1MRK504117-BEN B en Product Guide RET670 1.2 Customized

Relion® 670 series

Transformer protection RET670CustomizedProduct Guide

Contents

1. Application...........................................................3

2. Available functions...............................................4

3. Differential protection.........................................13

4. Impedance protection........................................15

5. Current protection..............................................18

6. Voltage protection..............................................21

7. Frequency protection.........................................22

8. Multipurpose protection.....................................22

9. Secondary system supervision..........................23

10. Control...............................................................23

11. Scheme communication....................................25

12. Logic..................................................................26

13. Monitoring.........................................................26

14. Metering............................................................29

15. Basic IED functions...........................................29

16. Human machine interface.................................29

17. Station communication ....................................30

18. Remote communication....................................31

19. Hardware description........................................32

20. Connection diagrams........................................34

21. Technical data...................................................43

22. Ordering..........................................................104

Disclaimer

The information in this document is subject to change without notice and should not be construed as a commitment by ABB AB. ABB AB assumesno responsibility for any errors that may appear in this document.

© Copyright 2011 ABB AB.

All rights reserved.

Trademarks

ABB and Relion are registered trademarks of ABB Group. All other brand or product names mentioned in this document may be trademarks orregistered trademarks of their respective holders.

Transformer protection RET670 1MRK 504 117-BEN BCustomizedProduct version: 1.2 Issued: September 2011

2 ABB

1. Application

RET670 provides fast and selectiveprotection, monitoring and control for two-and three-winding transformers,autotransformers, generator-transformerunits, phase shifting transformers, specialrailway transformers and shunt reactors. Thetransformer IED is designed to operatecorrectly over a wide frequency range inorder to accommodate power systemfrequency variations during disturbances andgenerator start-up and shut-down.

A very fast differential protection function,with automatic CT ratio matching and vectorgroup compensation, makes this IED theideal solution even for the most demandingapplications. Since RET670 has very lowrequirements on the main CTs, nointerposing CTs are required.It is suitable fordifferential applications with multi-breakerarrangements with up to six restraint CTinputs. The differential protection function isprovided with 2nd harmonic and wave-blockrestraint features to avoid tripping formagnetizing inrush current, and 5th harmonicrestraint to avoid tripping for overexcitation.

The differential function offers a highsensitivity for low-level internal faults. Theunique and innovative sensitive differentialprotection feature of the RET670 provides thebest possible coverage for winding internalturn-to-turn faults, based on well-knowntheory of symmetrical components .

Low impedance restricted earth-faultprotection functions are available ascomplimentary sensitive and fast mainprotection against winding earth faults. Thisfunction includes a directional zero-sequencecurrent criterion for additional security.

Additionally a high impedance differentialfunction is available. It can be used asrestricted earth fault or, as three functions areincluded, also as differential protection onautotransformers, as differential protectionfor a tertiary connected reactor, as T-differential protection for the transformer

feeder in a mesh-corner or ring arrangement,as tertiary bus protection and so on.

Tripping from Pressure relief/Buchholz andtemperature devices can be done through thetransformer IED where pulsing, lock-outcontact output and so on, is performed. Thebinary inputs are heavily stabilized againstdisturbance to prevent incorrect operations atfor example, dc system capacitive dischargesor DC earth faults.

Distance protection functionality for phase-to-phase and/or phase-to-earth faults is availableas back-up protection for faults within thetransformer and in the connected powersystem.

Versatile phase, earth, positive, negative andzero sequence overcurrent functions, whichcan optionally be made directional and/orvoltage controlled, provide further alternativebackup protection. Thermal overload withtwo time-constants, volts per hertz, over/under voltage and over/under frequencyprotection functions are also available.

A built-in disturbance and event recorderprovides valuable data to the user aboutstatus and operation for post-faultdisturbance analysis.

Breaker failure protection for eachtransformer breaker allows high speed back-up tripping of surrounding breakers.

The transformer IED can also be providedwith a full control and interlockingfunctionality including Synchrocheck functionto allow integration of the main and/or alocal back-up control.

Out of Step function is available to separatepower system sections close to electricalcentre at occurring out of step.

The advanced logic capability, where userlogic is prepared with a graphical tool, allowsspecial applications such as automaticopening of disconnectors in multi-breakerarrangements, closing of breaker rings, loadtransfer logic and so on. The graphicalconfiguration tool ensures simple and fasttesting and commissioning.


Revision: B

ABB 3

Serial data communication is via opticalconnections to ensure immunity againstdisturbances.

The wide application flexibility makes thisproduct an excellent choice for both new

installations and the refurbishment of existinginstallations.


