Pole discordance protection function (CCPDSC) operates
based on information from auxiliary contacts of the circuit
Two warning levels are available. This enables actions in the breaker for the three phases with additional criteria from
power system to be done before dangerous temperatures are unsymmetrical phase currents when required.
reached. If the temperature continues to increase to the trip
value, the protection initiates a trip of the protected Directional over/underpower protection GOPPDOP/
transformer. GUPPDUP
SEMOD175421-4 v7
The directional over-/under-power protection (GOPPDOP/
The estimated time to trip before operation is presented. GUPPDUP) can be used wherever a high/low active, reactive
or apparent power protection or alarming is required. The
Breaker failure protection CCRBRF functions can alternatively be used to check the direction of
M11550-6 v17
Breaker failure protection (CCRBRF) ensures a fast backup active or reactive power flow in the power system. There are
tripping of the surrounding breakers in case the own breaker a number of applications where such functionality is needed.
fails to open. CCRBRF can be current-based, contact-based Some of them are:
or an adaptive combination of these two conditions.
• detection of reversed active power flow
A current check with extremely short reset time is used as • detection of high reactive power flow
check criterion to achieve high security against unwanted
operation. Each function has two steps with definite time delay.
Contact check criteria can be used where the fault current Broken conductor check BRCPTOC
SEMOD171446-5 v2
through the breaker is small. The main purpose of the function Broken conductor check
(BRCPTOC) is the detection of broken conductors on
CCRBRF can be single- or three-phase initiated to allow use protected power lines and cables (series faults). Detection
with single phase tripping applications. For the three-phase can be used to give alarm only or trip the line breaker.
version of CCRBRF the current criteria can be set to operate
only if two out of four for example, two phases or one phase Voltage-restrained time overcurrent protection VRPVOC
GUID-935E1CE8-601F-40E2-8D22-2FF68420FADF v6
plus the residual current start. This gives a higher security to Voltage-restrained time overcurrent protection (VRPVOC)
the back-up trip command. function can be used as generator backup protection against
short-circuits.
CCRBRF function can be programmed to give a single- or
three-phase re-trip of its own breaker to avoid unnecessary The overcurrent protection feature has a settable current level
tripping of surrounding breakers at an incorrect initiation due that can be used either with definite time or inverse time
to mistakes during testing. characteristic. Additionally, it can be voltage controlled/
restrained.
Stub protection STBPTOC
M12902-3 v10
When a power line is taken out of service for maintenance One undervoltage step with definite time characteristic is also
and the line disconnector is opened in multi-breaker available within the function in order to provide functionality
arrangements the voltage transformers will mostly be outside for overcurrent protection with undervoltage seal-in.
on the disconnected part. The primary line distance
protection will thus not be able to operate and must be Capacitor bank protection CBPGAPC
GUID-D55CEBF7-9377-4E36-BD8B-533609048A1E v3
blocked. Shunt Capacitor Banks (SCB) are used in a power system to

provide reactive power compensation and power factor
The stub protection (STBPTOC) covers the zone between the correction. They are as well used as integral parts of Static
current transformers and the open disconnector. The three- Var Compensators (SVC) or Harmonic Filters installations.
phase instantaneous overcurrent function is released from a Capacitor bank protection (CBPGAPC) function is specially
normally open, NO (b) auxiliary contact on the line designed to provide protection and supervision features for
disconnector. SCBs.
Pole discordance protection CCPDSC

M13269-3 v15
An open phase can cause negative and zero sequence 7. Voltage protection
currents which cause thermal stress on rotating machines
Two-step undervoltage protection UV2PTUV
and can cause unwanted operation of zero sequence or M13789-3 v12
Undervoltages can occur in the power system during faults or
negative sequence current functions.
abnormal conditions. The two-step undervoltage protection
function (UV2PTUV) can be used to open circuit breakers to
30 ABB
1MRK 511 404-BEN A
prepare for system restoration at power outages or as a long- 8. Frequency protection

time delayed back-up to the primary protection.
Underfrequency protection SAPTUF
M13349-3 v13
UV2PTUV has two voltage steps, each with inverse or definite Underfrequency occurs as a result of a lack of generation in
time delay. the network.
It has a high reset ratio to allow settings close to the system Underfrequency protection (SAPTUF) measures frequency
service voltage. with high accuracy, and is used for load shedding systems,
remedial action schemes, gas turbine startup and so on.
Two step overvoltage protection OV2PTOV Separate definite time delays are provided for operate and
M13798-3 v15
Overvoltages may occur in the power system during abnormal restore.
conditions such as sudden power loss, tap changer
regulating failures, and open line ends on long lines. SAPTUF is provided with undervoltage blocking.
Two step overvoltage protection (OV2PTOV) function can be The operation is based on positive sequence voltage
used to detect open line ends, normally then combined with a measurement and requires two phase-phase or three phase-
directional reactive over-power function to supervise the neutral voltages to be connected.
system voltage. When triggered, the function will cause an
alarm, switch in reactors, or switch out capacitor banks. Overfrequency protection SAPTOF
M14953-3 v12
Overfrequency protection function (SAPTOF) is applicable in
OV2PTOV has two voltage steps, each of them with inverse all situations, where reliable detection of high fundamental
or definite time delayed. power system frequency is needed.
OV2PTOV has a high reset ratio to allow settings close to Overfrequency occurs because of sudden load drops or
system service voltage. shunt faults in the power network. Close to the generating
plant, generator governor problems can also cause over
Two step residual overvoltage protection ROV2PTOV frequency.
M13808-3 v11
Residual voltages may occur in the power system during
earth faults. SAPTOF measures frequency with high accuracy, and is used
mainly for generation shedding and remedial action schemes.
Two step residual overvoltage protection (ROV2PTOV) It is also used as a frequency stage initiating load restoring. A
function calculates the residual voltage from the three-phase definite time delay is provided for operate.
voltage input transformers or measures it from a single
voltage input transformer fed from an open delta or neutral SAPTOF is provided with an undervoltage blocking.
point voltage transformer.
The operation is based on positive sequence voltage
ROV2PTOV has two voltage steps, each with inverse or measurement and requires two phase-phase or three phase-
definite time delay. neutral voltages to be connected.
A reset delay ensures operation for intermittent earth faults. Rate-of-change of frequency protection SAPFRC
M14965-3 v13
The rate-of-change of frequency protection function
Voltage differential protection VDCPTOV (SAPFRC ) gives an early indication of a main disturbance in
SEMOD153862-5 v7
A voltage differential monitoring function is available. It the system. SAPFRC measures frequency with high accuracy,
compares the voltages from two three phase sets of voltage and can be used for generation shedding, load shedding and
transformers and has one sensitive alarm step and one trip remedial action schemes. SAPFRC can discriminate between
step. Alternatively, it can be used as voltage differential a positive or negative change of frequency. A definite time
protection (VDCPTOV) for shunt capacitor banks. delay is provided for operate.
Loss of voltage check LOVPTUV SAPFRC is provided with an undervoltage blocking. The
SEMOD171457-5 v8
Loss of voltage check (LOVPTUV ) is suitable for use in operation is based on positive sequence voltage
networks with an automatic system restoration function. measurement and requires two phase-phase or three phase-
LOVPTUV issues a three-pole trip command to the circuit neutral voltages to be connected.
breaker, if all three phase voltages fall below the set value for
a time longer than the set time and the circuit breaker Frequency time accumulation protection FTAQFVR
GUID-020CE8CF-9BEA-455D-ACBD-13023B93B4D1 v5
remains closed. Frequency time accumulation protection (FTAQFVR) is based

on measured system frequency and time counters. FTAQFVR
The operation of LOVPTUV is supervised by the fuse failure for generator protection provides the START output for a
supervision FUFSPVC. particular settable frequency limit, when the system frequency
falls in that settable frequency band limit and positive
sequence voltage within settable voltage band limit. The
ABB 31
1MRK 511 404-BEN A
START signal triggers the individual event timer, which is the with the neutral point current on a separate input taken from
continuous time spent within the given frequency band, and another set of cores on the current transformer.
the accumulation timer, which is the cumulative time spent
within the given frequency band. Once the timers reach their A detection of a difference indicates a fault in the circuit and
limit, an alarm or trip signal is activated to protect the turbine is used as alarm or to block protection functions expected to
against the abnormal frequency operation. This function is give inadvertent tripping.
blocked during generator start-up or shut down conditions by
Fuse failure supervision FUFSPVC
monitoring the circuit breaker position and current threshold SEMOD113820-4 v12
The aim of the fuse failure supervision function (FUFSPVC) is
value. The function is also blocked when the system positive
to block voltage measuring functions at failures in the
sequence voltage magnitude deviates from the given voltage
secondary circuits between the voltage transformer and the
band limit which can be enabled by EnaVoltCheck setting.
IED in order to avoid inadvertent operations that otherwise
It is possible to create functionality with more than one might occur.
frequency band limit by using multiple instances of the
The fuse failure supervision function basically has three
function. This can be achieved by a proper configuration
different detection methods, negative sequence and zero
based on the turbine manufacturer specification.
sequence based detection and an additional delta voltage
and delta current detection.
9. Multipurpose protection
The negative sequence detection algorithm is recommended
General current and voltage protection CVGAPC for IEDs used in isolated or high-impedance earthed
M13083-11 v9
The General current and voltage protection (CVGAPC) can be networks. It is based on the negative-sequence quantities.
utilized as a negative sequence current protection detecting
unsymmetrical conditions such as open phase or The zero sequence detection is recommended for IEDs used
unsymmetrical faults. in directly or low impedance earthed networks. It is based on
the zero sequence measuring quantities.
CVGAPC can also be used to improve phase selection for
high resistive earth faults, outside the distance protection The selection of different operation modes is possible by a
reach, for the transmission line. Three functions are used, setting parameter in order to take into account the particular
which measures the neutral current and each of the three earthing of the network.
phase voltages. This will give an independence from load
A criterion based on delta current and delta voltage
currents and this phase selection will be used in conjunction
measurements can be added to the fuse failure supervision
with the detection of the earth fault from the directional earth
function in order to detect a three phase fuse failure, which in
fault protection function.
practice is more associated with voltage transformer
switching during station operations.
10. General calculation
Fuse failure supervision VDSPVC
GUID-6AF2219A-264F-4971-8D03-3B8A9D0CB284 v5
Multipurpose filter SMAIHPAC Different protection functions within the protection IED
GUID-EB0B11C3-FF79-4B8D-A335-649623E832F9 v3
The multi-purpose filter function block (SMAIHPAC) is operates on the basis of measured voltage at the relay point.
arranged as a three-phase filter. It has very much the same Some example of protection functions are:
user interface (e.g. inputs and outputs) as the standard pre-
processing function block SMAI. However the main difference • Distance protection function.
is that it can be used to extract any frequency component • Undervoltage function.
from the input signal. Thus it can, for example, be used to • Energisation function and voltage check for the weak
build sub-synchronous resonance protection for synchronous infeed logic.
generator.
These functions can operate unintentionally, if a fault occurs
in the secondary circuits between voltage instrument
11. Secondary system supervision transformers and the IED. These unintentional operations can
be prevented by fuse failure supervision (VDSPVC).
Current circuit supervision CCSSPVC
M12444-3 v10
Open or short circuited current transformer cores can cause VDSPVC is designed to detect fuse failures or faults in voltage
unwanted operation of many protection functions such as measurement circuit, based on phase wise comparison of
differential, earth-fault current and negative-sequence current voltages of main and pilot fused circuits. VDSPVC blocking
functions. output can be configured to block functions that need to be
blocked in case of faults in the voltage circuit.
Current circuit supervision (CCSSPVC) compares the residual
current from a three phase set of current transformer cores
32 ABB
1MRK 511 404-BEN A
12. Scheme communication including a channel transmission time, can be achieved. This
short operate time enables rapid autoreclosing function after
Scheme communication logic with delta based blocking the fault clearance.
scheme signal transmit ZCPSCH
M13860-3 v10
To achieve instantaneous fault clearance for all line faults, The communication logic module for directional residual
scheme communication logic is provided. All types of current protection enables blocking as well as permissive
communication schemes for permissive underreaching, under/overreaching, and unblocking schemes. The logic can
permissive overreaching, blocking, delta based blocking, also be supported by additional logic for weak-end infeed and
unblocking and intertrip are available. current reversal, included in Current reversal and weak-end
infeed logic for residual overcurrent protection (ECRWPSCH)
The built-in communication module (LDCM) can be used for function.
scheme communication signaling when included.
Current reversal and weak-end infeed logic for residual
Current reversal and weak-end infeed logic for distance overcurrent protection ECRWPSCH
protection ZCRWPSCH M13928-3 v8
The Current reversal and weak-end infeed logic for residual
M13896-3 v15
The ZCRWPSCH function provides the current reversal and overcurrent protection (ECRWPSCH) is a supplement to
weak end infeed logic functions that supplement the standard Scheme communication logic for residual overcurrent
scheme communication logic. It is not suitable for standalone protection ECPSCH.
use as it requires inputs from the distance protection
functions and the scheme communications function included To achieve fast fault clearing for all earth faults on the line, the
within the terminal. directional earth fault protection function can be supported
with logic that uses tele-protection channels.
On detection of a current reversal, the current reversal logic
provides an output to block the sending of the teleprotection This is why the IEDs have available additions to the scheme
signal to the remote end, and to block the permissive tripping communication logic.
at the local end. This blocking condition is maintained long M13928-6 v2
enough to ensure that no unwanted operation will occur as a If parallel lines are connected to common busbars at both
result of the current reversal. terminals, overreaching permissive communication schemes
can trip unselectively due to fault current reversal. This
On verification of a weak end infeed condition, the weak end unwanted tripping affects the healthy line when a fault is
infeed logic provides an output for sending the received cleared on the other line. This lack of security can result in a
teleprotection signal back to the remote sending end and total loss of interconnection between the two buses. To avoid
other output(s) for local tripping. For terminals equipped for this type of disturbance, a fault current reversal logic
single- and two-pole tripping, outputs for the faulted phase(s) (transient blocking logic) can be used.
are provided. Undervoltage detectors are used to detect the M13928-8 v5
faulted phase(s). Permissive communication schemes for residual overcurrent

protection can basically operate only when the protection in
Local acceleration logic ZCLCPSCH the remote IED can detect the fault. The detection requires a
M13823-3 v7
To achieve fast clearing of faults on the whole line, when no sufficient minimum residual fault current, out from this IED.
communication channel is available, local acceleration logic The fault current can be too low due to an opened breaker or
(ZCLCPSCH) can be used. This logic enables fast fault high-positive and/or zero-sequence source impedance
clearing and re-closing during certain conditions, but behind this IED. To overcome these conditions, weak-end
naturally, it can not fully replace a communication channel. infeed (WEI) echo logic is used. The weak-end infeed echo is
limited to 200 ms to avoid channel lockup.
The logic can be controlled either by the autorecloser (zone
extension) or by the loss-of-load current (loss-of-load
acceleration). 13. Logic
Scheme communication logic for residual overcurrent Tripping logic SMPPTRC

M12275-3 v12
protection ECPSCH A function block for protection tripping and general start
M13918-4 v11
To achieve fast fault clearance of earth faults on the part of indication is always provided as a basic function for each
the line not covered by the instantaneous step of the residual circuit breaker. It provides a settable pulse prolongation time
overcurrent protection, the directional residual overcurrent to ensure a trip pulse of sufficient length, as well as all
protection can be supported with a logic that uses functionality necessary for correct co-operation with
communication channels. autoreclosing functions.
In the directional scheme, information of the fault current The trip function block includes a settable latch function for
direction must be transmitted to the other line end. With the trip signal and circuit breaker lockout.
directional comparison, a short operate time of the protection
ABB 33
1MRK 511 404-BEN A
The trip function can collect start and directional signals from • INVERTER function block that inverts the input signal to the
different application functions. The aggregated start and output.
directional signals are mapped to the IEC 61850 logical node
data model. • LLD function block. Loop delay used to delay the output
signal one execution cycle.
General start matrix block SMAGAPC
GUID-BA516165-96DE-4CD9-979B-29457C7653C0 v3
The Start Matrix (SMAGAPC) merges start and directional • OR function block. The OR function is used to form general
output signals from different application functions and creates combinatory expressions with boolean variables. The OR
a common start and directional output signal (STDIR ) to be function block has up to six inputs and two outputs. One of
connected to the Trip function. the outputs is inverted.
The purpose of this functionality is to provide general start • PULSETIMER function block can be used, for example, for
and directional information for the IEC 61850 trip logic data pulse extensions or limiting of operation of outputs, settable
model SMPPTRC. pulse time.
Trip matrix logic TMAGAPC • RSMEMORY function block is a flip-flop that can reset or
M15321-3 v12
The trip matrix logic TMAGAPC function is used to route trip set an output from two inputs respectively. Each block has
signals and other logical output signals to different output two outputs where one is inverted. The memory setting
contacts on the IED. controls if, after a power interruption, the flip-flop resets or
returns to the state it had before the power interruption.
The trip matrix logic function has 3 output signals and these RESET input has priority.
outputs can be connected to physical tripping outputs
according to the specific application needs for settable pulse • SRMEMORY function block is a flip-flop that can set or
or steady output. reset an output from two inputs respectively. Each block
has two outputs where one is inverted. The memory setting
Group alarm logic function ALMCALH controls if, after a power interruption, the flip-flop resets or
GUID-16E60E27-F7A8-416D-8648-8174AAC49BB5 v4
The group alarm logic function (ALMCALH) is used to route returns to the state it had before the power interruption.
several alarm signals to a common indication, LED and/or The SET input has priority.
contact, in the IED.
• TIMERSET function has pick-up and drop-out delayed
Group warning logic function WRNCALH outputs related to the input signal. The timer has a settable
GUID-F7D9A012-3AD4-4D86-BE97-DF2A99BE5383 v4
The group warning logic function (WRNCALH) is used to route time delay.
several warning signals to a common indication, LED and/or
contact, in the IED. • XOR is used to generate combinatory expressions with
boolean variables. XOR has two inputs and two outputs.
Group indication logic function INDCALH One of the outputs is inverted. The output signal OUT is 1 if
GUID-D8D1A4EE-A87F-46C6-8529-277FC1ADA9B0 v4
The group indication logic function (INDCALH) is used to the input signals are different and 0 if they are the same.
route several indication signals to a common indication, LED
and/or contact, in the IED.
Configurable logic blocks Q/T
GUID-0CA6511A-E8BD-416E-9B59-5C6BD98C60B7 v5
Basic configurable logic blocks The configurable logic blocks QT propagate the time stamp
M11396-4 v16
The basic configurable logic blocks do not propagate the time and the quality of the input signals (have suffix QT at the end
stamp and quality of signals (have no suffix QT at the end of of their function name).
their function name). A number of logic blocks and timers are
The function blocks assist the user to adapt the IEDs'
always available as basic for the user to adapt the
configuration to the specific application needs. The list below
configuration to the specific application needs. The list below
shows a summary of the function blocks and their features.
shows a summary of the function blocks and their features.
• ANDQT AND function block. The function also
These logic blocks are also available as part of an extension
propagates the time stamp and the quality of input
logic package with the same number of instances.
signals. Each block has four inputs and two outputs
• AND function block. The AND function is used to form where one is inverted.
general combinatory expressions with boolean variables.
• INDCOMBSPQT combines single input signals to group
The AND function block has up to four inputs and two
signal. Single position input is copied to value part of
outputs. One of the outputs is inverted.
SP_OUT output. TIME input is copied to time part of
• GATE function block is used for whether or not a signal SP_OUT output. Quality input bits are copied to the
should be able to pass from the input to the output. corresponding quality part of SP_OUT output.
34 ABB
1MRK 511 404-BEN A
• INDEXTSPQT extracts individual signals from a group M15322-3 v12
signal input. The value part of single position input is The Fixed signals function (FXDSIGN) has nine pre-set (fixed)
copied to SI_OUT output. The time part of single signals that can be used in the configuration of an IED, either
position input is copied to TIME output. The quality bits for forcing the unused inputs in other function blocks to a
in the common part and the indication part of inputs certain level/value, or for creating certain logic. Boolean,
signal are copied to the corresponding quality output. integer, floating point, string types of signals are available.
• INVALIDQT function which sets quality invalid of outputs One FXDSIGN function block is included in all IEDs.
according to a "valid" input. Inputs are copied to
Elapsed time integrator with limit transgression and overflow
outputs. If input VALID is 0, or if its quality invalid bit is
supervision TEIGAPC
set, all outputs invalid quality bit will be set to invalid. GUID-2D64874A-F266-4251-8EED-E813F40513D7 v3
The Elapsed time integrator function (TEIGAPC) is a function
The time stamp of an output will be set to the latest time
that accumulates the elapsed time when a given binary signal
stamp of INPUT and VALID inputs.
has been high.
• INVERTERQT function block that inverts the input signal
The main features of TEIGAPC
and propagates the time stamp and the quality of the
input signal. • Applicable to long time integration (≤999 999.9
seconds).
• ORQT OR function block that also propagates the time
• Supervision of limit transgression conditions and
stamp and the quality of the input signals. Each block
overflow.
has six inputs and two outputs where one is inverted.
• Possibility to define a warning or alarm with the
• PULSETIMERQT Pulse timer function block can be used, resolution of 10 milliseconds.
for example, for pulse extensions or limiting of operation • Retaining of the integration value.
of outputs. The function also propagates the time stamp • Possibilities for blocking and reset.
and the quality of the input signal. • Reporting of the integrated time.
• RSMEMORYQT function block is a flip-flop that can reset

Boolean to integer conversion, 16 bit B16I
or set an output from two inputs respectively. Each SEMOD175725-4 v5
Boolean to integer conversion, 16 bit (B16I) is used to
block has two outputs where one is inverted. The
transform a set of 16 boolean (logical) signals into an integer.
memory setting controls if the block after a power
interruption should return to the state before the Boolean to integer conversion with logical node
interruption, or be reset. The function also propagates representation, 16 bit BTIGAPC
SEMOD175781-4 v8
the time stamp and the quality of the input signal. Boolean to integer conversion with logical node
representation, 16 bit (BTIGAPC) is used to transform a set of
• SRMEMORYQT function block is a flip-flop that can set
16 boolean (logical) signals into an integer. The block input
or reset an output from two inputs respectively. Each
will freeze the output at the last value.
block has two outputs where one is inverted. The
memory setting controls if the block after a power Integer to Boolean 16 conversion IB16
SEMOD158373-5 v6
interruption should return to the state before the Integer to boolean 16 conversion function (IB16) is used to
interruption, or be reset. The function also propagates transform an integer into a set of 16 boolean (logical) signals.
the time stamp and the quality of the input signal.
Integer to Boolean 16 conversion with logic node
• TIMERSETQT function has pick-up and drop-out delayed representation ITBGAPC
SEMOD158421-5 v9
outputs related to the input signal. The timer has a Integer to boolean conversion with logic node representation
settable time delay. The function also propagates the function (ITBGAPC) is used to transform an integer which is
time stamp and the quality of the input signal. transmitted over IEC 61850 and received by the function to
16 boolean (logic) output signals.
• XORQT XOR function block. The function also
propagates the time stamp and the quality of the input Comparator for integer inputs INTCOMP
GUID-A93564FA-0017-4939-A9C1-095DA0FD9832 v1
signals. Each block has two outputs where one is The function gives the possibility to monitor the level of
inverted. integer values in the system relative to each other or to a
fixed value. It is a basic arithmetic function that can be used
Extension logic package for monitoring, supervision, interlocking and other logics.
GUID-144BAAA3-A5EF-49AF-8876-93CC5F3D0234 v1
The logic extension block package includes additional trip
Comparator for real inputs REALCOMP
matrix logic and configurable logic blocks. GUID-E17A88D7-D095-4F36-9CD5-64EBFD2A1DEA v1
The function gives the possibility to monitor the level of real
Fixed signal function block FXDSIGN value signals in the system relative to each other or to a fixed
ABB 35
1MRK 511 404-BEN A
value. It is a basic arithmetic function that can be used for The Disturbance report function is characterized by great
monitoring, supervision, interlocking and other logics. flexibility regarding configuration, starting conditions,
recording times, and large storage capacity.
14. Monitoring A disturbance is defined as an activation of an input to the

AnRADR or BnRBDR function blocks, which are set to trigger
Measurements CVMMXN, CMMXU, VNMMXU, VMMXU,
the disturbance recorder. All connected signals from start of
CMSQI, VMSQI
M12024-3 v9 pre-fault time to the end of post-fault time will be included in
The measurement functions are used to get on-line
the recording. Disturbance record will have visible settings
information from the IED. These service values make it
from all function instances that are configured in the
possible to display on-line information on the local HMI and
application configuration tool.
on the substation automation system about:
Every disturbance report recording is saved in the IED in the
• measured voltages, currents, frequency, active, reactive
standard Comtrade format as a reader file HDR, a
and apparent power and power factor
configuration file CFG, and a data file DAT. The same applies
• measured analog values from merging units
to all events, which are continuously saved in a ring-buffer.
• primary phasors
The local HMI is used to get information about the recordings.
• positive, negative and zero sequence currents and
The disturbance report files can be uploaded to PCM600 for
voltages
further analysis using the disturbance handling tool.
• mA, input currents
• pulse counters Event list DRPRDRE
M12412-6 v8
Continuous event-logging is useful for monitoring the system
Supervision of mA input signals from an overview perspective and is a complement to specific
M16054-3 v2
The main purpose of the function is to measure and process disturbance recorder functions.
signals from different measuring transducers. Many devices
The event list logs all binary input signals connected to the
used in process control represent various parameters such as
Disturbance recorder function. The list may contain up to
frequency, temperature and DC battery voltage as low current
1000 time-tagged events stored in a ring-buffer.
values, usually in the range 4-20 mA or 0-20 mA.
Indications DRPRDRE
Alarm limits can be set and used as triggers, e.g. to generate M12030-3 v6
To get fast, condensed and reliable information about
trip or alarm signals.
disturbances in the primary and/or in the secondary system it
The function requires that the IED is equipped with the mA is important to know, for example binary signals that have
input module. changed status during a disturbance. This information is used
in the short perspective to get information via the local HMI in
Disturbance report DRPRDRE a straightforward way.
M12153-3 v13
Complete and reliable information about disturbances in the
primary and/or in the secondary system together with There are three LEDs on the local HMI (green, yellow and
continuous event-logging is accomplished by the disturbance red), which will display status information about the IED and
report functionality. the Disturbance recorder function (triggered).
Disturbance report (DRPRDRE), always included in the IED, The Indication list function shows all selected binary input
acquires sampled data of all selected analog input and binary signals connected to the Disturbance recorder function that
signals connected to the function block with a maximum of have changed status during a disturbance.
40 analog and 352 binary signals.
Event recorder DRPRDRE
M12033-3 v8
The Disturbance report functionality is a common name for Quick, complete and reliable information about disturbances
several functions: in the primary and/or in the secondary system is vital, for
example, time-tagged events logged during disturbances.
• Event list This information is used for different purposes in the short
• Indications term (for example corrective actions) and in the long term (for
• Event recorder example functional analysis).
• Trip value recorder
• Disturbance recorder The event recorder logs all selected binary input signals
• Fault locator connected to the Disturbance recorder function. Each
• Settings information recording can contain up to 150 time-tagged events.
The event recorder information is available for the

disturbances locally in the IED.
36 ABB
1MRK 511 404-BEN A
The event recording information is an integrated part of the SEMOD55713-5 v8
disturbance record (Comtrade file). Generic communication function for Single Point indication
(SPGAPC) is used to send one single logical signal to other
Trip value recorder DRPRDRE systems or equipment in the substation.
M12128-3 v7
Information about the pre-fault and fault values for currents
and voltages are vital for the disturbance evaluation. Generic communication function for measured values
MVGAPC
SEMOD55872-5 v10
The Trip value recorder calculates the values of all selected Generic communication function for measured values
analog input signals connected to the Disturbance recorder (MVGAPC) function is used to send the instantaneous value
function. The result is magnitude and phase angle before and of an analog signal to other systems or equipment in the
during the fault for each analog input signal. substation. It can also be used inside the same IED, to attach
a RANGE aspect to an analog value and to permit
The trip value recorder information is available for the measurement supervision on that value.
disturbances locally in the IED.
Measured value expander block RANGE_XP
The trip value recorder information is an integrated part of the
SEMOD52450-4 v7
The current and voltage measurements functions (CVMMXN,
disturbance record (Comtrade file). CMMXU, VMMXU and VNMMXU), current and voltage
sequence measurement functions (CMSQI and VMSQI) and
Disturbance recorder DRPRDRE
M12156-3 v11 IEC 61850 generic communication I/O functions (MVGAPC)
The Disturbance recorder function supplies fast, complete
are provided with measurement supervision functionality. All
and reliable information about disturbances in the power
measured values can be supervised with four settable limits:
system. It facilitates understanding system behavior and
low-low limit, low limit, high limit and high-high limit. The
related primary and secondary equipment during and after a
measure value expander block (RANGE_XP) has been
disturbance. Recorded information is used for different
introduced to enable translating the integer output signal from
purposes in the short perspective (for example corrective
the measuring functions to 5 binary signals: below low-low
actions) and long perspective (for example functional
limit, below low limit, normal, above high limit or above high-
analysis).
high limit. The output signals can be used as conditions in the
The Disturbance recorder acquires sampled data from configurable logic or for alarming purpose.
selected analog and binary signals connected to the
Insulation supervision for gas medium function SSIMG
Disturbance recorder function (maximum 40 analog and 352 GUID-0692CD0D-F33E-4370-AC91-B216CAAAFC28 v6
Insulation supervision for gas medium (SSIMG) is used for
binary signals). The binary signals available are the same as
monitoring the circuit breaker condition. Binary information
for the event recorder function.
based on the gas pressure in the circuit breaker is used as
The function is characterized by great flexibility and is not input signals to the function. In addition, the function
dependent on the operation of protection functions. It can generates alarms based on received information.
record disturbances not detected by protection functions. Up
Insulation supervision for liquid medium SSIML
to ten seconds of data before the trigger instant can be saved GUID-3B1A665F-60A5-4343-85F4-AD9C066CBE8D v6
Insulation supervision for liquid medium (SSIML) is used for
in the disturbance file.
monitoring the transformer condition. Binary information
The disturbance recorder information for up to 100 based on the oil level in the transformer is used as input
disturbances are saved in the IED and the local HMI is used signals to the function. In addition, the function generates
to view the list of recordings. alarms based on received information.
Event function Circuit breaker condition monitoring SSCBR

GUID-E1FD74C3-B9B6-4E11-AA1B-7E7F822FB4DD v11
The circuit breaker condition monitoring function (SSCBR) is
M12805-6 v11
When using a Substation Automation system with LON or
SPA communication, time-tagged events can be sent at used to monitor different parameters of the breaker condition.
change or cyclically from the IED to the station level. These The breaker requires maintenance when the number of
events are created from any available signal in the IED that is operations reaches a predefined value. For a proper
connected to the Event function (EVENT). The EVENT functioning of the circuit breaker, it is essential to monitor the
function block is used for LON and SPA communication. circuit breaker operation, spring charge indication or breaker
wear, travel time, number of operation cycles and estimate
Analog, integer and double indication values are also the accumulated energy during arcing periods.
transferred through the EVENT function.
Generic communication function for Single Point indication Fault locator LMBRFLO
M13970-3 v13
SPGAPC The accurate fault locator is an essential component to

minimize the outages after a persistent fault and/or to pin-
point a weak spot on the line.
ABB 37
1MRK 511 404-BEN A
The fault locator is an impedance measuring function giving taken through sensors or the one calculated by the function.
the distance to the fault in km, miles or % of line length. The This decision is made based on the top oil temperature
main advantage is the high accuracy achieved by sensor quality. Top oil temperature calculation is done using
compensating for load current and for the mutual zero- the method explained in IEC 60076-7 standard.
sequence effect on double circuit lines.
Inputs required for hot spot temperature calculation are:
The compensation includes setting of the remote and local • Transformer oil time constant
sources and calculation of the distribution of fault currents • Winding time constant
from each side. This distribution of fault current, together with • Loss ratio at different tap positions
recorded load (pre-fault) currents, is used to exactly calculate • Ambient temperature around the transformer
the fault position. The fault can be recalculated with new
source data at the actual fault to further increase the
The oil and winding time constants can be calculated by the
accuracy.
function based on transformer parameters if the inputs are
Especially on heavily loaded long lines, where the source not available from the transformer manufacturer.
voltage angles can be up to 35-40 degrees apart, the
Ambient temperature to the function can either be provided
accuracy can be still maintained with the advanced
through the sensor or monthly average ambient temperature
compensation included in fault locator.
settings. This decision is made based on the ambient
Event counter with limit supervison L4UFCNT temperature sensor quality. Additionally, LOLSPTR function
GUID-13157EAB-1686-4D2E-85DF-EC89768F3572 v6
The Limit counter (L4UFCNT) provides a settable counter with provides difference between measured value and calculated
four independent limits where the number of positive and/or value of the top oil temperature.
negative flanks on the input signal are counted against the
Additionally, the function calculates loss of life in form of days
setting values for limits. The output for each limit is activated
and years. This information is updated at settable intervals,
when the counted value reaches that limit.
for example, hourly or daily. Transformer winding percentage
Overflow indication is included for each up-counter. loss of life is calculated every day and the information is
provided as total percentage loss of life from the installation
Running hour-meter TEILGAPC date and yearly percentage loss of life.
GUID-464FB24F-B367-446C-963A-A14841943B87 v2
The Running hour-meter (TEILGAPC) function is a function
that accumulates the elapsed time when a given binary signal
15. Metering
has been high.
Pulse-counter logic PCFCNT
The main features of TEILGAPC are: M13394-3 v7
Pulse-counter logic (PCFCNT) function counts externally
• Applicable to very long time accumulation (≤ 99999.9 generated binary pulses, for instance pulses coming from an
hours) external energy meter, for calculation of energy consumption
• Supervision of limit transgression conditions and rollover/ values. The pulses are captured by the binary input module
overflow and then read by the PCFCNT function. A scaled service
• Possibility to define a warning and alarm with the value is available over the station bus. The special Binary
resolution of 0.1 hours input module with enhanced pulse counting capabilities must
• Retain any saved accumulation value at a restart be ordered to achieve this functionality.
• Possibilities for blocking and reset
Function for energy calculation and demand handling
• Possibility for manual addition of accumulated time
ETPMMTR
• Reporting of the accumulated time GUID-6898E29B-DA70-421C-837C-1BBED8C63A7A v3
Power system measurement (CVMMXN) can be used to
measure active as well as reactive power values. Function for
Estimation of transformer winding insulation life LOLSPTR energy calculation and demand handling (ETPMMTR) uses
GUID-CDE89397-8E99-4873-9701-FF642101A308 v2
Estimation of transformer winding insulation life (LOLSPTR) is measured active and reactive power as input and calculates
used to calculate transformer winding hot spot temperature the accumulated active and reactive energy pulses, in forward
using the empirical formulae. It is also used to estimate and reverse direction. Energy values can be read or
transformer loss of life from the winding hot spot temperature generated as pulses. Maximum demand power values are
value. The transformer winding insulation is degraded when also calculated by the function. This function includes zero
the winding hot spot temperature exceeds certain limit. point clamping to remove noise from the input signal. As
LOLSPTR gives warning and alarm signals when the winding output of this function: periodic energy calculations,
hot spot temperature reaches a set value. integration of energy values, calculation of energy pulses,
alarm signals for limit violation of energy values and maximum
Hot spot temperature calculation requires top oil temperature power demand, can be found.
at a given time. This value can either be a measured value
38 ABB
1MRK 511 404-BEN A
The values of active and reactive energies are calculated from • Graphical display capable of showing a user defined single
the input power values by integrating them over a selected line diagram and provide an interface for controlling
time tEnergy. The integration of active and reactive energy switchgear.
values will happen in both forward and reverse directions. • Navigation buttons and five user defined command buttons
These energy values are available as output signals and also to shortcuts in the HMI tree or simple commands.
as pulse outputs. Integration of energy values can be • 15 user defined three-color LEDs.
controlled by inputs (STARTACC and STOPACC) and EnaAcc • Communication port for PCM600.
setting and it can be reset to initial values with RSTACC
input.
The LHMI is used for setting, monitoring and controlling.
The maximum demand for active and reactive powers are
calculated for the set time interval tEnergy and these values 17. Basic IED functions
are updated every minute through output channels. The
active and reactive maximum power demand values are Time synchronization
M11344-3 v10
calculated for both forward and reverse direction and these The time synchronization function is used to select a common
values can be reset with RSTDMD input. source of absolute time for the synchronization of the IED
when it is a part of a control and a protection system. This
makes it possible to compare events and disturbance data
16. Human machine interface between all IEDs within a station automation system and in
between sub-stations. A common source shall be used for
Local HMI IED and merging unit when IEC/UCA 61850-9-2LE process
AMU0600442 v14
bus communication is used.
M11345-3 v10
Precision time protocol PTP

PTP according to IEEE 1588-2008 and specifically its profile
IEC/IEEE 61850-9-3 for power utility automation is a
synchronization method that can be used to maintain a
common time within a station. This time can be synchronized
to the global time using, for instance, a GPS receiver. If PTP
is enabled on the IEDs and the switches that connect the
station are compatible with IEEE 1588, the station will
become synchronized to one common time with an accuracy
of under 1us. Using an IED as a boundary clock between
several networks will keep 1us accuracy on three levels or
when using an HSR, 15 IEDs can be connected in a ring
without losing a single microsecond in accuracy.
18. Ethernet
Access points
GUID-6E5D2696-A8EE-43E7-A94B-69C3D0612127 v1
An access point is an Ethernet communication interface for
single or redundant station communication. Each access
point is allocated with one physical Ethernet port, two
physical Ethernet ports are allocated if redundant
communication is activated for the access point.
Figure 5. Local human-machine interface Device 1 Device 1
AP1 AP2 AP3 AP1 AP2 AP3
The LHMI of the IED contains the following elements: SFP_301 SFP_302 SFP_303 SFP_301 SFP_302 SFP_303
IEC16000092-1-en.vsdx
Figure 6. Access points, non redundant (left) and redundant

communication (right)
ABB 39
1MRK 511 404-BEN A
DHCP is available for the front port, and a device connected systems or equipment, either on the Substation Automation
to it can thereby obtain an automatically assigned IP-address. (SA) bus or Substation Monitoring (SM) bus.
Access points diagnostics Available communication protocols are:

GUID-20F64A6D-AA8C-47D7-AA7D-4810996B2FF2 v1
The access point diagnostics function blocks (RCHLCCH,
SCHLCCH and FRONTSTATUS) supervise communication. • IEC 61850-8-1 communication protocol
SCHLCCH is used for communication over the rear Ethernet • IEC/UCA 61850-9-2LE communication protocol
ports, RCHLCCH is used for redundant communications over • LON communication protocol
the rear Ethernet ports and FRONTSTATUS is used for • SPA communication protocol
communication over the front port. All access point function • IEC 60870-5-103 communication protocol
blocks include output signal for denial of service. • DNP 3.0 communication protocol
Redundant communication Several protocols can be combined in the same IED.

GUID-A90FDBA7-D4D7-4CBD-9F05-13DCC9971779 v7
IEC 62439-3 redundant communication PRP IEC 61850-8-1 communication protocol

M14787-3 v15
Redundant communication according to IEC 62439-3 PRP-0, IEC 61850 Ed.1 or Ed.2 can be chosen by a setting in
IEC 62439-3 PRP-1 parallel redundancy protocol (PRP) is PCM600. The IED is equipped with up to six (order
available as an option when ordering IEDs. PRP according to dependent) optical Ethernet rear ports for IEC 61850-8-1
IEC 62439-3 uses two optical Ethernet ports. station bus communication. The IEC 61850-8-1
communication is also possible from the electrical Ethernet
IEC 62439-3 High-availability seamless redundancy HSR front port. IEC 61850-8-1 protocol allows intelligent electrical
Redundant station bus communication according to IEC devices (IEDs) from different vendors to exchange information
62439-3 Edition 2 High-availability seamless redundancy and simplifies system engineering. IED-to-IED communication
(HSR) is available as an option when ordering IEDs. using GOOSE and client-server communication over MMS are
Redundant station bus communication according to IEC supported. Disturbance recording file (COMTRADE) uploading
62439-3 uses two optical Ethernet ports. can be done over MMS or FTP.
The HSR ring supports the connection of up to 30 relays. If IEC 61850 quality expander QUALEXP
GUID-9C5DC78E-041B-422B-9668-320E62B847A2 v1
more than 30 relays are to be connected, it is recommended The quality expander component is used to display the
to split the network into several rings to guarantee the detailed quality of an IEC/UCA 61850-9-2LE analog channel.
performance for real-time applications. The component expands the channel quality output of a
Merging Unit analog channel received in the IED as per the
Routes IEC 61850-7-3 standard. This component can be used during
GUID-95F9C7BA-92F8-489F-AD0A-047410B5E66F v1
A route is a specified path for data to travel between the the ACT monitoring to get the particular channel quality of the
source device in a subnetwork to the destination device in a Merging Unit.
different subnetwork. A route consists of a destination
address and the address of the gateway to be used when IEC/UCA 61850-9-2LE communication protocol
GUID-C3AA21B4-730F-4327-943A-3C77102A80A0 v4
sending data to the destination device, see Figure 7. Optical Ethernet port communication standard IEC/UCA
61850-9-2LE for process bus is supported. IEC/UCA
61850-9-2LE allows Non Conventional Instrument
Transformers (NCIT) with Merging Units (MUs) or stand-alone
MUs to exchange information with the IED, and simplifies SA
engineering. IEC/UCA 61850-9-2LE uses the same port as
Default gateway IEC 61850-8-1.
LON communication protocol

SEMOD120140-5 v3
Gateway Existing stations with ABB station bus LON can be extended
with use of the optical LON interface (glass or plastic). This
Source Destination allows full SA functionality including peer-to-peer messaging
IEC16000095-1-en.vsdx
and cooperation between the IEDs.
Figure 7. Route from source to destination through gateway
SPA communication protocol
SEMOD120134-5 v1
A single glass or plastic port is provided for the ABB SPA
protocol. This allows extensions of simple substation
automation systems but the main use is for Substation
19. Station communication
Monitoring Systems SMS.
Communication protocols
M14815-3 v13
Each IED is provided with several communication interfaces
enabling it to connect to one or many substation level
40 ABB
1MRK 511 404-BEN A
include the FunctionType parameter for each block in the

IEC 60870-5-103 communication protocol private range, and the information number parameter for each
SEMOD120137-5 v4
A single glass or plastic port is provided for the IEC input signal.
60870-5-103 standard. This allows design of simple
substation automation systems including equipment from Function commands for IEC 60870-5-103 I103CMD
different vendors. Disturbance files uploading is provided. I103CMD is a command function block in control direction
with pre-defined output signals. The signals are in steady
Measurands for IEC 60870-5-103 I103MEAS state, not pulsed, and stored in the IED in case of restart.
103MEAS is a function block that reports all valid measuring
types depending on the connected signals. The set of IED commands for IEC 60870-5-103 I103IEDCMD
connected inputs will control which ASDUs (Application I103IEDCMD is a command block in control direction with
Service Data Units) are generated. defined IED functions. All outputs are pulsed and they are
NOT stored. Pulse-time is a hidden parameter.
Measurands user-defined signals for IEC 60870-5-103
I103MEASUSR Function commands user-defined for IEC 60870-5-103
I103MEASUSR is a function block with user-defined input I103USRCMD
measurands in monitor direction. These function blocks I103USRCMD is a command block in control direction with
include the FunctionType parameter for each block in the user-defined output signals. These function blocks include
private range, and the Information number parameter for each the FunctionType parameter for each block in the private
block. range, and the Information number parameter for each output
signal.
Function status auto-recloser for IEC 60870-5-103 I103AR
I103AR is a function block with defined functions for Function commands generic for IEC 60870-5-103
autorecloser indications in monitor direction. This block I103GENCMD
includes the FunctionType parameter, and the information I103GENCMD is used for transmitting generic commands
number parameter is defined for each output signal. over IEC 60870-5-103. The function has two output signals,
CMD_OFF and CMD_ON, that can be used to implement
Function status earth-fault for IEC 60870-5-103 I103EF double-point command schemes.
I103EF is a function block with defined functions for earth
fault indications in monitor direction. This block includes the The I103GENCMD component can be configured as either 2
FunctionType parameter; the information number parameter pulsed ON/OFF or 2 steady ON/OFF outputs. The ON output
is defined for each output signal. is pulsed with a command with value 2, while the OFF output
is pulsed with a command with value 1. If in steady mode is
Function status fault protection for IEC 60870-5-103 ON asserted and OFF deasserted with command 2 and vice
I103FLTPROT versa with command 1.
I103FLTPROT is used for fault indications in monitor
direction. Each input on the function block is specific for a IED commands with position and select for IEC 60870-5-103
certain fault type and therefore must be connected to a I103POSCMD
correspondent signal present in the configuration. For I103POSCMD has double-point position indicators that are
example: 68_TRGEN represents the General Trip of the getting the position value as an integer (for example, from the
device and must be connected to the general trip signal POSITION output of the SCSWI function block) and sending it
SMPPTRC_TRIP or equivalent. over IEC 60870-5-103 (1=OPEN; 2=CLOSE). The standard
does not define the use of values 0 and 3. However, when
IED status for IEC 60870-5-103 I103IED connected to a switching device, these values are
I103IED is a function block with defined IED functions in transmitted.
monitor direction. This block uses the parameter
FunctionType; the information number parameter is defined The BLOCK input will block only the signals in monitoring
for each input signal. direction (the position information), not the commands via IEC
60870-5-103. The SELECT input is used to indicate that the
Supervison status for IEC 60870-5-103 I103SUPERV monitored apparatus has been selected (in a select-before-
I103SUPERV is a function block with defined functions for operate type of control).
supervision indications in monitor direction. This block
includes the FunctionType parameter; the information number DNP3.0 communication protocol
SEMOD153688-5 v3
parameter is defined for each output signal. An electrical RS485 serial port, optical serial ports on the
serial communication module (SLM), optical Ethernet ports
Status for user-defined signals for IEC 60870-5-103 are available for DNP3.0 communication. DNP3.0 Level 2
I103USRDEF communication with unsolicited events, time synchronization
I103USRDEF comprises function blocks with user-defined and disturbance reporting is provided for communication to
input signals in monitor direction. These function blocks RTUs, Gateways or HMI systems.
ABB 41
1MRK 511 404-BEN A
21. Hardware description

Multiple command and transmit
M14791-3 v3
When IEDs are used in Substation Automation systems with Hardware modules
IP14529-1 v1
LON, SPA or IEC 60870-5-103 communication protocols, the Numeric processing module NUM
M12643-3 v3
Event and Multiple Command function blocks are used as the The numeric processing module (NUM) is a CPU module that
communication interface for vertical communication to station handles all protection functions and logic.
HMI and gateway, and as interface for horizontal peer-to-peer
communication (over LON only). NUM provides up to 4 optical (type LC) or galvanic (type
RJ45) Ethernet ports(one basic and three optional).
20. Remote communication Power supply module PSM

M11595-3 v6
The power supply module is used to provide the correct
Analog and binary signal transfer to remote end internal voltages and full isolation between the IED and the
M12449-6 v3
Three analog and eight binary signals can be exchanged battery system. An internal fail alarm output is available.
between two IEDs. This functionality is mainly used for the
line differential protection. However it can be used in other Alternative connectors of Ring lug or Compression type can
products as well. An IED can communicate with up to 4 be ordered.
remote IEDs.
Binary input module BIM
M1769-3 v4
Binary signal transfer The binary input module has 16 optically isolated inputs and
SEMOD52522-4 v7
The remote end data communication is used for the is available in two versions, one standard and one with
transmission of analog values for line differential protection or enhanced pulse counting capabilities on the inputs to be
for the transmission of only binary signals between IEDs. The used with the pulse counter function. The binary inputs are
binary signals are freely configurable and can thus be used freely programmable and can be used for the input of logical
for any purpose, such as communication scheme related signals to any of the functions. They can also be included in
signals, transfer trip and/or other binary signals between the disturbance recording and event-recording functions. This
IEDs. enables extensive monitoring and evaluation of operation of
the IED and for all associated electrical circuits.
Communication between two IEDs requires that each IED is
equipped with a Line Data Communication Module (LCDM). Binary output module BOM
M6938-3 v4
The LDCM then acts as an interface to 64 kbit/s and 2Mbit/s The binary output module has 24 independent output relays
communication channels for duplex communication between and is used for trip output or any signaling purpose.
the IEDs. In 2Mbit/s mode, each LDCM can send and receive
up to 9 analog and up to 192 binary signals simultaneously. Static binary output module SOM
SEMOD174196-4 v4
In 64kbit/s mode, the LDCM can be configured to work in The static binary output module has six fast static outputs
either analog mode or binary mode. In analog mode, the IED and six change over output relays for use in applications with
can send and receive up to 3 analog signals and up to 8 high speed requirements.
binary signals. In binary mode, the LDCM can send and
Binary input/output module IOM
receive only binary data (up to 192 binary signals). M6939-3 v6
The binary input/output module is used when only a few input
The IED can be equipped with up to two short range, medium and output channels are needed. The ten standard output
range or long range LDCMs. channels are used for trip output or any signaling purpose.
The two high speed signal output channels are used for
Line data communication module, short, medium and long applications where short operating time is essential. Eight
range LDCM optically isolated binary inputs cater for required binary input
SEMOD168481-4 v10
The line data communication module (LDCM) is used for information.
communication between the IEDs situated at a distance <110
km/68 miles or from the IED to the optical-to-electrical mA input module MIM
M15020-3 v4
converter with G.703 or G.703E1 interface located at a The milli-ampere input module is used to interface transducer
distance < 3 km/1.9 miles away. The LDCM module sends signals in the –20 to +20 mA range from for example OLTC
and receives data to and from another LDCM module. The position, temperature or pressure transducers. The module
IEEE/ANSI C37.94 standard format is used. has six independent, galvanically separated channels.
Galvanic interface G.703 resp G.703E1 Optical Ethernet module

M16073-3 v7
The external galvanic data communication converter G.