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2. Available functions

Main protection functions

2 = number of basic instances

0-3 = option quantities


ABB 5

IEC 61850 ANSI Function description Transformer

RET670

Differential protection

T2WPDIF 87T Transformer differential protection, two winding 1-2

T3WPDIF 87T Transformer differential protection, three winding 1-2

HZPDIF 87 1Ph high impedance differential protection 0-6

REFPDIF 87N Restricted earth fault protection, low impedance 0-3

Impedance protection

ZMQPDIS,ZMQAPDIS

21 Distance protection zone, quadrilateralcharacteristic

0-5

ZDRDIR 21D Directional impedance quadrilateral 0-2

ZMCPDIS,ZMCAPDIS

21 Distance characteristic for series compensated lines 0-5

ZDSRDIR 21D Directional impedance quadrilateral, includingseries compensation

0-2

FDPSPDIS 21 Phase selection, quadrilateral characteristic withfixed angle

0-2

ZMHPDIS 21 Full-scheme distance protection, mho characteristic 0-5

ZMMPDIS,ZMMAPDIS

21 Full-scheme distance protection, quadrilaterial forearth faults

0-5

ZDMRDIR 21D Directional impedance element for mhocharacteristic

0-2

ZDARDIR Additional distance protection directional functionfor earth fault

0-1

ZSMGAPC Mho impedance supervision logic 0-1

FMPSPDIS 21 Faulty phase identification with loadenchroachment

0-2

ZMRPDIS,ZMRAPDIS

21 Distance protection zone, quadrilateralcharacteristic, separate settings

0-5

FRPSPDIS 21 Phase selection, quadrilateral characteristic withsettable angle

0-2

ZMRPSB 78 Power swing detection 0-1

ZMRPSL Power swing logic 0-1

PSPPPAM 78 Pole slip/out-of-step protection 0-1

PPLPHIZ Phase preference logic 0-1


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Back-up protection functions


RET670

Current protection

PHPIOC 50 Instantaneous phase overcurrent protection 0-8

OC4PTOC 51_67 Four step phase overcurrent protection 0-8

EFPIOC 50N Instantaneous residual overcurrent protection 0-8

EF4PTOC 51N_67N

Four step residual overcurrent protection 0-8

NS4PTOC 46I2 Four step directional negative phase sequenceovercurrent protection

0-8

SDEPSDE 67N Sensitive directional residual overcurrent andpower protection

0-3

LPTTR 26 Thermal overload protection, one time constant 0-2

TRPTTR 49 Thermal overload protection, two time constant 0-6

CCRBRF 50BF Breaker failure protection 0-6

CCRPLD 52PD Pole discordance protection 0-2

GUPPDUP 37 Directional underpower protection 0-2

GOPPDOP 32 Directional overpower protection 0-2

BRCPTOC 46 Broken conductor check 1

CBPGAPC Capacitor bank protection 0-6

NS2PTOC 46I2 Negative sequence time overcurrent protectionfor machines

0-2

Voltage protection

UV2PTUV 27 Two step undervoltage protection 0-3

OV2PTOV 59 Two step overvoltage protection 0-3

ROV2PTOV 59N Two step residual overvoltage protection 0-3

OEXPVPH 24 Overexcitation protection 0-2

VDCPTOV 60 Voltage differential protection 0-2

LOVPTUV 27 Loss of voltage check 1

Frequency protection

SAPTUF 81 Underfrequency protection 0-6

SAPTOP 81 Overfrequency protection 0-6


ABB 7


RET670

SAPFRC 81 Rate-of-change frequency protection 0-6

Multipurpose protection

CVGAPC General current and voltage protection 0-12


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Control and monitoring functions


RET670

Control

SESRSYN 25 Synchrocheck, energizing check and synchronizing 0-6, 0-5

APC30 3 Apparatus control for up to 6 bays, max 30apparatuses (6CBs) incl. interlocking