M16035-3 v5
The optical Ethernet module (OEM) provides two additional
703/G.703E1 makes an optical-to-galvanic conversion for optical ethernet ports. The port connectors are of LC type.
connection to a multiplexer. These units are designed for 64
kbit/s resp 2Mbit/s operation. The converter is delivered with
19” rack mounting accessories.
42 ABB
1MRK 511 404-BEN A
Serial and LON communication module (SLM) for SPA/IEC

60870-5-103, LON and DNP 3.0 Layout and dimensions
IP14539-1 v1
The Serial and LON communication module (SLM) is used for

M14933-3 v5
Dimensions
M15243-4 v1
IP14826-1 v6
SPA, IEC 60870-5-103, DNP3 and LON communication. SLM

has two optical communication ports for plastic/plastic,
plastic/glass or glass/glass fibre cables. One port is used for
serial communication (SPA, IEC 60870-5-103 or DNP3 port) E
and the other port is used for LON communication.
Line data communication module LDCM

M16075-3 v5
Each module has one optical port, one for each remote end
to which the IED communicates.
Alternative modules for Long range (1550 nm single mode), A

D
Medium range (1310 nm single mode) and Short range (850
nm multi mode) are available.
Galvanic RS485 serial communication module

SEMOD158664-5 v3
The Galvanic RS485 communication module (RS485) is used
for DNP3.0 and IEC 60870-5-103 communication. The
module has one RS485 communication port. The RS485 is a
B
balanced serial communication that can be used either in 2- C
wire or 4-wire connections. A 2-wire connection uses the
same signal for RX and TX and is a multidrop communication
with no dedicated Master or slave. This variant requires
however a control of the output. The 4-wire connection has IEC08000163 V2 EN-US
separated signals for RX and TX multidrop communication Figure 8. Case with rear cover
with a dedicated Master and the rest are slaves. No special
control signal is needed in this case.
GPS time synchronization module GTM

M14851-3 v4
This module includes a GPS receiver used for time
synchronization. The GPS has one SMA contact for
connection to an antenna. It also includes an optical PPS ST-
connector output. K
F
IRIG-B Time synchronizing module
SEMOD141113-4 v8
The IRIG-B time synchronizing module is used for accurate
time synchronizing of the IED from a station clock.
Electrical (BNC) and optical connection (ST) for 0XX and 12X
IRIG-B support.
Transformer input module TRM

M14875-3 v9
The transformer input module is used to galvanically separate G
and adapt the secondary currents and voltages generated by J
H
the measuring transformers. The module has twelve inputs in
different combinations of currents and voltage inputs.
Alternative connectors of Ring lug or Compression type can

be ordered. IEC08000165-2-en.vsdx
High impedance resistor unit Figure 9. Case with rear cover and 19” rack mounting kit
M16727-3 v2
The high impedance resistor unit, with resistors for pick-up
value setting and a voltage dependent resistor, is available in
a single phase unit and a three phase unit. Both are mounted
on a 1/1 19 inch apparatus plate with compression type
terminals.
ABB 43
1MRK 511 404-BEN A
M15243-12 v9
Figure 10. A 1/2 x 19” size IED side-by-side with RHGS6.
Case size A B C D E F G H J K
(mm)/(inches)
6U, 1/2 x 19” 265.9/ 223.7/ 242.1/ 255.8/ 205.7/ 190.5/ 203.7/ - 228.6/ -
10.47 8.81 9.53 10.07 8.10 7.50 8.02 9.00
6U, 3/4 x 19” 265.9/ 336.0/ 242.1/ 255.8/ 318.0/ 190.5/ 316.0/ - 228.6/ -
10.47 13.23 9.53 10.07 12.52 7.50 12.4 9.00
6U, 1/1 x 19” 265.9/ 448.3/ 242.1/ 255.8/ 430.3/ 190.5/ 428.3/ 465.1/ 228.6/ 482.6/19.00
10.47 17.65 9.53 10.07 16.86 7.50 16.86 18.31 9.00
The H and K dimensions are defined by the 19” rack mounting kit.
Mounting alternatives See ordering for details about available mounting alternatives.
M16079-3 v13
• 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
44 ABB
1MRK 511 404-BEN A
22. Connection diagrams Connection diagram, REC670 2.2, A30X00 1MRK002807-CA

GUID-CF4EFFA5-3081-4FC7-9A14-ED127C3C0FDE v6
The connection diagrams are delivered in the IED Connectivity
package as part of the product delivery. Connection diagram, REC670 2.2, B30X00 1MRK002807-CB
The latest versions of the connection diagrams can be Connection diagram, REC670 2.2, C30X00 1MRK002807-CC
downloaded from http://www.abb.com/protection-control.
Connection diagram, REC670 2.2, D30X00 1MRK002807-CE
Connection diagrams for IEC Customized products
Connection diagrams for ANSI Customized products
Connection diagram, 670 series 2.2 1MRK002801-AG
Connection diagram, 670 series 2.2 1MRK002802-AG
Connection diagrams for Configured products
ABB 45
1MRK 511 404-BEN A
23. Technical data
General
M10993-1 v3 IP11376-1 v2
Definitions
Reference value The specified value of an influencing factor to which are referred the characteristics of the equipment
Nominal range The range of values of an influencing quantity (factor) within which, under specified conditions, the equipment meets the
specified requirements
Operative range The range of values of a given energizing quantity for which the equipment, under specified conditions, is able to perform its
intended functions according to the specified requirements
Presumptions for Technical Data 6. Parameter SBase used by the tested function is set
GUID-1E949E38-E04D-4374-A086-912C25E9F93C v1
The technical data stated in this document are only valid equal to:
under the following circumstances: – √3 × IBase × UBase
7. The rated secondary quantities have the following
1. Main current transformers with 1 A or 2 A secondary values:
rating are wired to the IED 1 A rated CT inputs. – Rated secondary phase current I r is either 1 A or 5 A
2. Main current transformer with 5 A secondary rating are
depending on selected TRM.
wired to the IED 5 A rated CT inputs.
– Rated secondary phase-to-phase voltage U r is within
3. CT and VT ratios in the IED are set in accordance with
the range from 100 V to 120 V.
the associated main instrument transformers. Note that
– Rated secondary power for three-phase system S r =
for functions which measure an analogue signal which
√3 × U r × Ir
do not have corresponding primary quantity the 1:1 ratio
shall be set for the used analogue inputs on the IED. 8. For operate and reset time testing, the default setting
Example of such functions are: HZPDIF, ROTIPHIZ and values of the function are used if not explicitly stated
STTIPHIZ. otherwise.
4. Parameter IBase used by the tested function is set 9. During testing, signals with rated frequency have been
equal to the rated CT primary current. injected if not explicitly stated otherwise.
5. Parameter UBase used by the tested function is set
equal to the rated primary phase-to-phase voltage.
46 ABB
1MRK 511 404-BEN A
Energizing quantities, rated values and limits

Analog inputs
M16988-1 v11 IP15842-1 v1
Table 11. TRM - Energizing quantities, rated values and limits for protection transformer
Description Value
Frequency
Rated frequency fr 50/60 Hz
Operating range fr ± 10%
Current inputs
Rated current Ir 1 or 5 A
Operating range (0-100) x Ir
Thermal withstand 100 × Ir for 1 s *)

30 × Ir for 10 s
10 × Ir for 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 are specified as RMS values at rated frequency
ABB 47
1MRK 511 404-BEN A
Table 12. TRM - Energizing quantities, rated values and limits for measuring transformer
Description Value
Frequency
Rated frequency fr 50/60 Hz
Operating range fr ± 10%
Current inputs
Rated current Ir 1A 5A
Operating range (0-1.8) × Ir (0-1.6) × Ir
Thermal withstand 80 × Ir for 1 s 65 × Ir for 1 s

25 × Ir for 10 s 20 × Ir for 10 s
10 × Ir for 1 min 8 × Ir for 1 min
1.8 × Ir for 30 min 1.6 × Ir for 30 min
1.1 × Ir continuously 1.1 × Ir continuously
Burden < 200 mVA at Ir < 350 mVA at Ir
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 are specified as RMS values at rated frequency
M6389-1 v5
Table 13. 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 £2W
each mA input £ 0.1 W
SEMOD55310-2 v11
Table 14. 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 multimode fibre
Wave length 1310 nm, Class 1 laser safety
Optical connector Type LC
Communication speed Fast Ethernet 100 Mbit/s
48 ABB
1MRK 511 404-BEN A
Table 15. SFP - Galvanic RJ45 Table 15. SFP - Galvanic RJ45, continued
Connector Type RJ45
Number of Up to 6 single or 3 redundant or a combination of single
channels and redundant links for communication using any Communi Fast Ethernet 100 Mbit/s
protocol cation
Speed
Standard IEEE 802.3u 100BASE-TX
Type of Cat5e FTP

cable
Auxiliary DC voltage
M12286-1 v6 IP15843-1 v3
Table 16. PSM - Power supply module
Quantity Rated value Nominal range
Auxiliary DC voltage, EL (input) EL = (24-60) V EL ±20%

EL = (100-250) V EL ±20%
Power consumption 50 W typically -
Auxiliary DC power in-rush < 10 A during 0.1 s -
Binary inputs and outputs

M12576-1 v9 IP15844-1 v1
Table 17. BIM - Binary input module
Binary inputs 16 -
DC voltage, RL 24/30 V RL ±20%

48/60 V RL ±20%
110/125 V RL ±20%
220/250 V RL ±20%
Power consumption
24/30 V, 50 mA max. 0.05 W/input -
48/60 V, 50 mA max. 0.1 W/input
110/125 V, 50 mA max. 0.2 W/input
220/250 V, 50 mA max. 0.4 W/input
220/250 V, 110 mA 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
ABB 49
1MRK 511 404-BEN A
M50609-2 v7
Maximum 176 binary input channels may

be activated simultaneously with influencing
factors within nominal range.
Table 18. BIM - Binary input module with enhanced pulse counting capabilities
Binary inputs 16 -

48/60 V RL ±20%
110/125 V RL ±20%
220/250 V RL ±20%
Power consumption
24/30 V max. 0.05 W/input -
48/60 V max. 0.1 W/input
110/125 V max. 0.2 W/input
220/250 V max. 0.4 W/input
Counter input frequency 10 pulses/s max -
Balanced counter input frequency 40 pulses/s max -
Oscillating signal discriminator Blocking settable 1–40 Hz

Release settable 1–30 Hz
Debounce filter Settable 1-20 ms

M12573-1 v9

Table 19. IOM - Binary input/output module
Binary inputs 8 -

48/60 V RL ±20%
110/125 V RL ±20%
220/250 V RL ±20%
Power consumption -
24/30 V, 50 mA max. 0.05 W/input
48/60 V, 50 mA max. 0.1 W/input
110/125 V, 50 mA max. 0.2 W/input
220/250 V, 50 mA max. 0.4 W/input
220/250 V, 110 mA 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
50 ABB
1MRK 511 404-BEN A
M12318-1 v8

Table 20. IOM - Binary input/output module contact data (reference standard: IEC 61810-2)
Function or quantity Trip and signal relays Fast signal relays (parallel
reed relay)
Binary outputs 10 2
Max system voltage 250 V AC, DC 250 V DC
Test voltage across open contact, 1 min 1000 V rms 800 V DC
Current carrying capacity

Per relay, continuous 8A 8A
Per relay, 1 s 10 A 10 A
Per process connector pin, continuous 12 A 12 A
Making capacity at inductive load with L/R > 10 ms
0.2 s
1.0 s 30 A 0.4 A
10 A 0.4 A
Making capacity at resistive load

220–250 V/0.4 A
0.2 s 30 A 110–125 V/0.4 A
1.0 s 10 A 48–60 V/0.2 A
24–30 V/0.1 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 48 V/1 A 48 V/1 A

110 V/0.4 A 110 V/0.4 A
125 V/0.35 A 125 V/0.35 A
220 V/0.2 A 220 V/0.2 A
250 V/0.15 A 250 V/0.15 A
Maximum capacitive load - 10 nF
Maximum 72 outputs may be activated activated during 1 s. Continued activation

simultaneously with influencing factors is possible with respect to current
within nominal range. After 6 ms an consumption but after 5 minutes the
additional 24 outputs may be activated. temperature rise will adversely affect the
The activation time for the 96 outputs must hardware life. Maximum two relays per
not exceed 200 ms. 48 outputs can be
ABB 51
1MRK 511 404-BEN A
M12584-1 v7
BOM/IOM/SOM should be activated
continuously due to power dissipation.
Table 21. IOM with MOV and IOM 220/250 V, 110mA - contact data (reference standard: IEC 61810-2)
Function or quantity Trip and Signal relays Fast signal relays (parallel reed relay)
Binary outputs IOM: 10 IOM: 2
Max system voltage 250 V AC, DC 250 V DC
Test voltage across open 250 V rms 250 V rms

contact, 1 min

Per relay, continuous 8A 8A
Per relay, 1 s 10 A 10 A
Per process connector pin, 12 A 12 A
continuous
Making capacity at inductive

loadwith L/R > 10 ms
0.2 s 30 A 0.4 A
1.0 s 10 A 0.4 A
Making capacity at resistive load

220–250 V/0.4 A
0.2 s 30 A 110–125 V/0.4 A
1.0 s 10 A 48–60 V/0.2 A
24–30 V/0.1 A
Breaking capacity for AC, cos j 250 V/8.0 A 250 V/8.0 A

> 0.4
Breaking capacity for DC with 48 V/1 A 48 V/1 A

L/R < 40 ms 110 V/0.4 A 110 V/0.4 A
220 V/0.2 A 220 V/0.2 A
250 V/0.15 A 250 V/0.15 A
Maximum capacitive load - 10 nF
Maximum 72 outputs may be activated activated during 1 s. Continued activation

simultaneously with influencing factors is possible with respect to current
within nominal range. After 6 ms an consumption but after 5 minutes the
additional 24 outputs may be activated. temperature rise will adversely affect the
The activation time for the 96 outputs must hardware life. Maximum two relays per
not exceed 200 ms. 48 outputs can be
52 ABB
1MRK 511 404-BEN A
SEMOD175395-2 v7
BOM/IOM/SOM should be activated
continuously due to power dissipation.
Table 22. SOM - Static Output Module (reference standard: IEC 61810-2): Static binary outputs
Function of quantity Static binary output trip
Rated voltage 48-60 VDC 110-250 VDC
Number of outputs 6 6
Impedance open state ~300 kΩ ~810 kΩ
Test voltage across open contact, 1 min No galvanic separation No galvanic separation
Current carrying capacity:
Continuous 5A 5A
1.0 s 10 A 10 A
Making capacity at capacitive load with the

maximum capacitance of 0.2 μF :
0.2 s 30 A 30 A
1.0 s 10 A 10 A
Breaking capacity for DC with L/R ≤ 40 ms 48 V/1 A 110 V/0.4 A
60 V/0.75 A 125 V/0.35 A
220 V/0.2 A
250 V/0.15 A
Operating time < 1 ms < 1 ms
ABB 53
1MRK 511 404-BEN A
Table 23. SOM - Static Output module data (reference standard: IEC 61810-2): Electromechanical relay outputs
Function of quantity Trip and signal relays
Max system voltage 250 V AC/DC
Number of outputs 6
Test voltage across open contact, 1 min 1000 V rms
Current carrying capacity:
Continuous 8A
1.0 s 10 A
Making capacity at capacitive load with the maximum capacitance of

0.2 μF:
0.2 s 30 A
1.0 s 10 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
M12441-1 v8
Table 24. BOM - Binary output module contact data (reference standard: IEC 61810-2)
Function or quantity Trip and Signal relays
Binary outputs 24
Max system voltage 250 V AC, DC
Test voltage across open contact, 1 min 1000 V rms

Per relay, continuous 8A
Per relay, 1 s 10 A
Per process connector pin, continuous 12 A
Making capacity at inductive load with L/R > 10 ms

0.2 s 30 A
1.0 s 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
Influencing factors
M16705-1 v12 IP15846-1 v1
Table 25. Temperature and humidity influence
Parameter Reference value Nominal range Influence
Ambient temperature, operate +20°C -10°C to +55°C 0.02%/°C

value
Relative humidity 10-90% 10-90% -

Operative range 0-95%
Storage temperature - -40°C to +70°C -
54 ABB
1MRK 511 404-BEN A
Table 26. Auxiliary DC supply voltage influence on functionality during operation
Dependence on Reference value Within nominal Influence

range
Ripple, in DC auxiliary voltage max. 2% 15% of EL 0.01%/%

Operative range Full wave rectified
Auxiliary voltage dependence, operate ±20% of EL 0.01%/%

value
Interrupted auxiliary DC voltage 24-60 V DC ± 20%
100-250 V DC ±20%
Interruption
interval
0–50 ms No restart
0–∞ s Correct behaviour at power down
Restart time < 300 s
Table 27. Frequency influence (reference standard: IEC 60255–1)
Dependence on Within nominal range Influence
Frequency dependence, operate value fr ±2.5 Hz for 50 Hz ±1.0%/Hz

fr ±3.0 Hz for 60 Hz
Harmonic frequency dependence (20% content) 2nd, 3rd and 5th harmonic of fr ±2.0%
Harmonic frequency dependence for high impedance differential 2nd, 3rd and 5th harmonic of fr ±10.0%
protection (10% content)
Harmonic frequency dependence for overcurrent protection 2nd, 3rd and 5th harmonic of fr ±3.0%
Type tests according to standards

M16706-1 v10 IP15778-1 v1
ABB 55
1MRK 511 404-BEN A
Table 28. Electromagnetic compatibility
Test Type test values Reference standards
1 MHz burst disturbance 2.5 kV IEC 60255-26
100 kHz slow damped oscillatory wave immunity test 2.5 kV IEC 61000-4-18, Class III
Ring wave immunity test, 100 kHz 2-4 kV IEC 61000-4-12, Class IV
Surge withstand capability test 2.5 kV, oscillatory IEEE/ANSI C37.90.1

4.0 kV, fast transient
Electrostatic discharge 15 kV air discharge IEC 60255-26

Direct application 8 kV contact discharge
Indirect application 8 kV contact discharge IEC 61000-4-2, Class IV
Electrostatic discharge 15 kV air discharge IEEE/ANSI C37.90.1

Direct application 8 kV contact discharge
Indirect application 8 kV contact discharge
Fast transient disturbance 4 kV IEC 60255-26, Zone A

(SFP galvanic RJ45: 2kV)
Surge immunity test 2-4 kV, 1.2/50 ms IEC 60255-26, Zone A

high energy
Power frequency immunity test 150-300 V, 50 Hz IEC 60255-26, Zone A
Conducted common mode immunity test 15 Hz-150 kHz IEC 61000-4-16, Class IV
Power frequency magnetic field test 1000 A/m, 3 s IEC 61000-4-8, Class V
100 A/m, cont.
Pulse magnetic field immunity test 1000 A/m IEC 61000–4–9, Class V
Damped oscillatory magnetic field test 100 A/m IEC 61000-4-10, Class V
Radiated electromagnetic field disturbance 20 V/m, 80-1000 MHz IEC 60255-26
1.4-2.7 GHz
Radiated electromagnetic field disturbance 20 V/m IEEE/ANSI C37.90.2

80-1000 MHz
Conducted electromagnetic field disturbance 10 V, 0.15-80 MHz IEC 60255-26
Radiated emission 30-5000 MHz IEC 60255-26
Radiated emission 30-5000 MHz IEEE/ANSI C63.4, FCC
Conducted emission 0.15-30 MHz IEC 60255-26
Table 29. Insulation
Test Type test values Reference standard
Dielectric test 2.0 kV AC, 1 min. IEC 60255-27

(SFP galvanic RJ45: 1.0 kV, ANSI C37.90
1 min.) IEEE 802.3-2015,
Environment A
Impulse voltage test 5 kV, 1.2/50 ms, 0.5 J
Insulation resistance > 100 MW at 500 VDC
56 ABB
1MRK 511 404-BEN A
Table 30. Environmental tests
Test Type test value Reference standard
Cold operation test Test Ad for 16 h at -25°C IEC 60068-2-1
Cold storage test Test Ab for 16 h at -40°C IEC 60068-2-1
Dry heat operation test Test Bd for 16 h at +70°C IEC 60068-2-2
Dry heat storage test Test Bb for 16 h at +85°C IEC 60068-2-2
Change of temperature test Test Nb for 5 cycles at -25°C to +70°C IEC 60068-2-14
Damp heat test, steady state Test Ca for 10 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 = IEC 60068-2-30
24 hours)
Table 31. CE compliance
Test According to
Immunity EN 60255–26
Emissivity EN 60255–26
Low voltage directive EN 60255–27
Table 32. Mechanical tests
Test Type test values Reference standards
Vibration response test Class II IEC 60255-21-1
Vibration endurance test Class I IEC 60255-21-1
Shock response test Class I IEC 60255-21-2
Shock withstand test Class I IEC 60255-21-2
Bump test Class I IEC 60255-21-2
Seismic test Class II IEC 60255-21-3
ABB 57
1MRK 511 404-BEN A
Differential protection
M13081-1 v12
Table 33. High impedance differential protection, single phase HZPDIF
Function Range or value Accuracy
Operate voltage (10-900) V ±1.0% of Ir at I ≤ Ir

I=U/R ±1.0% of I at I > Ir
Reset ratio >95% at (30-900) V -
Maximum continuous power U>Trip2/SeriesResistor ≤200 W -
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 ms typically at 0 to 2 x Ud -
58 ABB
1MRK 511 404-BEN A
Wide area measurement system

GUID-F0BAEBD8-E361-4D50-9737-7DF8B043D66A v4
Table 34. Protocol reporting via IEEE 1344 and C37.118 PMUREPORT
Influencing quantity Range Accuracy
Signal frequency ± 0.1 x fr ≤ 1.0% TVE
Signal magnitude:
Voltage phasor (0.1–1.2) x Ur
Current phasor (0.5–2.0) x Ir
Phase angle ± 180°
Harmonic distortion 10% from 2nd – 50th
Interfering signal:
Magnitude 10% of fundamental signal
Minimum frequency 0.1 x fr
Maximum frequency 1000 Hz
ABB 59
1MRK 511 404-BEN A
Current protection
M12336-1 v13
Table 35. Instantaneous phase overcurrent protection PHPIOC
Operate current (5-2500)% of lBase ±1.0% of Ir at I ≤ Ir

±1.0% of I at I > Ir
Reset ratio > 95% at (50–2500)% of IBase -
Operate time at 0 to 2 x Iset 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 -

Max. = 15 ms

Max. = 40 ms
Dynamic overreach < 5% at t = 100 ms -
60 ABB
1MRK 511 404-BEN A
M12342-1 v20
Table 36. Directional phase overcurrent protection, four steps OC4PTOC
Function Setting range Accuracy
Operate current, step 1-4 (5-2500)% of lBase ±1.0% of Ir at I ≤ Ir

Reset ratio > 95% at (50–2500)% of lBase -
Minimum operate current, step 1-4 (1-10000)% of lBase ±1.0% of Ir at I ≤ Ir

Relay characteristic angle (RCA) (40.0–65.0) degrees ±2.0 degrees
Relay operating angle (ROA) (40.0–89.0) degrees ±2.0 degrees
Second harmonic blocking (5–100)% of fundamental ±2.0% of Ir
Independent time delay at 0 to 2 x Iset, step (0.000-60.000) s ±0.2% or ±35 ms whichever is greater
1-4
Minimum operate time for inverse curves , (0.000-60.000) s ±0.2% or ±35 ms whichever is greater
step 1-4
Inverse time characteristics, see table 155, 16 curve types See table 155, table 156 and table 157
table 156 and table 157
Operate time, start non-directional at 0 to 2 x Min. = 15 ms -

Iset
Max. = 30 ms
Reset time, start non-directional at 2 x Iset to 0 Min. = 15 ms -
Max. = 30 ms

Iset Max. = 20 ms
Reset time, start non-directional at 10 x Iset to Min. = 20 ms -

0 Max. = 35 ms
Impulse margin time 15 ms typically -

M12340-2 v9
Table 37. Instantaneous residual overcurrent protection EFPIOC
Operate current (5-2500)% of lBase ±1.0% of Ir at I ≤ Ir

Reset ratio > 95% at (50–2500)% of lBase -

Max. = 25 ms

Max. = 25 ms

Max. = 15 ms

Max. = 35 ms
Dynamic overreach < 5% at t = 100 ms -
ABB 61
1MRK 511 404-BEN A
M15223-1 v17
Table 38. Directional residual overcurrent protection, four steps EF4PTOC
Operate current, step 1-4 (1-2500)% of IBase ±1.0% of Ir at I ≤ Ir

Reset ratio > 95% at (10-2500)% of IBase -
Relay characteristic angle (-180 to 180) degrees ±2.0 degrees

(RCA)
Operate current for directional release (1–100)% of IBase For RCA ±60 degrees:
±2.5% of Ir at I ≤ Ir
Independent time delay at 0 to 2 x Iset, step (0.000-60.000) s ±0.2% or ±35 ms whichever is greater
1-4
Minimum operate time for inverse curves, (0.000 - 60.000) s ±0.2% or ±35 ms whichever is greater
step 1-4
Inverse time characteristics, see Table 155, 16 curve types See Table 155, Table 156 and Table 157
Table 156 and Table 157
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 (0.50-1000.00) W/phase -

polarization
Imaginary part of source Z used for current (0.50–3000.00) W/phase -

polarization

Iset Max. = 30 ms

0 Max. = 30 ms
Operate time, start non-directional at 0 to 10 Min. = 5 ms -

x Iset Max. = 20 ms

0 Max. = 35 ms
62 ABB
1MRK 511 404-BEN A
GUID-E83AD807-8FE0-4244-A50E-86B9AF92469E v6
Table 39. Four step directional negative phase sequence overcurrent protection NS4PTOC
Operate current, step 1 - 4 (1-2500)% of lBase ±1.0% of Ir at I £ Ir

Independent time delay at 0 to 2 x Iset, (0.000-60.000) s ±0.2% or ±35 ms whichever is greater

step 1 - 4
step 1 - 4
Inverse time characteristics, see table 16 curve types See table 155, table 156 and table 157
155, table 156 and table 157
Minimum operate current, step 1 - 4 (1.00 - 10000.00)% of IBase ±1.0% of Ir at I ≤ Ir

Relay characteristic angle (RCA) (-180 to 180) degrees ±2.0 degrees
Operate current for directional release (1–100)% of IBase For RCA ±60 degrees:
±2.5% of Ir at I ≤ Ir
Minimum polarizing voltage (1–100)% of UBase ±0.5% of Ur
Real part of negative sequence source (0.50-1000.00) W/phase -

impedance used for current polarization
Imaginary part of negative sequence (0.50–3000.00) W/phase -

source impedance used for current
polarization
Operate time, start non-directional at 0 to Min. = 15 ms -

2 x Iset Max. = 30 ms
Reset time, start non-directional at 2 x Iset Min. = 15 ms -

to 0 Max. = 30 ms
Operate time, start non-directional at 0 to Min. = 5 ms -

10 x Iset Max. = 20 ms
Reset time, start non-directional at 10 x Min. = 20 ms -

Iset to 0 Max. = 35 ms
Transient overreach <10% at τ = 100 ms -
ABB 63
1MRK 511 404-BEN A
SEMOD173350-2 v16
Table 40. Sensitive directional residual overcurrent and power protection SDEPSDE
Operate level for 3I0·cosj directional residual (0.25-200.00)% of IBase ±1.0% of Ir at I £ Ir

overcurrent ±1.0% of I at I > Ir
Operate level for ·3I0·3U0 cosj directional (0.25-200.00)% of SBase ±1.0% of Sr at S £ Sr

residual power ±1.0% of S at S > Sr
Operate level for 3I0 and j residual (0.25-200.00)% of IBase ±1.0% of Ir at £ Ir

overcurrent ±1.0% of I at I > Ir
Operate level for non-directional overcurrent (1.00-400.00)% of IBase ±1.0% of Ir at I £ Ir

Operate level for non-directional residual (1.00-200.00)% of UBase ±0.5% of Ur at U £ Ur

overvoltage ±0.5% of U at U > Ur
Residual release current for all directional (0.25-200.00)% of IBase ±1.0% of Ir at I £ Ir

modes ±1.0% of I at I > Ir
Residual release voltage for all directional (1.00-300.00)% of UBase ±0.5% of Ur at U £ Ur

modes ±0.5% of U at U > Ur
Operate time for non-directional residual Min. = 40 ms

overcurrent at 0 to 2 x Iset
Max. = 65 ms
Reset time for non-directional residual Min. = 40 ms

overcurrent at 2 x Iset to 0
Max. = 65 ms
Operate time for directional residual Min. = 110 ms

overcurrent at 0 to 2 x Iset
Max. = 160 ms
Reset time for directional residual overcurrent Min. = 20 ms

at 2 x Iset to 0
Max. = 60 ms
Independent time delay for non-directional (0.000 – 60.000) s ±0.2% or ± 75 ms whichever is greater
residual overvoltage at 0.8 x Uset to 1.2 x Uset
Independent time delay for non-directional (0.000 – 60.000) s ±0.2% or ± 75 ms whichever is greater
residual overcurrent at 0 to 2 x Iset
Independent time delay for directional (0.000 – 60.000) s ±0.2% or ± 170 ms whichever is greater
residual overcurrent at 0 to 2 x Iset
Inverse characteristics, see table 158, 16 curve types See Table 158, Table 159 and Table 160
Table 159 and Table 160
Relay characteristic angle (RCADir) (-179 to 180) degrees ±2.0 degrees
Relay operate angle (ROADir) (0 to 90) degrees ±2.0 degrees
64 ABB
1MRK 511 404-BEN A
M12352-1 v14
Table 41. Thermal overload protection, one time constant LCPTTR/LFPTTR
Reference current (2-400)% of IBase ±1.0% of Ir
Reference temperature (0-300)°C, (0 - 600)°F ±1.0°C, ±2.0°F
Operate time: Time constant t = (1–1000) IEC 60255-149, ±5.0% or ±200 ms whichever is greater
minutes
é ù
ê I - Ip
2 2 ú
t = t ln ê ú
ê 2 2 TTrip - TAmb 2 ú
ê I - Ip - T × I ref
ú
ë ref û
EQUATION13000039 V2 EN-US (Equation 1)
TTrip= set operate temperature

TAmb = ambient temperature
Tref = temperature rise above ambient at Iref
Iref = reference load current
I = actual measured current
Ip = load current before overload occurs
Alarm temperature (0-200)°C, (0-400)°F ±2.0°C, ±4.0°F
Operate temperature (0-300)°C, (0-600)°F ±2.0°C, ±4.0°F
Reset level temperature (0-300)°C, (0-600)°F ±2.0°C, ±4.0°F

M13266-2 v8
Table 42. Thermal overload protection, two time constants TRPTTR
Base current 1 and 2 (30–250)% of IBase ±1.0% of Ir
Operate time: Ip = load current before overload ±5.0% or ±200 ms whichever is greater
occurs
æ I 2 - I p2 ö Time constant τ = (0.10–500.00)
t = t × ln ç 2 ÷ minutes
ç I - I ref 2 ÷
è ø
I = actual measured current

Ip = load current before overload
occurs
Iref = reference load current
Alarm level 1 and 2 (50–99)% of heat content ±2.0% of heat content trip
operate value
Operate current (50–250)% of IBase ±1.0% of Ir
Reset level temperature (10–95)% of heat content trip ±2.0% of heat content trip
ABB 65
1MRK 511 404-BEN A
M12353-1 v14
Table 43. Breaker failure protection CCRBRF
Operate phase current (5-200)% of lBase ±1.0% of Ir at I £ Ir

Reset ratio, phase current > 95% -
Operate residual current (2-200)% of lBase ±1.0% of Ir 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
Reset ratio > 95% -
Operate time for current detection 10 ms typically -
Reset time for current detection 15 ms maximum -
Time delay for re-trip at 0 to 2 x Iset (0.000-60.000) s ±0.2% or ±15 ms whichever is greater
Time delay for back-up trip at 0 to 2 x Iset (0.000-60.000) s ±0.2% or ±15 ms whichever is greater
Time delay for back-up trip at multi-phase start at (0.000-60.000) s ±0.2% or ±20 ms whichever is greater
0 to 2 x Iset
Additional time delay for a second back-up trip at (0.000-60.000) s ±0.2% or ±20 ms whichever is greater
0 to 2 x Iset
Time delay for alarm for faulty circuit breaker (0.000-60.000) s ±0.2% or ±15 ms whichever is greater
M12350-1 v12
Table 44. Stub protection STBPTOC
Operating current (5-2500)% of IBase ±1.0% of Ir at I ≤ Ir

Independent time delay at 0 to 2 x Iset (0.000-60.000) s ±0.2% or ±30 ms whichever is greater
Operate time, start at 0 to 2 x Iset Min. = 10 ms -

Max. = 20 ms
Reset time, start at 2 x Iset to 0 Min. = 10 ms -

Max. = 20 ms

M13279-1 v10
Table 45. Pole discordance protection CCPDSC
Operate current (0–100)% of IBase ±1.0% of Ir
Independent time delay (0.000-60.000) s ±0.2% or ± 30 ms whichever is greater

between trip condition and trip
signal
66 ABB
1MRK 511 404-BEN A
SEMOD175152-2 v11
Table 46. Directional underpower protection GUPPDUP
Power level (0.0–500.0)% of SBase ±1.0% of Sr at S ≤ Sr

for Step 1 and Step 2 ±1.0% of S at S > Sr
where
S r = 1.732 × U r × I r
Characteristic angle (-180.0–180.0) degrees ±2.0 degrees

for Step 1 and Step 2
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 Sr to 0.5 x Sr and k=0.000
SEMOD175159-2 v9
Table 47. Directional overpower protection GOPPDOP
Power level (0.0–500.0)% of SBase ±1.0% of Sr at S ≤ Sr

for Step 1 and Step 2 ±1.0% of S at S > Sr
Characteristic angle (-180.0–180.0) degrees ±2.0 degrees

for Step 1 and Step 2
Operate time, start at 0.5 x Sr to 2 x Sr and Min. =10 ms

k=0.000
Max. = 25 ms
Reset time, start at 2 x Sr to 0.5 x Sr and Min. = 35 ms

k=0.000
Max. = 55 ms
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 0.5 x Sr to 2 x Sr and k=0.000
SEMOD175200-2 v7
Table 48. Broken conductor check BRCPTOC
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 (0.000-60.000) s ±0.2% or ±45 ms whichever is greater
Independent reset time delay (0.010-60.000) s ±0.2% or ±30 ms whichever is greater
Start time at current change from Ir to 0 Min. = 25 ms -

Max. = 35 ms
Reset time at current change from 0 to Ir Min. = 5 ms -

Max. = 20 ms
ABB 67
1MRK 511 404-BEN A
GUID-6A7DA510-E145-4C5B-A7DC-97BC4258E621 v9
Table 49. Capacitor bank protection CBPGAPC
Operate value, overcurrent (10-900)% of lBase ±2.0% of Ir at I ≤ Ir

Reset ratio, overcurrent >95% at (100-900)% of IBase -
Start time, overcurrent, at 0.5 x Iset Min. = 5 ms -

to 2 x Iset Max. = 20 ms
Reset time, overcurrent, at 2 x Iset to Min. = 25 ms -

0.5 x Iset Max. = 40 ms
Critical impulse time, overcurrent 2 ms typically at 0.5 x Iset to 2 x Iset -

protection start 1 ms typically at 0.5 x Iset to 10 x Iset
Impulse margin time, overcurrent 10 ms typically

protection start
Operate value, undercurrent (5-100)% of IBase ±2.0% of Ir
Reset ratio, undercurrent <105% at (30-100)% of IBase -
Operate value, reconnection inhibit (4-1000)% of IBase ±1.0% of Ir at I ≤ Ir

function ±1.0% of I at I > Ir
Operate value, reactive power (10-900)% ±1.0% of Sr at S ≤ Sr

overload function ±1.0% of S at S > Sr
Operate value, voltage protection (10-500)% ±0.5% of Ur at U ≤ Ur

function for harmonic overload ±0.5% of U at U > Ur
(Definite time)
Operate value, voltage protection (80-200)% ±0.5% of Ur at U ≤ Ur

function for harmonic overload ±0.5% of U at U > Ur
(Inverse time)
Inverse time characteristic According to IEC 60871-1 (2005) and ±20% or ±200 ms whichever is greater
IEEE/ANSI C37.99 (2000)
Maximum trip delay, harmonic (0.05-6000.00) s ±20% or ±200 ms whichever is greater

overload IDMT
Minimum trip delay, harmonic (0.05-60.00) s ±20% or ±200 ms whichever is greater

overload IDMT
Independent time delay, overcurrent (0.00-6000.00) s ±0.2% or ±30 ms whichever is greater

at 0 to 2 x Iset
Independent time delay, undercurrent (0.00-6000.00) s ±0.2% or ±60 ms whichever is greater

at 2 x Iset to 0
Independent time delay, reactive (1.00-6000.00) s ±0.2% or ±100 ms whichever is greater

power overload function at 0 to 2 x
QOL>
Independent time delay, harmonic (0.00-6000.00) s ±0.2% or ±35 ms whichever is greater

overload at 0 to 2 x HOL>
68 ABB
1MRK 511 404-BEN A
GUID-7EA9731A-8D56-4689-9072-D72D9CDFD795 v8
Table 50. Voltage-restrained time overcurrent protection VRPVOC
Start overcurrent (2.0 - 5000.0)% of IBase ±1.0% of Ir at I ≤ Ir

Reset ratio, overcurrent > 95% -
Operate time, start overcurrent at 0 to 2 x Iset Min. = 15 ms -
Max. = 30 ms
Reset time, start overcurrent at 2 x Iset to 0 Min. = 15 ms -
Max. = 30 ms
Operate time, start overcurrent at 0 to 10 x Min. = 5 ms -

Iset Max. = 20 ms
Reset time, start overcurrent at 10 x Iset to 0 Min. = 20 ms -

Max. = 35 ms
Independent time delay to operate at 0 to 2 x (0.00 - 6000.00) s ±0.2% or ±35 ms whichever is greater
Iset
Inverse time characteristics, 13 curve types See tables 155 and 156
see tables 155 and 156
Minimum operate time for inverse time (0.00 - 60.00) s ±0.2% or ±35 ms whichever is greater
characteristics
High voltage limit, voltage dependent (30.0 - 100.0)% of UBase ±1.0% of Ur

operation
Start undervoltage (2.0 - 100.0)% of UBase ±0.5% of Ur
Reset ratio, undervoltage < 105% -
Operate time start undervoltage at 2 x Uset to Min. = 15 ms -

0
Max. = 30 ms
Reset time start undervoltage at 0 to 2 x Uset Min. = 15 ms -
Max. = 30 ms
Independent time delay to operate, (0.00 - 6000.00) s ±0.2% or ±35 ms whichever is greater
undervoltage at 2 x Uset to 0
Internal low voltage blocking (0.0 - 5.0)% of UBase ±0.25% of Ur
Overcurrent: -
Critical impulse time 10 ms typically at 0 to 2 x Iset
Impulse margin time 15 ms typically
Undervoltage: -
Critical impulse time 10ms typically at 2 x Uset to 0
Impulse margin time 15 ms typically
ABB 69
1MRK 511 404-BEN A
Voltage protection
M13290-1 v15
Table 51. Two step undervoltage protection UV2PTUV
Operate voltage, low and high step (1.0–100.0)% of UBase ±0.5% of Ur
Absolute hysteresis (0.0–50.0)% of UBase ±0.5% of Ur
Internal blocking level, step 1 and step 2 (1–50)% of UBase ±0.5% of Ur
Inverse time characteristics for step 1 - See table 164

and step 2, see table 164
Definite time delay, step 1 at 1.2 x Uset to (0.00-6000.00) s ±0.2% or ±40ms whichever is greater
0
Definite time delay, step 2 at 1.2 x Uset to (0.000-60.000) s ±0.2% or ±40ms whichever is greater
0
Minimum operate time, inverse (0.000–60.000) s ±0.5% or ±40ms whichever is greater

characteristics
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 x Uset Min. = 15 ms -

Max. = 35 ms
Critical impulse time 5 ms typically at 1.2 x Uset to 0 -
70 ABB
1MRK 511 404-BEN A
M13304-1 v14
Table 52. Two step overvoltage protection OV2PTOV
Operate voltage, step 1 and 2 (1.0-200.0)% of UBase ±0.5% of Ur at U ≤ Ur

±0.5% of U at U > Ur
Absolute hysteresis (0.0–50.0)% of UBase ±0.5% of Ur at U ≤ Ur

Inverse time characteristics for steps 1 and - See table 163

2, see table 163
Definite time delay, low step (step 1) at 0 (0.00 - 6000.00) s ±0.2% or ±45 ms whichever is greater
to 1.2 x Uset
Definite time delay, high step (step 2) at 0 (0.000-60.000) s ±0.2% or ±45 ms whichever is greater
to 1.2 x Uset
Minimum operate time, Inverse (0.000-60.000) s ±0.2% or ±45 ms whichever is greater

characteristics
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. = 5 ms -

Max. = 25 ms
Critical impulse time 10 ms typically at 0 to 2 x Uset -
ABB 71
1MRK 511 404-BEN A
M13317-2 v14
Table 53. Two step residual overvoltage protection ROV2PTOV
Operate voltage, step 1 - step 2 (1.0-200.0)% of UBase ± 0.5% of Ur at U ≤ Ur

± 0.5% of U at U > Ur
Absolute hysteresis (0.0–50.0)% of UBase ± 0.5% of Ur at U ≤ Ur

± 0.5% of U at U > Ur
Inverse time characteristics for low and - See table 165

high step, see table 165
Definite time delay low step (step 1) at 0 (0.00–6000.00) s ± 0.2% or ± 45 ms whichever is greater
to 1.2 x Uset
Definite time delay high step (step 2) at 0 (0.000–60.000) s ± 0.2% or ± 45 ms whichever is greater
to 1.2 x Uset
Minimum operate time (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. = 5 ms -

Max. = 25 ms
Critical impulse time 10 ms typically at 0 to 2 x Uset -

SEMOD166919-2 v7
Table 54. Voltage differential protection VDCPTOV
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 (0.000–60.000)s ±0.2% or ±40 ms whichever is greater
differential alarm at 0.8 x UDAlarm to 1.2 x
UDAlarm
differential trip at 0.8 x UDTrip to 1.2 x
UDTrip
differential reset at 1.2 x UDTrip to 0.8 x
UDTrip
72 ABB
1MRK 511 404-BEN A
SEMOD175210-2 v6
Table 55. Loss of voltage check LOVPTUV
Operate voltage (1–100)% of UBase ±0.5% of Ur
Pulse timer when disconnecting (0.050–60.000) s ±0.2% or ±15 ms whichever is greater

all three phases
Time delay for enabling the (0.000–60.000) s ±0.2% or ±35 ms whichever is greater
functions after restoration
Operate time delay when (0.000–60.000) s ±0.2% or ±35 ms whichever is greater

disconnecting all three phases
Time delay to block when all (0.000–60.000) s ±0.2% or ±35 ms whichever is greater
three phase voltages are not low
ABB 73
1MRK 511 404-BEN A
Frequency protection
M13360-1 v15
Table 56. Underfrequency protection SAPTUF
Operate value, start function, at symmetrical three (35.00-75.00) Hz ±2.0 mHz

phase voltage
Operate time, start at fset + 0.02 Hz to fset - 0.02 Hz Min. = 80 ms

fn = 50 Hz
Max. = 95 ms
-
Min. = 65 ms
fn = 60 Hz
Max. = 80 ms
Reset time, start at fset - 0.02 Hz to fset + 0.02 Hz Min. = 15 ms

-
Max. = 30 ms
Operate time, definite time function at fset + 0.02 Hz (0.000-60.000)s ±0.2% or ±100 ms whichever is greater
to fset - 0.02 Hz
Reset time, definite time function at fset - 0.02 Hz to (0.000-60.000)s ±0.2% or ±120 ms whichever is greater
fset + 0.02 Hz
Voltage dependent time delay Settings: ±1.0% or ±100 ms whichever is greater

UNom=(50-150)% of Ubase
UMin=(50-150)% of Ubase
Exponent=0.0-5.0
tMax=(0.010–60.000)s
tMin=(0.010–60.000)s
Exponent
é U - UMin ù
t=ê × ( tMax - tMin ) + tMin
ë UNom - UMin úû
U=Umeasured
M14964-1 v12
Table 57. Overfrequency protection SAPTOF
Operate value, start function at symmetrical three-phase voltage (35.00-90.00) Hz ±2.0 mHz
Operate time, start at fset -0.02 Hz to fset +0.02 Hz Min. = 80 ms -

fn = 50Hz
Max. = 95 ms
Min. = 65 ms
fn = 60 Hz
Max. = 80 ms
Reset time, start at fset +0.02 Hz to fset -0.02 Hz Min. = 15 ms -

Max. = 30 ms
Operate time, definite time function at fset -0.02 Hz to fset +0.02 Hz (0.000-60.000)s ±0.2% ±100 ms
whichever is greater
Reset time, definite time function at fset +0.02 Hz to fset -0.02 Hz (0.000-60.000)s ±0.2% ±120 ms,
74 ABB
1MRK 511 404-BEN A
M14976-1 v9
Table 58. Rate-of-change of frequency protection SAPFRC
Operate value, start function (-10.00-10.00) Hz/s ±10.0 mHz/s
Operate value, restore enable frequency (45.00-65.00) Hz ±2.0 mHz
Definite restore time delay (0.000-60.000) s ±0.2% or ±100 ms whichever is

greater
Definite time delay for frequency gradient trip (0.200-60.000) s ±0.2% or ±120 ms whichever is
greater
Definite reset time delay (0.000-60.000) s ±0.2% or ±250 ms whichever is

greater
GUID-E8D0EE7C-D7B8-46C3-9C0D-363FFC75DE93 v5
Table 59. Frequency accumulation protection FTAQFVR
Operate value, frequency high limit level at (35.00 – 90.00) Hz ±2.0 mHz
symmetrical three phase voltage
Operatevalue, frequency low limit level at (30.00 – 85.00) Hz ±2.0 mHz

symmetrical three phase voltage
Operate value, voltage high and low limit (0.0 – 200.0)% of UBase ±0.5% of Ur at U ≤ Ur
for voltage band limit check ±0.5% of U at U > Ur
Operate value, current start level (5.0 – 100.0)% of IBase ±1.0% of Ir or 0.01 A at I≤Ir
Independent time delay for the continuous (0.0 – 6000.0) s ±0.2% or ±250 ms whichever is
time limit at fset+0.02 Hz to fset-0.02 Hz greater
Independent time delay for the (10.0 – 90000.0) s ±0.2% or ±250 ms whichever is
accumulation time limit at fset+0.02 Hz to greater
fset-0.02 Hz
ABB 75
1MRK 511 404-BEN A
Multipurpose protection
M13095-2 v8
76 ABB
1MRK 511 404-BEN A
Table 60. General current and voltage protection CVGAPC
Measuring current input phase1, phase2, phase3, PosSeq, - -