0-1

QCBAY Apparatus control 1

LocalRemote

Handling of LRswitch positions 1

LocRemControl

LHMI control of PSTO 1

TR1ATCC 90 Automatic voltage control for tap changer, singlecontrol

0-4

TR8ATCC 90 Automatic voltage control for tap changer, parallelcontrol

0-4

TCMYLTC 84 Tap changer control and supervision, 6 binaryinputs

0-4

TCLYLTC 84 Tap changer control and supervision, 32 binaryinputs

0-4

SLGGIO Logic rotating switch for function selection andLHMI presentation

15

VSGGIO Selector mini switch 20

DPGGIO IEC61850 generic communication I/O functions 16

SPC8GGIO Single pole generic control 8 signals 5

AutomationBits

AutomationBits, command function for DNP3.0 3

Single command, 16 signals 4

VCTRSend Horizonal communication via GOOSE for VCTR 1

VCTRReceive

Horizontal communication via GOOSE for VCTR 7

Secondary system supervision

CCSRDIF 87 Current circuit supervision 0-5

SDDRFUF Fuse failure supervision 0-4

Logic


ABB 9


RET670

SMPPTRC 94 Tripping logic 1-6

TMAGGIO Trip matrix logic 12

Configuration logic blocks 40-280

Fixed signal function blocks 1

B16I Boolean 16 to Integer conversion 16

B16IFCVI Boolean 16 to Integer conversion with Logic Noderepresentation

16

IB16 Integer to Boolean 16 conversion 16

IB16FVCB Integer to Boolean 16 conversion with Logic Noderepresentation

16

Monitoring

CVMMXN Measurements 6

CNTGGIO Event counter 5

Event Event function 20

DRPRDRE Disturbance report 1

SPGGIO IEC61850 generic communication I/O functions 64

SP16GGIO IEC61850 generic communication I/O functions 16inputs

16

MVGGIO IEC61850 generic communication I/O functions 24

BSStartReport

Logical signal status report 3

RANGE_XP Measured value expander block 66

Metering

PCGGIO Pulse-counter logic 16

ETPMMTR Function for energy calculation and demandhandling

6


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Designed to communicate


RET670

Station communication

SPA communication protocol 1

LON communication protocol 1

IEC60870-5-103 communication protocol 20/1

Operation selection between SPA andIEC60870-5-103 for SLM

1

DNP3.0 for TCP/IP and EIA-485 communicationprotocol

1

DNP3.0 fault records for TCP/IP and EIA-485communication protocol

1

Redundant station bus communicationIEC61850-8-1, PRP

1

Parameter setting function for IEC61850 1

IntlReceive Horizontal communication via GOOSE forinterlocking

59

Goose binary receive 10

Multiple command and transmit 60/10

Ethernet configuration of links 1

DUODRV Duo driver configuration 0-1

Remote communication

Binary signal transfer receive/transmit 6/36

Transmission of analog data from LDCM 1

Receive binary status from remote LDCM 6/3/3

Scheme communication

ECPSCH 85 Scheme communication logic for residualovercurrent protection

0-1

ECRWPSCH 85 Current reversal and weak-end infeed logic forresidual overcurrent protection

0-1


ABB 11

Basic IED functions

IEC 61850 Function description

Basic functions included in all products

IntErrorSig Self supervision with internal event list 1

TIME Time and synchronization error 1

TimeSynch Time synchronization 1

ActiveGroup Parameter setting groups 1

Test Test mode functionality 1

ChangeLock Change lock function 1

TerminalID IED identifiers 1

Productinfo Product information 1

MiscBaseCommon Misc Base Common 1

IEDRuntimeComp IED Runtime Comp 1

RatedFreq Rated system frequency 1

SMBI Signal Matrix for binary inputs 40

SMBO Signal Matrix for binary outputs 40

SMMI Signal Matrix for mA inputs 4

SMAI Signal Matrix for analog inputs 36

Sum3Ph Summation block 3 phase 18

LocalHMI Parameter setting function for HMI in PCM600 1

LocalHMI Local HMI signals 1

AuthStatus Authority status 1

AuthorityCheck Authority check 1

AccessFTP FTP access with password 1

SPACommMap SPA communication mapping 1

DOSFRNT Denial of service, frame rate control for front port 1

DOSOEMAB Denial of service, frame rate control for OEM port AB 1

DOSOEMCD Denial of service, frame rate control for OEM port CD 1


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3. Differential protection

Transformer differential protectionT2WPDIF/T3WPDIF

The Transformer differential protection, two-winding (T2WPDIF) and Transformerdifferential protection, three-winding(T3WPDIF) are provided with internal CTratio matching and vector groupcompensation and settable zero sequencecurrent elimination.

The function can be provided with up tothree-phase sets of current inputs. All currentinputs are provided with percentage biasrestraint features, making the IED suitable fortwo- or three-winding transformer in multi-breaker station arrangements.