NegSeq, -3*ZeroSeq, MaxPh, MinPh,
UnbalancePh, phase1-phase2,
phase2-phase3, phase3-phase1,
MaxPh-Ph, MinPh-Ph, UnbalancePh-
Ph
Measuring voltage input phase1, phase2, phase3, PosSeq, - -

NegSeq, -3*ZeroSeq, MaxPh, MinPh,
UnbalancePh, phase1-phase2,
phase2-phase3, phase3-phase1,
MaxPh-Ph, MinPh-Ph, UnbalancePh-
Ph
Start overcurrent, step 1 - 2 (2 - 5000)% of IBase ±1.0% of Ir at I ≤ Ir

Start undercurrent, step 1 - 2 (2 - 150)% of IBase ±1.0% of Ir at I ≤ Ir

Independent time delay, overcurrent at 0 (0.00 - 6000.00) s ±0.2% or ±35 ms whichever is greater
to 2 x Iset, step 1 - 2
Independent time delay, undercurrent at (0.00 - 6000.00) s ±0.2% or ±35 ms whichever is greater
2 x Iset to 0, step 1 - 2
Overcurrent (non-directional):
Start time at 0 to 2 x Iset Min. = 15 ms -

Max. = 30 ms

Max. = 30 ms
Start time at 0 to 10 x Iset Min. = 5 ms -

Max. = 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:
Inverse time characteristics, see table 16 curve types See table 155, 156 and table 157
155, 156 and table 157
Overcurrent:
step 1 - 2
Voltage level where voltage memory (0.0 - 5.0)% of UBase ±0.5% of Ur

takes over
Start overvoltage, step 1 - 2 (2.0 - 200.0)% of UBase ±0.5% of Ur at U ≤ Ur

Start undervoltage, step 1 - 2 (2.0 - 150.0)% of UBase ±0.5% of Ur at U ≤ Ur

ABB 77
1MRK 511 404-BEN A
Table 60. General current and voltage protection CVGAPC , continued

Independent time delay, overvoltage at (0.00 - 6000.00) s ±0.2% or ±35 ms whichever is greater
0.8 x Uset to 1.2 x Uset, step 1 - 2
Independent time delay, undervoltage at (0.00 - 6000.00) s ±0.2% or ±35 ms whichever is greater
1.2 x Uset to 0.8 x Uset, step 1 - 2
Overvoltage:
Start time at 0.8 x Uset to 1.2 x Uset Min. = 15 ms -

Max. = 30 ms
Reset time at 1.2 x Uset to 0.8 x Uset Min. = 15 ms -

Max. = 30 ms
Undervoltage:
Start time at 1.2 x Uset to 0.8 x Uset Min. = 15 ms -

Max. = 30 ms
Reset time at 1.2 x Uset to 0.8 x Uset Min. = 15 ms -

Max. = 30 ms
Overvoltage:
Inverse time characteristics, see table 4 curve types See table 163
163
Undervoltage:
Inverse time characteristics, see table 3 curve types See table 164
164
High and low voltage limit, voltage (1.0 - 200.0)% of UBase ±1.0% of Ur at U ≤ Ur
dependent operation, step 1 - 2 ±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, overvoltage > 95% -
Reset ratio, undervoltage < 105% -
Overcurrent:
Undercurrent:
Critical impulse time 10 ms typically at 2 x Iset to 0 -
Overvoltage:
Critical impulse time 10 ms typically at 0.8 x Uset to 1.2 x -

Uset
78 ABB
1MRK 511 404-BEN A
Table 60. General current and voltage protection CVGAPC , continued

Undervoltage:
Critical impulse time 10 ms typically at 1.2 x Uset to 0.8 x -

Uset
ABB 79
1MRK 511 404-BEN A
Secondary system supervision

M12358-1 v10
Table 61. Current circuit supervision CCSSPVC
Operate current (10-200)% of IBase ±10.0% of Ir at I ≤ Ir

±10.0% of I at I > Ir
Reset ratio, Operate current >90%
Block current (20-500)% of IBase ±5.0% of Ir at I ≤ Ir

Reset ratio, Block current >90% at (50-500)% of IBase

M16069-1 v12
Table 62. Fuse failure supervision FUFSPVC
Operate voltage, zero sequence (1-100)% of UBase ±0.5% of Ur
Operate current, zero sequence (1–100)% of IBase ±0.5% of Ir
Operate voltage, negative sequence (1-100)% of UBase ±0.5% of Ur
Operate current, negative sequence (1–100)% of IBase ±0.5% of Ir
Operate voltage change level (1-100)% of UBase ±10.0% of Ur
Operate current change level (1–100)% of IBase ±10.0% of Ir
Operate phase voltage (1-100)% of UBase ±0.5% of 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
80 ABB
1MRK 511 404-BEN A
GUID-E2EA8017-BB4B-48B0-BEDA-E71FEE353774 v5
Table 63. Fuse failure supervision VDSPVC
Operate value, block of main fuse failure (10.0-80.0)% of UBase ±0.5% of Ur
Reset ratio <110%
Operate time, block of main fuse failure at 1 x Ur to 0 Min. = 5 ms –
Max. = 15 ms
Reset time, block of main fuse failure at 0 to 1 x Ur Min. = 15 ms –
Max. = 30 ms
Operate value, alarm for pilot fuse failure (10.0-80.0)% of UBase ±0.5% of Ur
Reset ratio <110% –
Operate time, alarm for pilot fuse failure at 1 x Ur to 0 Min. = 5 ms –
Max. = 15 ms
Reset time, alarm for pilot fuse failure at 0 to 1 x Ur Min. = 15 ms –
Max. = 30 ms
ABB 81
1MRK 511 404-BEN A
Control
M12359-1 v15
Table 64. Synchronizing, synchrocheck and energizing check SESRSYN
Phase shift, jline - jbus (-180 to 180) degrees -
Voltage high limit for synchronizing and synchrocheck (50.0-120.0)% of UBase ±0.5% of Ur at U ≤ Ur
Reset ratio, synchrocheck > 95% -
Frequency difference limit between bus and line for synchrocheck (0.003-1.000) Hz ±2.5 mHz
Phase angle difference limit between bus and line for synchrocheck (5.0-90.0) degrees ±2.0 degrees
Voltage difference limit between bus and line for synchronizing and (0.02-0.5) p.u ±0.5% of Ur
synchrocheck
Time delay output for synchrocheck when angle difference between bus (0.000-60.000) s ±0.2% or ±35 ms whichever is
and line jumps from “PhaseDiff” + 2 degrees to “PhaseDiff” - 2 degrees greater
Frequency difference minimum limit for synchronizing (0.003-0.250) Hz ±2.5 mHz
Frequency difference maximum limit for synchronizing (0.050-1.000) Hz ±2.5 mHz
Maximum closing angle between bus and line for synchronizing (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 (0.000-6000.00) s ±0.2% or ±35 ms whichever is
made before set time 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)% of UBase ±0.5% of Ur at U ≤ Ur

Reset ratio, voltage high limit > 95% -
Voltage low limit for energizing check (10.0-80.0)% of UBase ±0.5% of Ur
Reset ratio, voltage low limit < 105% -
Maximum voltage for energizing (50.0-180.0)% of UBase ±0.5% of Ur at U ≤ Ur

Time delay for energizing check when voltage jumps from 0 to 90% of (0.000-60.000) s ±0.2% or ±100 ms whichever is
Urated greater
Operate time for synchrocheck function when angle difference between Min. = 15 ms –
bus and line jumps from “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
82 ABB
1MRK 511 404-BEN A
M12379-1 v13
Table 65. Autorecloser SMBRREC
Dead time:
shot 1 “t1 1Ph” (0.000-120.000) s ±0.2% or ±35 ms
shot 1 “t1 2Ph” whichever is greater
shot 1 “t1 3Ph “
shot 1 “t1 3PhHS”
Dead time: (0.00-6000.00) s ±0.2% or ±35 ms

shot 2 “t2 3Ph” whichever is greater
shot 3 “t3 3Ph”
shot 4 “t4 3Ph”
shot 5 “t5 3Ph”
Extend three-phase dead time duration “tExtended t1” (0.000-60.000) s ±0.2% or ±35 ms
Minimum time that circuit breaker must be closed before new sequence is allowed (0.00-6000.00) s ±0.2% or ±35 ms
“tCBClosedMin” whichever is greater
Wait time for the slave to close when WAIT input has reset “tSlaveDeadTime” (0.100-60.000) s ±0.2% or ±35 ms
Maximum allowed start pulse duration “tLongStartInh” (0.000-60.000) s ±0.2% or ±15 ms

Circuit breaker closing pulse duration “tPulse” (0.000-60.000) s ±0.2% or ±15 ms

Reclaim time ”tReclaim” (0.00-6000.00) s ±0.2% or ±15 ms

Maximum wait time for release from master “tWaitForMaster” (0.00-6000.00) s ±0.2% or ±15 ms
Reset time for reclosing inhibit “tInhibit” (0.000-60.000) s ±0.2% or ±45 ms

Wait time after close command before proceeding to next shot “tAutoContWait” (0.000-60.000) s ±0.2% or ±45 ms
Maximum wait time for fulfilled synchrocheck conditions “tSync” (0.00-6000.00) s ±0.2% or ±45 ms
Delay time before indicating successful reclosing “tSuccessful” (0.000-60.000) s ±0.2% or ±50 ms
Maximum wait time for circuit breaker closing before indicating unsuccessful “tUnsucCl” (0.00-6000.00) s ±0.2% or ±45 ms
ABB 83
1MRK 511 404-BEN A
SEMOD175215-2 v14
Table 66. Voltage control TR1ATCC/TR8ATCC , TCMYLTC/TCLYLTC
Transformer reactance (0.1–200.0) Ω, primary -
Time delay for lower command when fast step down mode is activated (1.0–100.0) s -
Voltage control set voltage (85.0–120.0)% of UBase ±0.25% of Ur
Outer voltage deadband (0.2–9.0)% of UBase -
Inner voltage deadband (0.1–9.0)% of UBase -
Upper limit of busbar voltage (80–180)% of UBase ±0.5% of Ur
Lower limit of busbar voltage (70–120)% of UBase ±0.5% of Ur
Undervoltage block level (50–120)% of UBase ±0.5% of Ur
Time delay (long) for automatic control commands (3–1000) s ±0.2% or ±600 ms
Time delay (short) for automatic control commands (1–1000) s ±0.2% or ±600 ms
Minimum operating time in inverse mode (3–120) s ±0.2% or ±600 ms

Line resistance (0.00–150.00) Ω, primary -
Line reactance (-150.00–150.00) Ω, primary -
Load voltage adjustment constants (-20.0–20.0)% of UBase -
Load voltage auto correction (-20.0–20.0)% of UBase -
Duration time for the reverse action block signal (30–6000) s ±0.2% or ±600 ms
Current limit for reverse action block (0–100)% of I1Base -
Overcurrent block level (5–250)% of I1Base ±1.0% of Ir at I≤Ir

±1.0% of I at I>Ir
Level for number of counted raise/lower within one hour (0–30) operations/hour -
Level for number of counted raise/lower within 24 hours (0–100) operations/day -
Time window for hunting alarm (1–120) minutes -
Hunting detection alarm, max. operations/window (3–30) operations/window -
Alarm level of active power in forward and reverse direction at (-9999.99–9999.99) MW ±1.0% of Sr
(10-200)% of Sr and (85-120)% of UBase
Alarm level of reactive power in forward and reverse direction at (-9999.99–9999.99) MVAr ±1.0% of Sr
(10-200)% of Sr and (85-120)% of UBase
Time delay for alarms from power supervision (1–6000) s ±0.2% or ±600 ms
Tap position for lowest and highest voltage (1–63) -
mA for lowest and highest voltage tap position (0.000–25.000) mA -
Type of code conversion BIN, BCD, GRAY, SINGLE, mA -
84 ABB
1MRK 511 404-BEN A
Table 66. Voltage control TR1ATCC/TR8ATCC , TCMYLTC/TCLYLTC , continued

Time after position change before the value is accepted (1–60) s ±0.2% or ±200 ms
Tap changer constant time-out (1–120) s ±0.2% or ±200 ms

Raise/lower command output pulse duration (0.5–10.0) s ±0.2% or ±200 ms

ABB 85
1MRK 511 404-BEN A
Scheme communication
M16038-1 v14
Table 67. Scheme communication logic with delta based blocking scheme signal transmit ZCPSCH
Scheme type Off -

Intertrip
Permissive UR
Permissive OR
Blocking
DeltaBlocking
Operate voltage, Delta U (0–100)% of UBase ±5.0% of ΔU
Operate current, Delta I (0–200)% of IBase ±5.0% of ΔI
Operate zero sequence voltage, (0–100)% of UBase ±10.0% of Δ3U0

Delta 3U0
Operate zero sequence current, (0–200)% of IBase ±10.0% of Δ3I0

Delta 3I0
Co-ordination time for blocking (0.000-60.000) s ±0.2% or ±15 ms whichever is greater

communication scheme
Minimum duration of a carrier send (0.000-60.000) s ±0.2% or ±45 ms whichever is greater

signal
Security timer for loss of guard (0.000-60.000) s ±0.2% or ±15 ms whichever is greater
signal detection
Operation mode of unblocking logic Off -

NoRestart
Restart
M16039-1 v16
Table 68. Current reversal and weak-end infeed logic for distance protection ZCRWPSCH
Detection level phase-to-neutral (10-90)% of UBase ±0.5% of Ur

voltage
Detection level phase-to-phase (10-90)% of UBase ±0.5% of Ur

voltage
Operate time for current reversal (0.000-60.000) s ±0.2% or ±15 ms whichever is greater
logic
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
M16049-1 v10
Table 69. Scheme communication logic for residual overcurrent protection ECPSCH
Scheme type Permissive Underreaching -

Permissive Overreaching
Blocking
Communication scheme (0.000-60.000) s ±0.2% or ±20 ms whichever is greater

coordination time
86 ABB
1MRK 511 404-BEN A
GUID-CC9A02C2-AAE8-4B8C-A091-D4ED584A2EA7 v1
Table 70. Local acceleration logic ZCLCPSCH
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 value (0.000–60.000) s ±0.2% or ±35 ms whichever is greater
M16051-2 v11
Table 71. Current reversal and weak-end infeed logic for residual overcurrent protection ECRWPSCH
Operate mode of WEI logic Off -

Echo
Echo & Trip
Operate voltage 3U0 for WEI trip (5-70)% of UBase ±0.5% of Ur
Operate time for current reversal (0.000-60.000) s ±0.2% or ±30 ms whichever is greater
logic
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
ABB 87
1MRK 511 404-BEN A
Logic
M12380-1 v12
Table 72. Tripping logic common 3-phase output SMPPTRC
Trip action 3-ph, 1/3-ph, 1/2/3-ph -
Minimum trip pulse length (0.000-60.000) s ±0.2% or ±15 ms whichever is greater
3-pole trip delay (0.020-0.500) s ±0.2% or ±15 ms whichever is greater
Evolving fault delay (0.000-60.000) s ±0.2% or ±15 ms whichever is greater

GUID-1E1A829D-1F26-433A-8813-1F5A6F225418 v1
Table 73. Number of SMAGAPC instances
Function Quantity with cycle time
3 ms 8 ms 100 ms
SMAGAPC 12 - -
Table 74. Number of STARTCOMB instances
3 ms 8 ms 100 ms
STARTCOMB 32 - -
GUID-3AB1EE95-51BF-4CC4-99BD-F4ECDAACB75A v1
Table 75. Number of TMAGAPC instances
3 ms 8 ms 100 ms
TMAGAPC 6 6 -
GUID-A05AF26F-DC98-4E62-B96B-E75D19F20767 v1
Table 76. Number of ALMCALH instances
3 ms 8 ms 100 ms
ALMCALH - - 5
GUID-70B7357D-F467-4CF5-9F73-641A82D334F5 v1
Table 77. Number of WRNCALH instances
3 ms 8 ms 100 ms
WRNCALH - - 5
GUID-EAA43288-01A5-49CF-BF5B-9ABF6DC27D85 v1
Table 78. Number of INDCALH instances
3 ms 8 ms 100 ms
INDCALH - 5 -
88 ABB
1MRK 511 404-BEN A
GUID-D1179280-1D99-4A66-91AC-B7343DBA9F23 v2
Table 79. Number of AND instances
Logic block Quantity with cycle time
3 ms 8 ms 100 ms
AND 60 60 160
GUID-45DF373F-DC39-4E1B-B45B-6B454E8E0E50 v2
Table 80. Number of GATE instances
3 ms 8 ms 100 ms
GATE 10 10 20
GUID-0EC4192A-EF03-47C0-AEC1-09B68B411A98 v2
Table 81. Number of INV instances
3 ms 8 ms 100 ms
INV 90 90 240
GUID-B2E6F510-8766-4381-9618-CE02ED71FFB6 v1
Table 82. Number of LLD instances
3 ms 8 ms 100 ms
LLD 10 10 20
GUID-35A795D7-A6BD-4669-A023-43C497DBFB01 v3
Table 83. Number of OR instances
3 ms 8 ms 100 ms
OR 78 60 160
GUID-E05E5FB1-23E7-4816-84F2-1FBFFDFF2B43 v1
Table 84. Number of PULSETIMER instances
Logic block Quantity with 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 v1
Table 85. Number of RSMEMORY instances
3 ms 8 ms 100 ms
RSMEMORY 10 10 20
GUID-7A0F4327-CA83-4FB0-AB28-7C5F17AE6354 v1
Table 86. Number of SRMEMORY instances
3 ms 8 ms 100 ms
SRMEMORY 10 10 20
ABB 89
1MRK 511 404-BEN A
GUID-C6C98FE0-F559-45EE-B853-464516775417 v2
Table 87. Number of TIMERSET instances
3 ms 8 ms 100 ms
TIMERSET 15 15 30 (0.000–90000.000) s ±0.5% ±10 ms

GUID-0B07F78C-10BD-4070-AFF0-6EE36454AA03 v1
Table 88. Number of XOR instances
3 ms 8 ms 100 ms
XOR 10 10 20
GUID-23D4121A-4C9A-4072-BBE3-6DB076EDAB79 v1
Table 89. Number of ANDQT instances
3 ms 8 ms 100 ms
ANDQT - 20 100
GUID-27DF23C0-A0B2-4BB0-80B5-FC7B7F7FE448 v1
Table 90. Number of INDCOMBSPQT instances
3 ms 8 ms 100 ms
INDCOMBSPQT - 10 10
GUID-C1E61AE5-22CF-4198-97CF-8C8043EE96D2 v1
Table 91. Number of INDEXTSPQT instances
3 ms 8 ms 100 ms
INDEXTSPQT - 10 10
GUID-77FEBE9B-0882-4E85-8B1A-7671807BFC02 v2
Table 92. Number of INVALIDQT instances
3 ms 8 ms 100 ms
INVALIDQT 10 6 6
GUID-F25B94C6-9CC9-48A0-A7A3-47627D2B56E2 v1
Table 93. Number of INVERTERQT instances
3 ms 8 ms 100 ms
INVERTERQT - 20 100
GUID-88B27B3C-26D2-47AF-9878-CC19018171B1 v1
Table 94. Number of ORQT instances
3 ms 8 ms 100 ms
ORQT - 20 100
90 ABB
1MRK 511 404-BEN A
GUID-61263951-53A8-4113-82B5-3DB3BF0D9449 v1
Table 95. Number of PULSETIMERQT instances
3 ms 8 ms 100 ms
PULSETIMERQT - 10 30 (0.000–90000.000) s ±0.5% ±10 ms

GUID-94C803B4-6C5A-4072-AB5C-20DDE98C9A70 v1
Table 96. Number of RSMEMORYQT instances
3 ms 8 ms 100 ms
RSMEMORYQT - 10 30
GUID-341562FB-6149-495B-8A63-200DF16A5590 v1
Table 97. Number of SRMEMORYQT instances
3 ms 8 ms 100 ms
SRMEMORYQT - 10 30
GUID-B6231B97-05ED-40E8-B735-1E1A50FDB85F v1
Table 98. Number of TIMERSETQT instances
3 ms 8 ms 100 ms
TIMERSETQT - 10 30 (0.000–90000.000) s ±0.5% ±10 ms

GUID-1C381E02-6B9E-44DC-828F-8B3EA7EDAA54 v1
Table 99. Number of XORQT instances
3 ms 8 ms 100 ms
XORQT - 10 30
ABB 91
1MRK 511 404-BEN A
GUID-19810098-1820-4765-8F0B-7D585FFC0C78 v7
Table 100. Number of instances in the extension logic package
3 ms 8 ms 100 ms
SLGAPC 10 10 54
VSGAPC 10 10 100
AND 40 40 100
OR 40 40 100
PULSETIMER 20 20 49
GATE — — 49
TIMERSET 30 30 49
XOR 10 10 69
LLD — — 49
SRMEMORY 10 10 110
INV 40 40 100
RSMEMORY 10 10 20
GUID-65A2876A-F779-41C4-ACD7-7662D1E7F1F2 v2
Table 101. Number of B16I instances
3 ms 8 ms 100 ms
B16I 6 4 8
GUID-3820F464-D296-4CAD-8491-F3F997359D79 v1
Table 102. Number of BTIGAPC instances
3 ms 8 ms 100 ms
BTIGAPC 4 4 8
GUID-B45901F4-B163-4696-8220-7F8CAC84D793 v1
Table 103. Number of IB16 instances
3 ms 8 ms 100 ms
IB16 6 4 8
GUID-A339BBA3-8FD0-429D-BB49-809EAC4D53B0 v1
Table 104. Number of ITBGAPC instances
3 ms 8 ms 100 ms
ITBGAPC 4 4 8
92 ABB
1MRK 511 404-BEN A
GUID-B258726E-1129-47C9-94F9-BE634A2085FA v3
Table 105. Elapsed time integrator with limit transgression and overflow supervision TEIGAPC
Function Cycle time (ms) Range or value Accuracy
Elapsed time integration 3 0 ~ 999999.9 s ±0.2% or ±20 ms whichever is

greater
8 0 ~ 999999.9 s ±0.2% or ±100 ms whichever is

greater
100 0 ~ 999999.9 s ±0.2% or ±250 ms whichever is

greater
Table 106. Number of TEIGAPC instances
3 ms 8 ms 100 ms
TEIGAPC 4 4 4
GUID-CEA332FF-838D-42B7-AEFC-C1E87809825E v2
Table 107. Number of INTCOMP instances
3 ms 8 ms 100 ms
INTCOMP 10 10 10
GUID-3FDD7677-1D86-42AD-A545-B66081C49B47 v3
Table 108. Number of REALCOMP instances
3 ms 8 ms 100 ms
REALCOMP 10 10 10
ABB 93
1MRK 511 404-BEN A
Monitoring
M12386-1 v15
Table 109. Power system measurement CVMMXN
Frequency (0.95-1.05) x fr ±2.0 mHz
Voltage (10 to 300) V ±0.3% of U at U≤ 50 V

±0.2% of U at U> 50 V
Current (0.1-4.0) x Ir ±0.8% of I at 0.1 x Ir< I < 0.2 x Ir