Two-winding applications

xx05000048.vsd

IEC05000048 V1 EN

two-windingpowertransformer

xx05000049.vsd

IEC05000049 V1 EN

two-windingpowertransformer withunconnecteddelta tertiarywinding

xx05000050.vsd

IEC05000050 V1 EN

two-windingpowertransformer withtwo circuitbreakers on oneside

xx05000051.vsd

IEC05000051 V1 EN

two-windingpowertransformer withtwo circuitbreakers and twoCT-sets on bothsides

Three-winding applications

xx05000052.vsd

IEC05000052 V1 EN

three-windingpowertransformer withall threewindingsconnected


ABB 13

xx05000053.vsd

IEC05000053 V1 EN

three-windingpowertransformer withtwo circuitbreakers and twoCT-sets on oneside

xx05000057.vsd

IEC05000057 V1 EN

Autotransformerwith two circuitbreakers and twoCT-sets on twoout of three sides

Figure 1. CT group arrangement fordifferential protection andother protections

The setting facilities cover the applications ofthe differential protection to all types ofpower transformers and auto-transformerswith or without load tap changer as well asfor shunt reactors or and local feeders withinthe station. An adaptive stabilizing feature isincluded for heavy through-faults.Byintroducing the load tap changer position, thedifferential protection pick-up can be set tooptimum sensitivity thus covering internalfaults with low fault level.

Stabilization is included for inrush currents aswell as for overexcitation conditions.Adaptive stabilization is also included forsystem recovery inrush and CT saturation forexternal faults. A high set unrestraineddifferential current protection is included fora very high speed tripping at a high internalfault currents.

An innovative sensitive differential protectionfeature, based on the theory of symmetricalcomponents, offers the best possiblecoverage for power transformer winding turn-to-turn faults.

1Ph High impedance differentialprotection HZPDIF

The 1Ph High impedance differentialprotection (HZPDIF) function can be usedwhen the involved CT cores have the sameturns ratio and similar magnetizingcharacteristics. It utilizes an external CTcurrent summation by wiring, a seriesresistor, and a voltage dependent resistorwhich are mounted externally connected tothe IED.

HZPDIF can be used to protect tee-feeders orbusbars. Six single phase function blocks areavailable to allow application for two three-phase zones busbar protection.

Restricted earth fault protection,low impedance REFPDIF

Restricted earth-fault protection, low-impedance function (REFPDIF) can be usedon all directly or low-impedance earthedwindings. The REFPDIF function provideshigh sensitivity (down to 5%) and high speedtripping as it measures each windingindividually and thus does not need inrushstabilization.

The low-impedance function is a percentagebiased function with an additional zerosequence current directional comparisoncriterion. This gives excellent sensitivity andstability during through faults. The functionallows the use of different CT ratios andmagnetizing characteristics on the phase andneutral CT cores and mixing with otherfunctions and protection IEDs on the samecores.

xx05000058.vsd

IEC05000058 V1 EN

Figure 2. Autotransformer low impedanceREFPDIF


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4. Impedance protection

Distance measuring zone,quadrilateral characteristicZMQPDIS, ZMQAPDIS (21)

The line distance protection is a five zone fullscheme protection with three fault loops forphase-to-phase faults and three fault loopsfor phase-to-earth faults for each of theindependent zones. Individual settings foreach zone in resistive and reactive reachgives flexibility for use as back-up protectionfor transformer connected to overhead linesand cables of different types and lengths.

ZMQPDIS together with Phase selection withload encroachment FDPSPDIS hasfunctionality for load encroachment, whichincreases the possibility to detect highresistive faults on heavily loaded lines.

The distance protection zones can operateindependently of each other in directional(forward or reverse) or non-directional mode.

Distance measuring zone,quadrilateral characteristic forseries compensated lines ZMCPDIS,ZMCAPDIS

The line distance protection is a five zone fullscheme protection with three fault loops forphase-to-phase faults and three fault loopsfor phase-to-earth fault for each of theindependent zones. Individual settings foreach zone resistive and reactive reach giveflexibility for use on overhead lines andcables of different types and lengths.

Quadrilateral characteristic is available.

ZMCPDIS function has functionality for loadencroachment which increases the possibilityto detect high resistive faults on heavilyloaded lines.

en05000034.vsd

R

X

Forwardoperation

Reverseoperation

IEC05000034 V1 EN

Figure 3. Typical quadrilateral distanceprotection zone with loadencroachment function activated

The distance protection zones can operate,independent of each other, in directional(forward or reverse) or non-directional mode.This makes them suitable, together withdifferent communication schemes, for theprotection of power lines and cables incomplex network configurations, such asparallel lines, multi-terminal lines.

Phase selection, quadrilateralcharacteristic with fixed angleFDPSPDIS

The operation of transmission networkstoday is in many cases close to the stabilitylimit. Due to environmental considerations,the rate of expansion and reinforcement ofthe power system is reduced, for example,difficulties to get permission to build newpower lines. The ability to accurately andreliably classify the different types of fault, sothat single pole tripping and autoreclosingcan be used plays an important role in thismatter.Phase selection, quadrilateralcharacteristic with fixed angle FDPSPDIS isdesigned to accurately select the proper faultloop in the distance function dependent onthe fault type.