± 0.5% of I at 0.2 x Ir< I < 0.5 x Ir
±0.2% of I at 0.5 x Ir< I < 4.0 x Ir
Active power, P (10 to 300) V ±0.5% of Sr at S ≤0.5 x Sr

(0.1-4.0) x Ir ±0.5% of S at S > 0.5 x Sr
(100 to 220) V ±0.2% of P

(0.5-2.0) x Ir
cos φ< 0.7
Reactive power, Q (10 to 300) V ±0.5% of Sr at S ≤0.5 x Sr

(0.1-4.0) x Ir ±0.5% of S at S > 0.5 x Sr
(100 to 220) V ±0.2% of Q

(0.5-2.0) x Ir
cos φ> 0.7
Apparent power, S (10 to 300) V ±0.5% of Sr at S ≤0.5 x Sr

(0.1-4.0) x Ir ±0.5% of S at S >0.5 x Sr
(100 to 220) V ±0.2% of S

(0.5-2.0) x Ir
Power factor, cos (φ) (10 to 300) V <0.02

(0.1-4.0) x Ir
(100 to 220) V <0.01

(0.5-2.0) x Ir
GUID-5E04B3F9-E1B7-4974-9C0B-DE9CD4A2408F v6
Table 110. Current measurement CMMXU
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 symmetrical load (0.1-4.0) × Ir ±1.0 degrees at 0.1 × Ir < I ≤ 0.5 × Ir
±0.5 degrees at 0.5 × Ir < I ≤ 4.0 × Ir
GUID-374C2AF0-D647-4159-8D3A-71190FE3CFE0 v5
Table 111. Voltage measurement phase-phase VMMXU
Voltage (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 degrees at U ≤ 50 V

±0.2 degrees at U > 50 V
94 ABB
1MRK 511 404-BEN A
GUID-ED634B6D-9918-464F-B6A4-51B78129B819 v6
Table 112. Voltage measurement phase-earth VNMMXU
Voltage (5 to 175) V ±0.5% of U at U ≤ 50 V

±0.2% of U at U > 50 V

GUID-9B8A7FA5-9C98-4CBD-A162-7112869CF030 v5
Table 113. Current sequence measurement CMSQI
Current positive sequence, I1 (0.1–4.0) × Ir ±0.3% of Ir at I ≤ 0.5 × Ir

Three phase settings ±0.3% of I at I > 0.5 × Ir
Current zero sequence, 3I0 (0.1–1.0) × Ir ±0.3% of Ir at I ≤ 0.5 × Ir

Current negative sequence, I2 (0.1–1.0) × Ir ±0.3% of Ir at I ≤ 0.5 × Ir

Phase angle (0.1–4.0) × Ir ±1.0 degrees at 0.1 × Ir < I ≤ 0.5 × Ir

±0.5 degrees at 0.5 × Ir < I ≤ 4.0 × Ir
GUID-47094054-A828-459B-BE6A-D7FA1B317DA7 v6
Table 114. Voltage sequence measurement VMSQI
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

M16080-1 v5
Table 115. Supervision of mA input signals
mA measuring function ±5, ±10, ±20 mA ±0.1 % of set value ±0.005 mA

0-5, 0-10, 0-20, 4-20 mA
Max current of transducer to (-20.00 to +20.00) mA

input
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
ABB 95
1MRK 511 404-BEN A
M12760-1 v10
Table 116. Disturbance report DRPRDRE
Pre-fault time (0.05–9.90) s -
Post-fault time (0.1–10.0) s -
Limit time (0.5–10.0) s -
Maximum number of recordings 100, first in - first out -
Time tagging resolution 1 ms See table 150
Maximum number of analog inputs 30 + 10 (external + internally -

derived)
Maximum number of binary inputs 352 -
Maximum number of phasors in the Trip Value recorder per recording 30 -
Maximum number of indications in a disturbance report 352 -
Maximum number of events in the Event recording per recording 150 -
Maximum number of events in the Event list 1000, first in - first out -
Maximum total recording time (3.4 s recording time and maximum number of 340 seconds (100 recordings) at -
channels, typical value) 50 Hz, 280 seconds (80
recordings) at 60 Hz
Sampling rate 1 kHz at 50 Hz -

1.2 kHz at 60 Hz
Recording bandwidth (5-300) Hz -

GUID-F034B396-6600-49EF-B0A5-8ED96766A6A0 v7
Table 117. Insulation supervision for gas medium function SSIMG
Pressure alarm level 1.00-100.00 ±10.0% of set value
Pressure lockout level 1.00-100.00 ±10.0% of set value
Temperature alarm level -40.00-200.00 ±2.5% of set value
Temperature lockout level -40.00-200.00 ±2.5% of set value
Time delay for pressure alarm (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Reset time delay for pressure alarm (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Time delay for pressure lockout (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Time delay for temperature alarm (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Reset time delay for temperature alarm (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Time delay for temperature lockout (0.000-60.000) s ±0.2% or ±250ms whichever is greater
96 ABB
1MRK 511 404-BEN A
GUID-83B0F607-D898-403A-94FD-7FE8D45C73FF v7
Table 118. Insulation supervision for liquid medium function SSIML
Oil alarm level 1.00-100.00 ±10.0% of set value
Oil lockout level 1.00-100.00 ±10.0% of set value
Temperature alarm level -40.00-200.00 ±2.5% of set value
Temperature lockout level -40.00-200.00 ±2.5% of set value
Time delay for oil alarm (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Reset time delay for oil alarm (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Time delay for oil lockout (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Time delay for temperature alarm (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Reset time delay for temperature alarm (0.000-60.000) s ±0.2% or ±250ms whichever is greater
Time delay for temperature lockout (0.000-60.000) s ±0.2% or ±250ms whichever is greater
GUID-B6799420-D726-460E-B02F-C7D4F1937432 v8
Table 119. Circuit breaker condition monitoring SSCBR
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 (0.00 – 60.00) s ±0.2% or ±30 ms whichever is greater
time alarm
Independent time delay for gas pressure alarm (0.00 – 60.00) s ±0.2% or ±30 ms whichever is greater
Independent time delay for gas pressure (0.00 – 60.00) s ±0.2% or ±30 ms whichever is greater
lockout
CB Contact Travel Time, opening and closing ±3 ms
Remaining Life of CB ±2 operations
Accumulated Energy ±1.0% or ±0.5 whichever is greater

M14987-1 v6
Table 120. Fault locator LMBRFLO
Function Value 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 -
Maximum number of fault 100 -

locations
ABB 97
1MRK 511 404-BEN A
GUID-F6B6ED6B-2488-483C-B068-3F4631F34DC8 v1
Table 121. Transformer loss of life LOLSPTR
Service value, hot spot – ±2.0% of expected value

temperature
Service value, top oil – ±2.0% of expected value

temperature
Service value, loss of life – ±2.0% of expected value
Operate level , Warning level 1 (50 - 700)°C/°F of hot spot temperature ±2.0% of hot spot temperature
and 2
Operate time, Warning level 1 (50 - 700)°C/°F of hot spot temperature ±200 ms typically
and 2
Operate time, definite time (0.0 - 6000.0) s ±250 ms typically

function (ALARMx)
M12700-1 v4
Table 122. Event list
Function Value
Buffer capacity Maximum number of events in the list 1000
Resolution 1 ms
Accuracy Depending on time synchronizing

M13765-1 v5
Table 123. Indications
Function Value
Buffer capacity Maximum number of indications presented for single disturbance 352
Maximum number of recorded disturbances 100

M12702-1 v4
Table 124. Event recorder
Function Value
Buffer capacity Maximum number of events in disturbance report 150
Maximum number of disturbance reports 100
Resolution 1 ms
Accuracy Depending on time

synchronizing
M13747-1 v5
Table 125. Trip value recorder
Function Value
Buffer capacity Maximum number of analog inputs 30
98 ABB
1MRK 511 404-BEN A
M12384-1 v7
Table 126. Disturbance recorder
Function Value
Buffer capacity Maximum number of analog inputs 40
Maximum number of binary inputs 352
Maximum total recording time (3.4 s recording time and maximum number 340 seconds (100 recordings) at 50 Hz
of channels, typical value) 280 seconds (80 recordings) at 60 Hz
GUID-C43B8654-60FE-4E20-8328-754C238F4AD0 v3
Table 127. Event counter with limit supervision L4UFCNT
Counter value 0-65535 -
Max. count up speed 30 pulses/s (50% duty cycle) -

GUID-F5E124E3-0B85-41AC-9830-A2362FD289F2 v1
Table 128. Running hour-meter TEILGAPC
Time limit for alarm supervision, tAlarm (0 - 99999.9) hours ±0.1% of set value
Time limit for warning supervision, tWarning (0 - 99999.9) hours ±0.1% of set value
Time limit for overflow supervision Fixed to 99999.9 hours ±0.1%
ABB 99
1MRK 511 404-BEN A
Metering
M13404-2 v5
Table 129. Pulse-counter logic PCFCNT
Function Setting range Accuracy
Input frequency See Binary Input Module (BIM) -
Cycle time for report of counter (1–3600) s -

value
SEMOD153707-2 v5
Table 130. Function for energy calculation and demand handling ETPMMTR
Energy metering kWh Export/Import, kvarh Export/ Input from MMXU. No extra error at steady load
Import
100 ABB
1MRK 511 404-BEN A
Station communication
M15031-1 v8
Table 131. Communication protocols
Function Value
Protocol IEC 61850-8-1
Communication speed for the IEDs 100BASE-FX
Protocol IEC 60870–5–103
Communication speed for the IEDs 9600 or 19200 Bd
Protocol DNP3.0
Communication speed for the IEDs 300–115200 Bd
Protocol TCP/IP, Ethernet
Communication speed for the IEDs 100 Mbit/s
Protocol LON
Communication speed for the IEDs 1.25 Mbit/s
Protocol SPA
Communication speed for the IEDs 300–38400 Bd

GUID-E8B5405C-241C-4DC2-8AB1-3FA77343A4DE v2
Table 132. IEC 61850-9-2 communication protocol
Function Value
Communication speed for the IEDs 100BASE-FX

M11927-1 v2
Table 133. LON communication protocol
Function Value
Protocol LON
Communication speed 1.25 Mbit/s

M11901-1 v2
Table 134. SPA communication protocol
Function Value
Protocol SPA
Communication speed 300, 1200, 2400, 4800, 9600, 19200 or 38400 Bd
Slave number 1 to 899

M11921-1 v4
Table 135. IEC 60870-5-103 communication protocol
Function Value
Communication speed 9600, 19200 Bd
ABB 101
1MRK 511 404-BEN A
M12589-1 v4
Table 136. SLM – LON port
Quantity Range or value
Optical connector Glass fiber: type ST

Plastic fiber: type HFBR snap-in
Fiber, optical budget Glass fiber: 11 dB (1000m/3000 ft typically *)

Plastic fiber: 7 dB (10m/35ft typically *)
Fiber diameter Glass fiber: 62.5/125 mm

Plastic fiber: 1 mm
*) depending on optical budget calculation

SEMOD117441-2 v5
Table 137. SLM – SPA/IEC 60870-5-103/DNP3 port
Optical connector Glass fiber: type ST

Plastic fiber: type HFBR snap-in
Fiber, optical budget Glass fiber: 11 dB (1000m/3000ft m typically *)

Plastic fiber: 7 dB (25m/80ft m typically *)
Fiber diameter Glass fiber: 62.5/125 mm

Plastic fiber: 1 mm

SEMOD158710-2 v2
Table 138. Galvanic RS485 communication module
Communication speed 2400–19200 bauds
External connectors RS-485 6-pole connector

Soft ground 2-pole connector
GUID-8651FF22-C007-4D53-B7E3-686A30F37CB6 v5
Table 139. Ethernet redundancy protocols, IEC 62439-3
Function Value
Protocol IEC 62439-3 Ed.1 Parallel Redundancy Protocol (PRP-0)
Communication speed 100Base-FX
Protocol IEC 62439-3 Ed.2 Parallel Redundancy Protocol (PRP-1)
Protocol IEC 62439-3 Ed.2 High-availability Seamless Redundancy (HSR)
Connectors Optical, type LC
102 ABB
1MRK 511 404-BEN A
M12756-1 v10
Remote communication
Table 140. Line data communication module
Characteristic Range or value
Type of LDCM Short range (SR) Medium range (MR) Long range (LR)
Type of fiber Graded-index Singlemode 9/125 Singlemode 9/125

multimode 62.5/125 µm µm
µm
Graded-index
multimode 50/125
µm
Peak Emission Wave length

Nominal 820 nm 1310 nm 1550 nm
Maximum 865 nm 1330 nm 1580 nm
Minimum 792 nm 1290 nm 1520 nm
Optical budget 13 dB (typical 22 dB (typical 26 dB (typical

Graded-index multimode 62.5/125 mm distance about 3 distance 80 km/50 distance 110 km/68
km/2 mile *) mile *) mile *)
Graded-index multimode 50/125 mm 9 dB (typical distance

about 2 km/1 mile *)
Optical connector Type ST Type FC/PC Type FC/PC
Protocol C37.94 C37.94 C37.94

implementation **) implementation **)
Data transmission Synchronous Synchronous Synchronous
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 Internal or derived Internal or derived

from received signal from received signal from received signal

**) C37.94 originally defined just for multimode; using same header, configuration and data format as C37.94
ABB 103
1MRK 511 404-BEN A
Hardware
IED
M11778-1 v6 SEMOD53385-1 v1
Table 141. Case
Material Steel sheet
Front plate Stainless steel with cut-out for HMI
Surface treatment Aluzink preplated steel
Finish Light grey (RAL 7035)

M12327-1 v4
Table 142. Water and dust protection level according to IEC 60529
Front IP40 (IP54 with sealing strip)
Sides, top and bottom IP40
Rear side IP20 with screw compression type

IP10 with ring lug terminals
M11777-1 v5
Table 143. Weight
Case size Weight
6U, 1/2 x 19” £ 10 kg/22 lb
6U, 3/4 x 19” £ 15 kg/33 lb
6U, 1/1 x 19” £ 18 kg/40 lb
Electrical safety
GUID-1CF5B10A-CF8B-407D-8D87-F4B48B43C2B2 v1 GUID-2825B541-DD31-4DAF-B5B3-97555F81A1C2 v1
Table 144. Electrical safety according to IEC 60255-27
Equipment 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
SEMOD53376-2 v6 SEMOD53371-1 v1
Table 145. CT and VT circuit connectors
Connector type Rated voltage and current Maximum conductor area
Screw compression type 250 V AC, 20 A 4 mm2 (AWG12)

2 x 2.5 mm2 (2 x AWG14)
Terminal blocks suitable for ring lug terminals 250 V AC, 20 A 4 mm2 (AWG12)
M12583-1 v6
Table 146. Auxiliary power supply and binary I/O connectors
Connector type Rated voltage Maximum conductor area
Screw compression type 250 V AC 2.5 mm2 (AWG14)

2 × 1 mm2 (2 x AWG18)
Terminal blocks suitable for ring lug terminals 300 V AC 3 mm2 (AWG14)
Because of limitations of space, when ring

lug terminal is ordered for Binary I/O
104 ABB
1MRK 511 404-BEN A
GUID-96676D5D-0835-44DA-BC22-058FD18BDF34 v2
connections, one blank slot is necessary
between two adjacent IO modules. Please
refer to the ordering particulars for details.
Table 147. 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 v2
Table 148. OEM: Number of Ethernet ports
OEM 2 Ethernet Ports
Ethernet connection type SFP Optical LC or Galvanic RJ45
ABB 105
1MRK 511 404-BEN A
Basic IED functions

M11963-1 v5
Table 149. Self supervision with internal event list
Data Value
Recording manner Continuous, event controlled
List size 40 events, first in-first out

M12331-1 v8
Table 150. Time synchronization, time tagging
Function Value
Time tagging accuracy of the synchrophasor data ± 1 µs
Time tagging resolution, events and sampled measurement values 1 ms
Time tagging error with synchronization once/min (minute pulse synchronization), events and sampled ± 1.0 ms typically
measurement values
Time tagging error with SNTP synchronization, sampled measurement values ± 1.0 ms typically
GUID-8AEB81D0-1731-46DF-A206-D2E758823575 v1
Table 151. Time synchronization PTP: IEC/IEEE 61850-9-3
Supported types of clock Boundary Clock (BC), Ordinary Clock (OC), Transparent 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 152. GPS time synchronization module (GTM)
Receiver – ±1µs relative UTC
Time to reliable time reference with antenna in new <30 minutes –

position or after power loss longer than 1 month
Time to reliable time reference after a power loss <15 minutes –

longer than 48 hours
Time to reliable time reference after a power loss <5 minutes –

shorter than 48 hours
SEMOD55693-2 v5
Table 153. GPS – Antenna and cable
Function Value
Max antenna cable attenuation 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
106 ABB
1MRK 511 404-BEN A
SEMOD141136-2 v8
Table 154. IRIG-B
Number of channels IRIG-B 1
Number of optical channels 1
Electrical connector:
Electrical connector IRIG-B BNC
Pulse-width modulated 5 Vpp
Amplitude modulated
– low level 1-3 Vpp
– high level 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 fibre 62.5/125 μm multimode fibre
Supported formats IRIG-B 00x
Accuracy +/- 1μs
ABB 107
1MRK 511 404-BEN A
Inverse characteristic
M12388-1 v21
Table 155. ANSI Inverse time characteristics
Operating characteristic: 0.10 ≤ k ≤ 3.00 ANSI/IEEE C37.112 ,

1.5 x Iset ≤ I ≤ 20 x Iset ±2.0% or ±40 ms
æ
A
ö whichever is greater
t=ç + B ÷ × k + tDef
è
P
(
çç I - 1 ÷÷
ø)
EQUATION1249-SMALL V2 EN-US
Reset characteristic:
tr
t = ×k
(I 2
-1 )
I = Imeasured/Iset
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
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
108 ABB
1MRK 511 404-BEN A
Table 156. IEC Inverse time characteristics
Operating characteristic: 0.10 ≤ k ≤ 3.00 IEC 60255-151, ±2.0%

1.5 x Iset ≤ I ≤ 20 x Iset or ±40 ms whichever is
æ A ö greater
t = ç P ÷×k
ç ( I - 1) ÷
è ø
I = Imeasured/Iset
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
Programmable characteristic k = (0.05-999) in steps of 0.01

Operate characteristic: A=(0.005-200.000) in steps of 0.001
B=(0.00-20.00) in steps of 0.01
æ A ö C=(0.1-10.0) in steps of 0.1
t = ç P + B÷ × k P=(0.005-3.000) in steps of 0.001
ç (I - C ) ÷
è ø TR=(0.005-100.000) in steps of 0.001
EQUATION1370-SMALL V1 EN-US CR=(0.1-10.0) in steps of 0.1
Reset characteristic: PR=(0.005-3.000) in steps of 0.001
TR
t = ×k
(I PR
- CR )
I = Imeasured/Iset
Table 157. RI and RD type inverse time characteristics
RI type inverse characteristic 0.10 ≤ k ≤ 3.00 IEC 60255-151, ±2.0%

1 greater
t = ×k
0.236
0.339 -
I
I = Imeasured/Iset
RD type logarithmic inverse characteristic
æ I ö
t = 5.8 - ç 1.35 × In ÷
è k ø
I = Imeasured/Iset
ABB 109
1MRK 511 404-BEN A
GUID-19F8E187-4ED0-48C3-92F6-0D9EAA2B39BB v3
Table 158. ANSI Inverse time characteristics for Sensitive directional residual overcurrent and power protection

1.5 x Iset ≤ I ≤ 20 x Iset ±5.0% or ±160 ms
æ
A
è (
çç I P - 1
)
÷÷
ø
tr
t = ×k
(I 2
-1 )
I = Imeasured/Iset
110 ABB
1MRK 511 404-BEN A
Table 159. IEC Inverse time characteristics for Sensitive directional residual overcurrent and power protection

æ A ö greater
t = ç P ÷×k
ç ( I - 1) ÷
è ø
I = Imeasured/Iset
Programmable characteristic k = (0.05-999) in steps of 0.01

Operate characteristic: A=(0.005-200.000) in steps of 0.001
B=(0.00-20.00) in steps of 0.01
æ A ö C=(0.1-10.0) in steps of 0.1
t = ç P + B÷ × k P=(0.005-3.000) in steps of 0.001
ç (I - C ) ÷
è ø TR=(0.005-100.000) in steps of 0.001
EQUATION1370-SMALL V1 EN-US CR=(0.1-10.0) in steps of 0.1
Reset characteristic: PR=(0.005-3.000) in steps of 0.001
TR
t = ×k
(I PR
- CR )
I = Imeasured/Iset
Table 160. RI and RD type inverse time characteristics for Sensitive directional residual overcurrent and power protection
RI type inverse characteristic 0.10 ≤ k ≤ 2.00 IEC 60255-151, ±5.0%

1 greater
t = ×k
0.236
0.339 -
I
I = Imeasured/Iset
RD type logarithmic inverse characteristic
æ I ö
t = 5.8 - ç 1.35 × In ÷
è k ø
I = Imeasured/Iset
ABB 111
1MRK 511 404-BEN A
GUID-2AE8C92E-5DA8-487F-927D-8E553EE29240 v1
Table 161. ANSI Inverse time characteristics for Voltage restrained time overcurrent protection

± 5.0% or ±40 ms
æ
A
è (
çç I P - 1
)
÷÷
ø
tr
t = ×k
(I 2
-1 )
I = Imeasured/Iset
Table 162. IEC Inverse time characteristics for Voltage restrained time overcurrent protection

or ±40 ms whichever is
æ A ö greater
t = ç P ÷×k
ç ( I - 1) ÷
è ø
I = Imeasured/Iset
112 ABB
1MRK 511 404-BEN A
SEMOD116978-2 v10
Table 163. Inverse time characteristics for overvoltage protection
Type A curve: k = (0.05-1.10) in steps of 0.01 ±5.0% or ±45 ms

k
t =
æU -U >ö
ç ÷
è U> ø
U> = Uset
U = Umeasured
Type B curve: k = (0.05-1.10) in steps of 0.01
k  480
t 2.0
 0.035
 U  Un  
 32   0.5 
 Un  
IECEQUATION2423 V2 EN-US
Type C curve: k = (0.05-1.10) in steps of 0.01
k × 480
t= 3.0
+ 0.035
æ U - Un > ö
ç 32 × - 0.5 ÷
è U> ø
IECEQUATION2421 V1 EN-US
Programmable curve: k = (0.05-1.10) in steps of 0.01

A = (0.005-200.000) in steps of 0.001
k×A B = (0.50-100.00) in steps of 0.01
t = +D C = (0.0-1.0) in steps of 0.1
P
æB × U -U > ö D = (0.000-60.000) in steps of 0.001
ç -C÷
è U > ø P = (0.000-3.000) in steps of 0.001
ABB 113
1MRK 511 404-BEN A
Table 164. Inverse time characteristics for undervoltage protection
Type A curve: k = (0.05-1.10) in steps of 0.01 ±5.0% or ±45 ms

k
t =
æ U < -U
ö
ç ÷
è U< ø
U< = Uset
U = Umeasured
Type B curve: k = (0.05-1.10) in steps of 0.01
k × 480
t = + 0.055
2.0
æ 32 × U < -U - 0.5 ö
ç ÷
è U < ø
U< = Uset
U = Umeasured
Programmable curve: k = (0.05-1.10) in steps of 0.01

A = (0.005-200.000) in steps of 0.001
é ù B = (0.50-100.00) in steps of 0.01
ê k×A
ú C = (0.0-1.0) in steps of 0.1
t =ê ú+D D = (0.000-60.000) in steps of 0.001
ê æ U < -U ö
P
ú P = (0.000-3.000) in steps of 0.001
êçB × -C÷ ú
ëè U < ø û
U< = Uset
U = Umeasured
114 ABB
1MRK 511 404-BEN A
Table 165. Inverse time characteristics for residual overvoltage protection
Type A curve: k = (0.05-1.10) in steps of ±5.0% or ±45 ms whichever is greater

0.01
k
t =
æU -U >ö
ç ÷
è U> ø
U> = Uset
U = Umeasured
Type B curve: k = (0.05-1.10) in steps of

0.01
k ⋅ 480
t = + 0.035
2.0
 32 ⋅ U − U > − 0.5 
 
 U > 
Type C curve: k = (0.05-1.10) in steps of

0.01
k ⋅ 480
t = + 0.035
3.0
 32 ⋅ U − U > − 0.5 
 
 U > 
Programmable curve: k = (0.05-1.10) in steps of

0.01
k×A A = (0.005-200.000) in
t = +D steps of 0.001
P
æB × U - U > ö B = (0.50-100.00) in steps
ç -C÷
è U > ø 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
ABB 115
1MRK 511 404-BEN A
24. Ordering for customized IED

GUID-43BAC6E7-5454-464E-A4B0-97D2A602785D v7
Table 166. General guidelines
Guidelines
Carefully read and follow the set of rules to ensure problem-free order management.
Please refer to the available functions table for included application functions.
PCM600 can be used to make changes and/or additions to the delivered factory configuration of the pre-configured.
Table 167. Example ordering code
To obtain the complete ordering code, please combine code from the selection tables, as given in the example below.
The selected qty of each table must be filled in, if no selection is possible the code is 0.
Example of a complete code: REC670*2.2-F00X00 - A000006000000000 - B00000000000000000000000000 - C6600666666660036221300300 - D22206020 -
E6662 - F9 - S6 - G642 - H26461114444 - K10101110 - L1100 - M614 - P11100000000000100 - B1X0 - AC - CA - B - A3X0 - CD1D1ARGN1N1XXXXXXX -
KKKXXHKKLAGXSY
Product definition - Differential protection -

REC670* 2.2 - F00 X00 - A 0 0 0 0 0 0 0 0 0 0 0 0 0 0 -
Impedance protection -
B 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 -
Current protection -
C 00 00 0 0 0 0 -
Voltage protection - Frequency protection - Multipurpose protection - General -

calculation
D 0 0 0 - E - F - S -
Secondary system supervision - Control -

G - H -
Scheme communication - Logic - Monitoring - Station communication -

K 0 0 0 - L 00 - M - P 0 0 0 0 0 0 0 0 0 0 0 0 0 -
Language - Casing - Power - HMI - Analog input - Binary input/output -

and supply
mounting
B1 - - - - - -
Station communication, remote end serial communication and time synchronization

K
Table 168. Product definition
REC670* 2.2 F00
Table 169. Product definition ordering codes
Product REC670*
Software version 2.2
Configuration alternative
Bay control REC670 F00
ACT configuration
No ACT configuration downloaded X00
Table 170. Differential protection
Position 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
A 0 0 0 0 0 0 0 0 0 0 0 0 0 0
116 ABB
1MRK 511 404-BEN A
Table 171. Differential functions
Function Function Ordering no Position Available Selected Notes and rules

identification qty qty
High impedance differential protection, single phase HZPDIF 1MRK005904-HB 6 0-6
Table 172. Impedance protection
Position 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26
B 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
Table 173. Current protection
Position 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23
C 00 00 0 0 0 0
Table 174. Current functions

Instantaneous phase overcurrent protection PHPIOC 1MRK005910-AD 1 0-6
Directional phase overcurrent protection, four steps OC4PTOC 1MRK005910-BC 2 0-6
Instantaneous residual overcurrent protection EFPIOC 1MRK005910-DD 4 0-6
Directional residual overcurrent protection, four steps EF4PTOC 1MRK005910-EE 5 0-6
Four step directional negative phase sequence overcurrent NS4PTOC 1MRK005910-FB 6 0-6
protection
Sensitive directional residual overcurrent and power protection SDEPSDE 1MRK005910-GA 7 0-6
Thermal overload protection, one time constant, Celsius LCPTTR 1MRK005911-BA 8 0-6
Thermal overload protection, one time constant, Fahrenheit LFPTTR 1MRK005911-AA 9 0-6
Thermal overload protection, two time constants TRPTTR 1MRK005910-HC 10 0-6
Breaker failure protection CCRBRF 1MRK005910-LA 11 0-6
Stub protection STBPTOC 1MRK005910-NC 13 0-6
Pole discordance protection CCPDSC 1MRK005910-PA 14 0-6
Directional underpower protection GUPPDUP 1MRK005910-RA 15 0-2
Directional overpower protection GOPPDOP 1MRK005910-TA 16 0-2
Broken conductor check BRCPTOC 1MRK005910-SA 17 0-1
Capacitor bank protection CBPGAPC 1MRK005910-UB 18 0-3
Voltage restrained overcurrent protection VRPVOC 1MRK005910-XA 21 0-3
Table 175. Voltage protection
Position 1 2 3 4 5 6 7 8
D 0 0 0
Table 176. Voltage functions

Two step undervoltage protection UV2PTUV 1MRK005912-AA 1 0-2
Two step overvoltage protection OV2PTOV 1MRK005912-BA 2 0-2
Two step residual overvoltage protection ROV2PTOV 1MRK005912-CC 3 0-2
Voltage differential protection VDCPTOV 1MRK005912-EA 5 0-6
Loss of voltage check LOVPTUV 1MRK005912-GA 7 0-2
Table 177. Frequency protection
Position 1 2 3 4
E
ABB 117
1MRK 511 404-BEN A
Table 178. Frequency functions

Underfrequency protection SAPTUF 1MRK005914-AC 1 0-6
Overfrequency protection SAPTOF 1MRK005914-BB 2 0-6
Rate-of-change of frequency protection SAPFRC 1MRK005914-CB 3 0-6
Frequency time accumulation protection FTAQFVR 1MRK005914-DB 4 00-12
Table 179. Multipurpose protection
Position 1
F
Table 180. Multipurpose functions

General current and voltage protection CVGAPC 1MRK005915-AA 1 0-9
Table 181. General calculation
Position 1
S
Table 182. General calculation functions

Multipurpose filter SMAIHPAC 1MRK005915-KB 1 0-6
Table 183. Secondary system supervision
Position 1 2 3
G
Table 184. Secondary system supervision functions

Current circuit supervision CCSSPVC 1MRK005916-AC 1 0-6
Fuse failure supervision FUFSPVC 1MRK005916-BA 2 0-4
Fuse failure supervision based on voltage difference VDSPVC 1MRK005916-CA 3 0-2
Table 185. Control
Position 1 2 3 4 5 6 7 8 9 10 11
H
118 ABB
1MRK 511 404-BEN A
Table 186. Control functions

identification qty Qty
Synchrocheck, energizing check and synchronizing SESRSYN 1MRK005917-AC 1 0-2 Can only be ordered
with Apparatus
control APC10/
APC15
Synchrocheck, energizing check and synchronizing SESRSYN 1MRK005917-XD 2 0-6 Can only be ordered
with Apparatus
control APC30
Autorecloser SMBRREC 1MRK005917-BC 3 0-4 Can only be ordered
with Apparatus
control APC10/
APC15
Autorecloser SMBRREC 1MRK005917-XE 4 0-6 Can only be ordered
with Apparatus
control APC30
Control functionality for a single bay, max 10 objects (1CB), APC10 1MRK005917-AZ 5 1 Only one of APC10,
including interlocking APC15 or APC30
must be ordered.
Control functionality for a single bay, max 15 objects (2CB), APC15 1MRK005917-BZ 6 1
including interlocking
Control functionality for up to 6 bays, max 30 objects (6CBs), APC30 1MRK005917-CZ 7 1
including interlocking
Automatic voltage control for tapchanger, single control TR1ATCC 1MRK005917-NC 8 0-4 Only one ATCC
may be selected.
Automatic voltage control for tapchanger, parallel control TR8ATCC 1MRK005917-PC 9 0-4
If TR1ATCC or
TR8ATCC is
ordered then one of
TCMYLTC or
TCLYLTC must be
ordered.
Tap changer control and supervision, 6 binary inputs TCMYLTC 1MRK005917-DB 10 0-4
Tap changer control and supervision, 32 binary inputs TCLYLTC 1MRK005917-EA 11 0-4
Table 187. Scheme communication
Position 1 2 3 4 5 6 7 8
K 0 0 0
Table 188. Scheme communication functions

Scheme communication logic with delta based blocking scheme ZCPSCH 1MRK005920-AA 1 0-1
signal transmit
Current reversal and weak-end infeed logic for distance protection ZCRWPSCH 1MRK005920-CA 3 0-1
Local acceleration logic ZCLCPSCH 1MRK005920-EA 5 0-1
Scheme communication logic for residual overcurrent protection ECPSCH 1MRK005920-FA 6 0-1
Current reversal and weak-end infeed logic for residual ECRWPSCH 1MRK005920-GA 7 0-1
overcurrent protection
Table 189. Logic
Position 1 2 3
L 00
Table 190. Logic functions

Configurable logic blocks Q/T 1MRK005922-MX 1 0-1
Extension logic package 1MRK005922-AZ 2 0-1
Table 191. Monitoring
Position 1 2 3
M
ABB 119
1MRK 511 404-BEN A
Table 192. Monitoring functions

Circuit breaker condition monitoring SSCBR 1MRK005924-HA 1 00-18
Fault locator LMBRFLO 1MRK005925-XB 2 0-1
Transformer insulation loss of life monitoring LOLSPTR 1MRK005924-NB 3 0-4
Table 193. Station communication
Position 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
P 0 0 0 0 0 0 0 0 0 0 0 0 0
Table 194. Station communication functions

IEC 61850-9-2 Process bus communication, 8 merging units 1MRK005933-HA 1 0-1
IEC 62439-3 Parallel redundancy protocol PRP 1MRK005932-FA 2 0-1 PRP and HSR
require two SFPs
IEC 62439-3 High-availability seamless redundancy HSR 1MRK005932-NA 3 0-1
placed in pairs.
Synchrophasor report, 8 phasors 1MRK005933-DA 15 0-1
Table 195. Language selection
Language Ordering no Selection Notes and rules

First local HMI user dialogue language
HMI language, English IEC 1MRK002930-AA B1
Additional local HMI user dialogue language
No additional HMI language X0
HMI language, English US 1MRK002920-UB A12
Selected B1
Table 196. Casing selection
Casing Ordering no Selection Notes and rules

1/2 x 19" rack casing, 1 TRM 1MRK000151-VA A
3/4 x 19" rack casing, 1 TRM 1MRK000151-VB B
3/4 x 19" rack casing, 2 TRM 1MRK000151-VE C
1/1 x 19" rack casing, 1 TRM 1MRK000151-VC D
1/1 x 19" rack casing, 2 TRM 1MRK000151-VD E
Selected
Table 197. Mounting selection
Mounting details with IP40 of protection from the front Ordering no Selection Notes and rules
No mounting kit included X
19" rack mounting kit for 1/2 x 19" case or 2xRHGS6 or RHGS12 1MRK002420-BB A
19" rack mounting kit for 3/4 x 19" case or 3xRHGS6 1MRK002420-BA B
19" rack mounting kit for 1/1 x 19" case 1MRK002420-CA C
Wall mounting kit 1MRK002420-DA D Wall mounting not recommended
with communication modules with
fibre connection
Flush mounting kit 1MRK002420-PA E
Flush mounting kit + IP54 mounting seal 1MRK002420-NA F
Selected
120 ABB
1MRK 511 404-BEN A
Table 198. Power supply module selection
Power supply module Ordering no Selection Notes and rules

Compression terminals 1MRK002960-GA C
Ringlug terminals 1MRK002960-HA R
Power supply module 24-60 VDC 1MRK002239-AB A
Power supply module 90-250 VDC 1MRK002239-BB B
Selected
Table 199. Human machine interface selection
Human machine hardware interface Case size Ordering no Selection 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", ANSI 1MRK000028-AB C
3/4 x 19”, ANSI 1MRK000028-CB
1/1 x 19”, ANSI 1MRK000028-BB
Selected
ABB 121
1MRK 511 404-BEN A
Table 200. Analog system selection
Analog system Ordering no Selection Notes and rules

When more than one TRM is selected, the connector type on both TRMs must be the same (A compression or B ring lug).
Slot position (front view/rear view)
P40/X401
P41/X411
No Transformer input module included X0 X0
TRM 12I 1A, 50/60Hz, compression terminals 1MRK002247-CG A1 A1
TRM 12I 5A, 50/60Hz, compression terminals 1MRK002247-CH A2 A2
TRM 9I 1A + 3U 110/220V, 50/60Hz, compression terminals 1MRK002247-BG A3 A3
TRM 9I 5A + 3U 110/220V, 50/60Hz, compression terminals 1MRK002247-BH A4 A4
TRM 5I 1A + 4I 5A + 3U 110/220V, 50/60Hz, compression terminals 1MRK002247-BK A5 A5
TRM 6I 1A + 6U 110/220V, 50/60Hz, compression terminals 1MRK002247-AG A6 A6
TRM 6I 5A + 6U 110/220V, 50/60Hz, compression terminals 1MRK002247-AH A7 A7
TRM 6I 1A, 50/60Hz, compression terminals 1MRK002247-DG A8 A8
TRM 6I 5A, 50/60Hz, compression terminals 1MRK002247-DH A9 A9
TRM 7I 1A + 5U 110/220V, 50/60Hz, compression terminals 1MRK002247-AP A12 A12
TRM 7I 5A + 5U 110/220V, 50/60Hz, compression terminals 1MRK002247-AR A13 A13
TRM 6I 5A + 1I 1A + 5U 110/220V, 50/60Hz, compression terminals 1MRK002247-AU A14 A14
TRM 3I 5A + 4I 1A + 5U 110/220V, 50/60Hz, compression terminals 1MRK002247-AV A15 A15
TRM 3I 5A + 3I 1A + 6U 110/220V, 50/60Hz, compression terminals 1MRK002247-AE A16 A16
TRM 3IM 1A + 4IP 1A + 5U 110/220V, 50/60Hz, compression terminals 1MRK002247-EA A17 A17
TRM 3IM 5A + 4IP 5A + 5U 110/220V, 50/60Hz, compression terminals 1MRK002247-EB A18 A18
TRM 10I 1A + 2U 110/220V, 50/60Hz, compression terminals 1MRK002247-FA A19 A19
TRM 10I 5A + 2U 110/220V, 50/60Hz, compression terminals 1MRK002247-FB A20 A20
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 1A + 6U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AC B6 B6
TRM 6I 5A + 6U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AD B7 B7
TRM 6I 1A, 50/60Hz, ring lug terminals 1MRK002247-DC B8 B8
TRM 6I 5A, 50/60Hz, ring lug terminals 1MRK002247-DD B9 B9
TRM 7I 1A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AS B12 B12
TRM 7I 5A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AT B13 B13
TRM 6I 5A + 1I 1A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AX B14 B14
TRM 3I 5A + 4I 1A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AY B15 B15
TRM 3I 5A + 3I 1A + 6U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AF B16 B16
TRM 3IM 1A + 4IP 1A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-EC B17 B17
TRM 3IM 5A + 4IP 5A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-ED B18 B18
TRM 10I 1A + 2U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-FC B19 B19
TRM 10I 5A + 2U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-FD B20 B20
Selected
122 ABB
1MRK 511 404-BEN A
Table 201. Maximum quantity of I/O modules, with compression terminals
When ordering I/O modules, observe the maximum quantities according to the tables below.
Note: Standard order of location for I/O modules is BIM-BOM-SOM-IOM-MIM from left to right as seen from the rear side of the IED, but
can also be freely placed.
Note: The maximum quantity of I/O modules depends on the type of connection terminals.
Case sizes BIM IOM BOM/ MIM Maximum in case
SOM
1/1 x 19” rack casing, 14 6 4 4 14 *)
one (1) TRM
1/1 x 19” rack casing, 11 6 4 4 11 *)
two (2) TRM
3/4 x 19” rack casing, 8 6 4 4 8 *)
one (1) TRM
3/4 x 19” rack casing, 5 5 4 4 5 *)
two (2) TRM
1/2 x 19” rack casing, 3 3 3 1 3
one (1) TRM
*) including a combination of maximum four modules of type BOM, SOM and MIM
Table 202. Maximum quantity of I/O modules, with ringlug terminals
Note: Only every second slot can be used.

Case sizes BIM IOM BOM/ MIM Maximum in case
SOM
1/1 x 19” rack casing, 7 6 4 4 7 **) possible locations: P3, P5, P7, P9, P11, P13, P15
one (1) TRM
1/1 x 19” rack casing, 5 5 4 4 5 **) possible locations: P3, P5, P7, P9, P11
two (2) TRM
3/4 x 19” rack casing, 4 4 4 4 4 **) possible locations: P3, P5, P7, P9
one (1) TRM
3/4 x 19” rack casing, 2 2 2 2 2, possible locations: P3, P5
two (2) TRM
1/2 x 19” rack casing, 1 1 1 1 1, possible location: P3
one (1) TRM
**) including a combination of maximum four modules of type BOM, SOM and MIM
ABB 123
1MRK 511 404-BEN A
Table 203. Binary input/output module selection
Binary input/ Ordering no Selection Notes and rules

output modules
Slot position
P3/X31
P4/X41
P5/X51
P6/X61
P7/X71
P8/X81
P9/X91
P10/X101
P11/X111
P12/X121
P13/X131
P14/X141
P15/X151
P16/X161
(front view/rear
view)
1/2 case with 1 █ █ █ These black marks

TRM indicate the maximum
number of modules per
3/4 case with 1 █ █ █ █ █ █ █ █
casing type and the
TRM
slots that can be
3/4 case with 2 █ █ █ █ █ occupied.
TRM
1/1 case with 1 █ █ █ █ █ █ █ █ █ █ █ █ █ █
TRM
1/1 case with 2 █ █ █ █ █ █ █ █ █ █ █
TRM
Compression 1MRK002960-KA C
terminals
Ringlug terminals 1MRK002960-LA R Only every second slot
can be used; see Table
202
No board in slot X X X X X X X X X X X X X X
Binary output 1MRK000614-AB A A A A A A A A A A A A A A
module 24 output
relays (BOM)
BIM 16 inputs, 1MRK000508-DD B1 B1 B1 B1 B1 B1 B1 B1 B1 B1 B1 B1 B1 B1
RL24, 24-30VDC,
50mA
BIM 16 inputs, 1MRK000508-AD C1 C1 C1 C1 C1 C1 C1 C1 C1 C1 C1 C1 C1 C1
RL48, 48-60VDC,
50mA
BIM 16 inputs, 1MRK000508-BD D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1
RL110,
110-125VDC,
50mA
BIM 16 inputs, 1MRK000508-CD E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1
RL220,
220-250VDC,
50mA
BIM 16 inputs, 1MRK000508-CE E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2
RL220,
220-250VDC,
120mA
BIM 16 inputs, 1MRK000508-HA F F F F F F F F F F F F F F
RL24, 24-30VDC,
50mA, enhanced
pulse counting
BIM 16 inputs, 1MRK000508-EA G G G G G G G G G G G G G G
RL48, 48-60VDC,
50mA, enhanced
pulse counting
BIM 16 inputs, 1MRK000508-FA H H H H H H H H H H H H H H
RL110,
110-125VDC,
50mA, enhanced
pulse counting
BIM 16 inputs, 1MRK000508-GA K K K K K K K K K K K K K K
RL220,
220-250VDC,
50mA, enhanced
pulse counting
IOM 8 inputs, 1MRK000173-GD L1 L1 L1 L1 L1 L1 L1 L1 L1 L1 L1 L1 L1 L1
10+2 outputs,
RL24, 24-30VDC,
50mA
IOM 8 inputs, 1MRK000173-AE M1 M1 M1 M1 M1 M1 M1 M1 M1 M1 M1 M1 M1 M1
10+2 outputs,
RL48, 48-60VDC,
50mA
124 ABB
1MRK 511 404-BEN A
Table 203. Binary input/output module selection, continued

Binary input/ Ordering no Selection Notes and rules
output modules
IOM 8 inputs, 1MRK000173-BE N1 N1 N1 N1 N1 N1 N1 N1 N1 N1 N1 N1 N1 N1
10+2 outputs,
RL110,
110-125VDC,
50mA
IOM 8 inputs, 1MRK000173-CE P1 P1 P1 P1 P1 P1 P1 P1 P1 P1 P1 P1 P1 P1
10+2 outputs,
RL220,
220-250VDC,
50mA
IOM 8 inputs 1MRK000173-CF P2 P2 P2 P2 P2 P2 P2 P2 P2 P2 P2 P2 P2 P2
10+2 outputs,
RL220,
220-250VDC,
110mA
IOM with MOV 8 1MRK000173-GC U U U U U U U U U U U U U U
inputs, 10+2
outputs, RL24,
24-30VDC, 50mA
IOM with MOV 8 1MRK000173-AD V V V V V V V V V V V V V V
inputs, 10+2
outputs, RL48,
48-60VDC, 50mA
IOM with MOV 8 1MRK000173-BD W W W W W W W W W W W W W W
inputs, 10+2
outputs, RL110,
110-125VDC,
50mA
IOM with MOV 8 1MRK000173-CD Y Y Y Y Y Y Y Y Y Y Y Y Y Y
inputs, 10+2
outputs, RL220,
220-250VDC,
50mA
mA input module 1MRK000284-AB R R R R R R R R R R R R R R
MIM 6 channels
SOM Static 1MRK002614-BA T1 T1 T1 T1 T1 T1 T1 T1 T1 T1 T1 T1 T1 SOM must not be
output module, placed in the following
12 outputs; 6 positions: 1/2 case slot
standard relays P5, 3/4 case 1 TRM slot
+ 6 static outputs, P10, 3/4 case 2 TRM
48-60VDC slot P7, 1/1 case 2 TRM
slot P13.
SOM Static 1MRK002614-CA T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 T2
output module,
12 outputs; 6
standard relays
+ 6 static outputs,
110-250VDC
Selected
ABB 125
1MRK 511 404-BEN A
Table 204. Station communication, remote end serial communication and time synchronization selection
Station communication, remote end Ordering no Selection Notes and rules

serial communication and time
synchronization
Slot position (front view/rear view) The maximum number
P30:1/X301
P30:2/X302
P30:3/X303
P30:4/X304
P30:5/X305
P30:6/X306
P30:6:1/X3061
P30:6:2/X3062
P31:1/X311
P31:2/X312
P31:3/X313
P32:2/X322
P32:3/X323
LDCM mode
and type of LDCM
modules supported
depend on the total
amount of I/O and
communication modules
in the IED.
Available slots in 1/2, 3/4 and 1/1 █ █ █ █ █ █ █ █ █ █ █ █
case with 1 TRM
Available slots in 3/4 and 1/1 case █ █ █ █ █ █ █ █ █ █ █ █ █ █
with 2 TRM
No communication board included X X X X X X X X X X X X
Ethernet SFP, optical LC connector 1MRK005500-AA K K K K K K Ethernet SFP is basic in
P30:1. P30:6:1 and
Ethernet SFP, RJ45 connector 1MRK005500-BA P p p p p p
P30:6:2 require the
Optical Ethernet module
in P30:6.
Optical Ethernet module 1MRK002266-EA H
Serial SPA/LON/DNP/IEC 1MRK001608-AB L
60870-5-103 plastic interface
Serial SPA/LON/DNP/IEC 1MRK001608-BB M
60870-5-103 plastic/glass interface
Serial SPA/LON/DNP/IEC 1MRK001608-CB N
60870-5-103 glass interface
Galvanic RS485 communication 1MRK002309-AA G G G G
module
Optical short range LDCM 1MRK002122-AB A A A A A A Max 2 LDCMs can be
ordered. Always place
Optical medium range LDCM, 1310 1MRK002311-AA B B B B B B
LDCM modules on the
nm
same board to support
Optical long range LDCM, 1550 nm 1MRK002311-BA C C C C C C redundant
communication: in P30:5
and P30:6, P31:2 and
P31:3 or P32:2 and
P32:3.
Line data communication, default — X Default if no LDCM is
64kbps mode selected
Allow line data communication in 1MRK007002-AA Y
2Mbps mode
GPS time module 1MRK002282-AB S S S S
IRIG-B time synchronization module 1MRK002305-AA F F F F
Selected K
126 ABB
1MRK 511 404-BEN A
25. Ordering for pre-configured IED

GUID-25AF8847-411F-4F1D-91ED-0ED71C5AA8A1 v12
Guidelines
Carefully read and follow the set of rules to ensure problem-free order management.
Please refer to the available functions table for included application functions.
PCM600 can be used to make changes and/or additions to the delivered factory configuration of the pre-configured.
To obtain the complete ordering code, please combine code from the tables, as given in the example below.
Example code: REC670 *2.2-A30X00- A02H02-B1A3-AC-CA-B-A3X0-CDAB1RGN1N1XXXXXXX-KKKXXHKKLAGXSY. Using the code of each position #1-11
specified as REC670*1-2 2-3 3-4 4-5 6-7 7-8-9 9 9-10 10 10 10 10 10 10 10-11 11 11 11 11 11 11 11 11 11 11
# 1 - 2 - 3 - 4 - 5 6 - 7 - 8 - 9 -
REC670* 2.2 - - - - - - - -
10 - 11
-
Position
SOFTWARE #1 Notes and rules
Version number
Version no. 2.2
Selection for position #1
Configuration alternatives Ordering no #2 Notes and rules

Single breaker 1MRK004004-AG A30
Double breaker 1MRK004004-BG B30
1 1/2 breaker diameter 1MRK004004-CG C30
Single breaker, with PMU 1MRK004004-EG D30
ACT configuration
ABB standard configuration X00
Selection for
position #2
ABB 127
1MRK 511 404-BEN A
Software options Ordering no #3 Notes and rules

No option X00 All fields in the ordering form do
not need to be filled in.
High impedance differential protection - 3 blocks 1MRK004001-AB A02 A02 only in A30/B30/D30, A07
only in C30
High impedance differential protection - 6 blocks 1MRK004001-AG A07
Stub protection 1MRK004001-VG B25 B25 only in B30/C30
1MRK004001-VK B27 B27 only in A30/D30
Sensitive directional residual overcurrent and power protection 1MRK004001-CT C16
Directional power and voltage restrained overcurrent protection 1MRK004001-VL C35
Current and breaker failure protection - 1 circuit breaker 1MRK004001-US C51 Only one type of Current and
breaker failure protection can be
Current and breaker failure protection - 2 circuit breakers 1MRK004001-UT C52
ordered.
Current and breaker failure protection - 1 1/2 circuit breaker 1MRK004001-UU C53 C51 only in A30/D30; C52 only in
B30; C53 only in C30
Voltage protection - 2 buses 1MRK004001-DB D02
Frequency protection - station 1MRK004001-EA E01
General current and voltage protection 1MRK004001-FA F01
Fuse failure supervision based on voltage difference 1MRK004001-HC G03
Autorecloser, 1 circuit breaker 1MRK004001-GD H04 Only one type of Autorecloser
can be ordered.
Autorecloser, 2 circuit breakers 1MRK004001-GE H05
H04 only in A30/D30, H05 only in
Autorecloser, 3 circuit breakers 1MRK004001-GF H06 B30, H06 only in C30
Voltage control, single transformer 1MRK004001-GL H11 H11 and H15 only in
A30/B30/D30
Voltage control, parallel transformers 1MRK004001-GM H15
H16 and H18 only in C30
Voltage control, single transformer, 2 control blocks 1MRK004001-GN H16 Only one type of voltage control
Voltage control, parallel transformers, 2 control blocks 1MRK004001-GP H18 can be ordered.
Scheme communication 1MRK004001-KC K01

Transformer insulation loss of life monitoring 1MRK004001-KM M21
IEC 62439-3 Parallel redundancy protocol 1MRK004001-PP P23 Options P23 and P24 require two
SFPs placed in pairs.
IEC 62439-3 High-availability seamless redundancy 1MRK004001-PR P24
IEC 61850-9-2 Process Bus communication, 8 merging units 1MRK004001-PT P30
Synchrophasor report, 8 phasors 1MRK004001-PV P32 P32 only in A30/B30/C30
Selection for
position #3
Language Ordering no #4 Notes and rules

First local HMI user dialogue language
HMI language, English IEC 1MRK002930-AA B1
Additional local HMI user dialogue language
No additional HMI language X0
HMI language, English US 1MRK002920-UB A12
Selection for B1
position #4
Casing Ordering no #5 Notes and rules

1/2 x 19" rack casing, 1 TRM 1MRK000151-VA A Only for A30/B30/D30
3/4 x 19" rack casing, 1 TRM 1MRK000151-VB B
3/4 x 19" rack casing, 2 TRM 1MRK000151-VE C
1/1 x 19" rack casing, 1 TRM 1MRK000151-VC D Only for A30/B30/D30
1/1 x 19" rack casing, 2 TRM 1MRK000151-VD E
Selection for
position #5
128 ABB
1MRK 511 404-BEN A
Mounting details with IP40 of protection from the front Ordering no #6 Notes and rules
No mounting kit included X
19" rack mounting kit for 1/2 x 19" case or 2xRHGS6 or RHGS12 1MRK002420-BB A Only for A30/B30/D30
19" rack mounting kit for 3/4 x 19" case or 3xRGHS6 1MRK002420-BA B
19" rack mounting kit for 1/1 x 19" case 1MRK002420-CA C
Wall mounting kit 1MRK002420-DA D Wall mounting not recommended
with communication modules with
fibre connection
Flush mounting kit 1MRK002420-PA E
Flush mounting kit + IP54 mounting seal 1MRK002420-NA F
Selection for
position #6
Power supply modules Ordering no #7 Notes and rules

Compression terminals 1MRK002960-GA C
Ringlug terminals 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 Only valid for A30/B30/D30
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", ANSI 1MRK000028-AB C Only valid for A30/B30/D30
3/4 x 19”, ANSI 1MRK000028-CB
1/1 x 19”, ANSI 1MRK000028-BB
Selection for
position #8
Analog system Ordering no #9 Notes and rules

When more than one TRM is selected, the connector type on both TRMs must be the same (A compression or B ring lug).
Slot position (front view/rear view)
P40/X401
P41/X411
No Transformer input module included X0 X0 Only valid if IEC 61850-9-2

Process bus communication is
selected.
TRM 9I 1A + 3U 110/220V, 50/60Hz, compression terminals 1MRK002247-BG A3 Only for A30/B30/D30
TRM 9I 5A + 3U 110/220V, 50/60Hz, compression terminals 1MRK002247-BH A4
TRM 5I 1A + 4I 5A + 3U 110/220V, 50/60Hz, compression terminals 1MRK002247-BK A5
TRM 6I 1A + 6U 110/220V, 50/60Hz, compression terminals 1MRK002247-AG A6 A6 A second TRM is optional for
A30/B30/D30 and required for
TRM 6I 5A + 6U 110/220V, 50/60Hz, compression terminals 1MRK002247-AH A7 A7
C30.
TRM 6I 1A, 50/60Hz, compression terminals 1MRK002247-DG A8 Only for A30/B30/D30
TRM 6I 5A, 50/60Hz, compression terminals 1MRK002247-DH A9
TRM 7I 1A + 5U 110/220V, 50/60Hz, compression terminals 1MRK002247-AP A12
TRM 7I 5A + 5U 110/220V, 50/60Hz, compression terminals 1MRK002247-AR A13
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 A second TRM is optional for
A30/B30/D30 and required for
TRM 6I 5A + 6U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AD B7 B7
C30.
TRM 6I 1A, 50/60Hz, ring lug terminals 1MRK002247-DC B8 Only for A30/B30/D30
TRM 6I 5A, 50/60Hz, ring lug terminals 1MRK002247-DD B9
TRM 7I 1A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AS B12
TRM 7I 5A + 5U 110/220V, 50/60Hz, ring lug terminals 1MRK002247-AT B13
Selection for
position #9
ABB 129
1MRK 511 404-BEN A
Binary input/output Ordering no #10 Notes and rules

module and mA
input module
For pulse counting, for example kWh metering, the BIM with enhanced pulse counting capabilities must be used.
Note: 1 BIM required in position P3 and 1 BOM required in position P4. Products B30 and C30 require an extra BIM in position P5.
Slot position (front
P3/X31
P4/X41
P5/X51
P6/X61
P7/X71
P8/X81
P9/X91
P10/X101
P11/X111
P12/X121
P13/X131
P14/X141
P15/X151
P16/X161
view/rear view)
1/2 case with 1 TRM █ █ █ These black marks

indicate the maximum
3/4 case with 1 TRM █ █ █ █ █ █ █ █
number of modules per
3/4 case with 2 TRM █ █ █ █ █ casing type and the
1/1 case with 1 TRM █ █ █ █ █ █ █ █ █ █ █ █ █ █ slots that can be
occupied.
1/1 case with 2 TRM █ █ █ █ █ █ █ █ █ █ █
Compression 1MRK002960-KA C
terminals
No board in slot X X X X X X X X X X X X
Binary output 1MRK000614-AB A A A A A A A A A A A A A Maximum 4 (BOM+SOM
module 24 output +MIM) boards. P5 not in
relays (BOM) B30/C30.
BIM 16 inputs, 1MRK000508-DD B1 B1 B1 B1 B1 B1 B1 B1 B1 B1 B1 B1 B1
RL24, 24-30VDC,
50mA
BIM 16 inputs, 1MRK000508-AD C1 C1 C1 C1 C1 C1 C1 C1 C1 C1 C1 C1 C1
RL48, 48-60VDC,
50mA
BIM 16 inputs, 1MRK000508-BD D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1 D1
RL110,
110-125VDC,
50mA
BIM 16 inputs, 1MRK000508-CD E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1 E1
RL220,
220-250VDC,
50mA
BIM 16 inputs, 1MRK000508-CE E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2 E2
RL220,
220-250VDC,
120mA
BIM 16 inputs, 1MRK000508-HA F F F F F F F F F F F F P5 not in B30/C30
RL24, 24-30VDC,
50mA, enhanced
pulse counting
BIM 16 inputs, 1MRK000508-EA G G G G G G G G G G G G
RL48, 48-60VDC,
50mA, enhanced
pulse counting
BIM 16 inputs, 1MRK000508-FA H H H H H H H H H H H H
RL110,
110-125VDC,
50mA, enhanced
pulse counting
BIM 16 inputs, 1MRK000508-GA K K K K K K K K K K K K
RL220,
220-250VDC,
50mA, enhanced
pulse counting
IOM 8 inputs, 10+2 1MRK000173-GD L1 L1 L1 L1 L1 L1 L1 L1 L1 L1 L1 L1
outputs, RL24,
24-30VDC, 50mA
IOM 8 inputs, 10+2 1MRK000173-AE M1 M1 M1 M1 M1 M1 M1 M1 M1 M1 M1 M1
outputs, RL48,
48-60VDC, 50mA
IOM 8 inputs, 10+2 1MRK000173-BE N1 N1 N1 N1 N1 N1 N1 N1 N1 N1 N1 N1
outputs, RL110,
110-125VDC,
50mA
IOM 8 inputs, 10+2 1MRK000173-CE P1 P1 P1 P1 P1 P1 P1 P1 P1 P1 P1 P1
outputs, RL220,
220-250VDC,
50mA
130 ABB
1MRK 511 404-BEN A
Binary input/output Ordering no #10 Notes and rules

module and mA
input module
For pulse counting, for example kWh metering, the BIM with enhanced pulse counting capabilities must be used.
Note: 1 BIM required in position P3 and 1 BOM required in position P4. Products B30 and C30 require an extra BIM in position P5.
IOM 8 inputs 10+2 1MRK000173-CF P2 P2 P2 P2 P2 P2 P2 P2 P2 P2 P2 P2
outputs, RL220,
220-250VDC,
110mA
IOM with MOV 8 1MRK000173-GC U U U U U U U U U U U U
inputs, 10+2
outputs, RL24,
24-30VDC, 50mA
IOM with MOV 8 1MRK000173-AD V V V V V V V V V V V V
inputs, 10+2
outputs, RL48,
48-60VDC, 50mA
IOM with MOV 8 1MRK000173-BD W W W W W W W W W W W W
inputs, 10+2
outputs, RL110,
110-125VDC,
50mA
IOM with MOV 8 1MRK000173-CD Y Y Y Y Y Y Y Y Y Y Y Y
inputs, 10+2
outputs, RL220,
220-250VDC,
50mA
mA input module 1MRK000284-AB R R R R R R R R R R R R Maximum 1 MIM in 1/2
MIM 6 channels case
P5 not in B30/C30
SOM Static output 1MRK002614-BA T1 T1 T1 T1 T1 T1 T1 T1 T1 T1 T1 SOM must not to be
module, 12 placed in the position
outputs; 6 standard nearest to NUM: 1/2
relays + 6 static case slot P5, 3/4 case 1
outputs, 48-60VDC TRM slot P10, 3/4 case
2 TRM slot P7, 1/1 case
SOM Static output 1MRK002614-CA T2 T2 T2 T2 T2 T2 T2 T2 T2 T2 T2
2 TRM slot P13.
module, 12
P5 not in B30/C30
outputs; 6 standard
relays + 6 static
outputs,
110-250VDC
Selection for C
position #10
ABB 131
1MRK 511 404-BEN A
Station communication, remote end Ordering no #11 Notes and rules

serial communication and time
synchronization
Slot position (front view/rear view) The maximum number
P30:1/X301
P30:2/X302
P30:3/X303
P30:4/X304
P30:5/X305
P30:6/X306
P30:6:1/X3061
P30:6:2/X3062
P31:1/X311
P31:2/X312
P31:3/X313
P32:2/X322
P32:3/X323
LDCM mode
and type of LDCM
modules supported
depend on the total
amount of I/O and
communication modules
in the IED.
Available slots in 1/2 and 3/4 case █ █ █ █ █ █ █ █ █ █ █ █
with 1 TRM
Available slots in 3/4 and 1/1 case █ █ █ █ █ █ █ █ █ █ █ █ █ █
with 2 TRM
No communication board included X X X X X X X X X X X X
Ethernet SFP, optical LC connector 1MRK005500-AA K K K K K K Ethernet SFP is basic in
P30:1. P30:6:1 and
Ethernet SFP, RJ45 connector 1MRK005500-BA p p p p p p
P30:6:2 require Optical
Ethernet module in
P30:6.
Optical Ethernet module 1MRK002266-EA H
Serial SPA/LON/DNP/IEC 1MRK001608-AB L
60870-5-103 plastic interface
Serial SPA/LON/DNP/IEC 1MRK001608-BB M
60870-5-103 plastic/glass interface
Serial SPA/LON/DNP/IEC 1MRK001608-CB N
60870-5-103 glass interface
Galvanic RS485 communication 1MRK002309-AA G G G G
module
Optical short range LDCM 1MRK002122-AB A A A A A A Max 2 LDCMs can be
ordered. Always place
Optical medium range, LDCM 1310 1MRK002311-AA B B B B B B
LDCM modules on the
nm
same board to support
redundant
communication: in P30:5
and P30:6, P31:2 and
P31:3 or P32:2 and
P32:3.
Line data communication, default — X Default if no LDCM is
64kbps mode selected
Allow line data communication in 1MRK007002-AA Y
2Mbps mode
GPS time module 1MRK002282-AB S S S S
IRIG-B time synchronization module 1MRK002305-AA F F F F
Selection for K
position #11
132 ABB
1MRK 511 404-BEN A
26. Ordering for Accessories
Accessories
IP15151-1 v1
GPS antenna and mounting details
M12374-3 v5
GPS antenna, including mounting kits Quantity: 1MRK 001 640-AA
Cable for antenna, 20 m (Appx. 65 ft) Quantity: 1MRK 001 665-AA
Cable for antenna, 40 m (Appx. 131 ft) Quantity: 1MRK 001 665-BA
Interface converter (for remote end data communication)

M16668-3 v9
External interface converter from C37.94 (64kbps) to G703 Quantity: 1 2

1MRK 002 245-AA
External interface converter from C37.94 (64kbps/2Mbps) to G703.E1 Quantity: 1 2

1MRK 002 245-BA
Test switch Multi-breaker/Single or Three Phase trip with internal neutral

SEMOD111888-5 v12
The test system COMBITEST intended for use with the IEDs on current circuits (ordering number RK926 315-BE).
is described in 1MRK 512 001-BEN and 1MRK 001024-CA.
Please refer to the website: www.abb.com/protection-control Multi-breaker/Single or Three Phase trip with external neutral
for detailed information. on current circuit (ordering number RK926 315-BV).
Due to the high flexibility of our product and the wide variety The normally open "In test mode" contact 29-30 on the RTXP
of applications possible the test switches needs to be test switches should be connected to the input of the test
selected for each specific application. function block to allow activation of functions individually
during testing.
Select your suitable test switch base on the available
contacts arrangements shown in the reference Test switches type RTXP 24 is ordered separately. Please
documentation. refer to Section Related documents for references to
corresponding documents.
However our proposals for suitable variants are;
RHGS 6 Case or RHGS 12 Case with mounted RTXP 24 and
Single breaker/Single or Three Phase trip with internal neutral the on/off switch for dc-supply are ordered separately. Please
on current circuits (ordering number RK926 315-AK). 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).
Protection cover
M15040-3 v6
Protective cover for rear side of RHGS6, 6U, 1/4 x 19” Quantity: 1MRK 002 420-AE
Protective cover for rear side of terminal, 6U, 1/2 x 19” Quantity: 1MRK 002 420-TA
Protective cover for rear side of terminal, 6U, 3/4 x 19” Quantity: 1MRK 002 420-SA
Protective cover for rear side of terminal, 6U, 1/1 x 19” Quantity: 1MRK 002 420-RA
ABB 133
1MRK 511 404-BEN A
External resistor unit

SEMOD120228-4 v8
High impedance resistor unit with resistor and voltage dependent resistor 20-100V, 1ph Quantity: 1 2 3
RK 795 101-MA
High impedance resistor unit with resistor and voltage dependent resistor 20-100V, 3ph Quantity: RK 795 101-MB
High impedance resistor unit with resistor and voltage dependent resistor 100-400V, 1ph Quantity: 1 2 3
RK 795 101-CB
High impedance resistor unit with resistor and voltage dependent resistor 100-400V, 3ph Quantity: RK 795 101-DC
Combiflex
IP15161-1 v1
Key switch for settings SEMOD130356-4 v6
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 v6
Mounting kit Ordering number

Side-by-side mounting kit Quantity: 1MRK 002 420-Z
Configuration and monitoring tools

M15042-3 v4 IP15162-1 v2
Front connection cable between LHMI and PC Quantity: 1MRK 001 665-CA
SEMOD131414-4 v3
LED Label special paper A4, 1 pc Quantity: 1MRK 002 038-CA
LED Label special paper Letter, 1 pc Quantity: 1MRK 002 038-DA
Manuals
M15161-3 v13
Note: One (1) IED Connect USB flash drive containing user documentation (Operation manual, Technical
manual, Installation manual, Commissioning manual, Application manual and Getting started guide),
Connectivity packages and LED label template is always included for each IED.
Rule: Specify additional quantity of IED Connect USB flash drive requested. Quantity: 1MRK 002 290-AE
134 ABB
1MRK 511 404-BEN A
User documentation
Rule: Specify the number of printed manuals requested
Application manual IEC Quantity: 1MRK 511 401-UEN
ANSI Quantity: 1MRK 511 401-UUS
Technical manual IEC Quantity: 1MRK 511 402-UEN
Commissioning manual IEC Quantity: 1MRK 511 403-UEN
Communication protocol manual, IEC 61850 Edition 1 IEC Quantity: 1MRK 511 392-UEN
Communication protocol manual, IEC 61850 Edition 2 IEC Quantity: 1MRK 511 393-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
Installation manual IEC Quantity: 1MRK 514 026-UEN
Engineering manual IEC Quantity: 1MRK 511 398-UEN
ABB 135
1MRK 511 404-BEN A
Cyber security deployment guideline IEC Quantity: 1MRK 511 399-UEN
Application guide, Communication set-up IEC Quantity: 1MRK 505 382-UEN
Reference information
M2175-3 v4
For our reference and statistics we would be pleased to be provided with the following application data:
Country: End user:
Station name: Voltage level: kV
Related documents
GUID-94E8A5CA-BE1B-45AF-81E7-5A41D34EE112 v5 670 series manuals Document numbers
Documents related to REC670 Document numbers Operation manual IEC:1MRK 500 127-UEN
ANSI:1MRK 500 127-UUS
Application manual IEC:1MRK 511 401-UEN
ANSI:1MRK 511 401-UUS Engineering manual IEC:1MRK 511 398-UEN
Commissioning manual IEC:1MRK 511 403-UEN
ANSI:1MRK 511 403-UUS Installation manual IEC:1MRK 514 026-UEN
Product guide 1MRK 511 404-BEN
Communication protocol manual, 1MRK 511 391-UUS
Technical manual IEC:1MRK 511 402-UEN DNP3
Communication protocol manual, 1MRK 511 394-UEN
Type test certificate IEC:1MRK 511 404-TEN IEC 60870-5-103
ANSI:1MRK 511 404-TUS
IEC 61850 Edition 1

IEC 61850 Edition 2

LON

SPA
Point list manual, DNP3 1MRK 511 397-UUS
Accessories guide IEC:1MRK 514 012-BEN

ANSI:1MRK 514 012-BUS
Cyber security deployment 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
136 ABB
137
—
ABB AB
Grid Automation Products
721 59 Västerås, Sweden
Phone: +46 (0) 21 32 50 00
abb.com/protection-control
1MRK 511 404-BEN
© Copyright 2017 ABB. All rights reserved.

Specifications subject to change without notice.

1MRK511404-BEN A en Product Guide Bay Control REC670 Version 2.2

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Bay control REC670

1. Application..................................................................... 3 14. Monitoring................................................................... 36

1. Application Duplex communication channels for transfer of up to 192

Description of configuration A30

WA2 3 Control 3 Control 3 Control

QC1 WA1_VT 3 Control 3 Control 3 Control

QA1 3 Control 3 Control 3 Control MET UN 25 SC/VC

3 Control 3 Control 3 Control MET W/Varh

LINE_VT DRP RDRE Q CBAY Q CRSV

MET U MET Usqi MET UN

Other Functions available from the function library

46 Iub> 52PD PD 87 INd/I 21FL FL 27 3U< 3 Control 94 1 0 84 84

60 Ud> 51V 2(I>/U<) 85 85

Figure 1. Configuration diagram for configuration A30

Description of configuration B30

3 Control 3 Control 3 Control

WA1_VT S CILO S CSWI S XSWI VN MMXU SES RSYN

3 Control 3 Control 3 Control MET UN 25 SC/VC

LINE_CT2 C MMXU C MSQI FUF SPVC

3 Control 3 Control 3 Control MET P/Q

3 Control 3 Control 3 Control MET W/Varh

3 Control 3 Control 3 Control

3 Control 3 Control 3 Control

MET U MET Usqi MET UN

Other Functions available from the function library

26 θ 26 θ 46I2 4(I2>) 51_67 4(3I>) 59 2(3U>) 50 3I>> 59N 2(U0>) 81 df/dt<>

f> f< θ U↑↓ U↑↓ 2(3U<)

81 81 67N IN> 79 5(0 1) 50STB 3I>STB 49 90 90 27

60 Ud> 51V 2(I>/U<) 85 85

Figure 2. Configuration diagram for configuration B30

Description of configuration C30

QB1 3 Control 3 Control 3 Control

WA1_QA1 3 Control 3 Control 3 Control MET UN 25 SC

3 Control 3 Control 3 Control

3 Control 3 Control 3 Control

WA2_QB6 S CILO S CSWI S XSWI

LINE2_VT S CILO S CSWI S XSWI DRP RDRE

3 Control 3 Control 3 Control MET U MET Usqi MET UN

3 Control 3 Control 3 Control 63 71

3 Control 3 Control 3 Control MET UN

Other Functions available from the function library

Figure 3. Configuration diagram for configuration C30

Description of configuration D30

WA2 3 Control 3 Control 3 Control

S CILO S CSWI S XSWI

S CILO S CSWI S XSWI

QC1 WA1_VT 3 Control 3 Control 3 Control

S CILO S CSWI S XSWI

QA1 3 Control 3 Control 3 Control MET UN 25 SC/VC

S CILO S CSWI S XSWI

3 Control 3 Control 3 Control MET W/Varh

S CILO S CSWI S XSWI

MET U MET Usqi MET UN

Other Functions available from the function library

Figure 4. Configuration diagram for configuration D30

Main protection functions

Table 1. Example of quantities

2 = number of basic instances