ABB 15

The heavy load transfer that is common inmany transmission networks may make faultresistance coverage difficult to achieve.Therefore, FDPSPDIS has a built-in algorithmfor load encroachment, which gives thepossibility to enlarge the resistive setting ofboth the phase selection and the measuringzones without interfering with the load.

The extensive output signals from the phaseselection gives also important informationabout faulty phase(s), which can be used forfault analysis.

A current-based phase selection is alsoincluded. The measuring elementscontinuously measure three phase currentsand the residual current and, compare themwith the set values.

Full-scheme distance measuring,Mho characteristic ZMHPDIS

The numerical mho line distance protection isa five zone full scheme protection for back-up detection of short circuit and earth faults.The full scheme technique provides back-upprotection of power lines with highsensitivity and low requirement on remoteend communication. The five zones havefully independent measuring and settings,which gives high flexibility for all types oflines.

The function can be used as underimpedance back-up protection fortransformers and generators.

Full-scheme distance protection,quadrilateral for earth faultsZMMPDIS, ZMMAPDIS

The distance protection is a five zoneprotection with three fault loops for phase-to-earth fault for each of the independent zones.Individual settings for each zone resistive andreactive reach give flexibility for use onoverhead lines and cables of different typesand lengths.

The Full-scheme distance protection,quadrilateral for earth faults functionsZMMDPIS and ZMMAPDIS have functionality

for load encroachment, which increases thepossibility to detect high resistive faults onheavily loaded lines .

The independent measurement of impedancefor each fault loop together with a sensitiveand reliable built in phase selection makesthe function suitable in applications withsingle phase auto-reclosing.

The distance protection zones can operate,independent of each other, in directional(forward or reverse) or non-directional mode.This makes them suitable, together withdifferent communication schemes, for theprotection of power lines and cables incomplex network configurations, such asparallel lines, multi-terminal lines.

Directional impedance element forMho characteristic ZDMRDIR

The phase-to-earth impedance elements canbe optionally supervised by a phaseunselective directional function (phaseunselective, because it is based onsymmetrical components).

Mho impedance supervision logicZSMGAPC

The Mho impedance supervision logic(ZSMGAPC) includes features for faultinception detection and high SIR detection. Italso includes the functionality for loss ofpotential logic as well as for the pilot channelblocking scheme.

ZSMGAPC can mainly be decomposed in twodifferent parts:

1. A fault inception detection logic2. High SIR detection logic

Faulty phase identification withload encroachment FMPSPDIS

The operation of transmission networkstoday is in many cases close to the stabilitylimit. Due to environmental considerationsthe rate of expansion and reinforcement ofthe power system is reduced, for exampledifficulties to get permission to build newpower lines. The ability to accurate and


16 ABB

reliable classifying the different types of faultso that single phase tripping andautoreclosing can be used plays an importantroll in this matter.

The phase selection function is design toaccurately select the proper fault loop(s) inthe distance function dependent on the faulttype.

The heavy load transfer that is common inmany transmission networks may in somecases interfere with the distance protectionzone reach and cause unwanted operation.Therefore the function has a built inalgorithm for load encroachment, which givesthe possibility to enlarge the resistive settingof the measuring zones without interferingwith the load.

The output signals from the phase selectionfunction produce important informationabout faulty phase(s), which can be used forfault analysis as well.

Distance protection zone,quadrilateral characteristic,separate settings ZMRPDIS,ZMRAPDIS

The line distance protection is up to five zonefull scheme protection with three fault loopsfor phase-to-phase faults and three faultloops for phase-to-earth fault for each of theindependent zones. Individual settings foreach zone in resistive and reactive reachgives flexibility for use as back-up protectionfor transformer connected to overhead linesand cables of different types and lengths.

Mho alternative quadrilateral characteristic isavailable.

ZMRPDIS together with Phase selection,quadrilateral characteristic with settable angleFRPSPDIS has functionality for loadencroachment, which increases the possibilityto detect high resistive faults on heavilyloaded lines.

The distance protection zones can operate,independent of each other, in directional(forward or reverse) or non-directional mode.

Phase selection, quadrilateralcharacteristic with settable angleFRPSPDIS

The operation of transmission networkstoday is in many cases close to the stabilitylimit. Due to environmental considerations,the rate of expansion and reinforcement ofthe power system is reduced for example,difficulties to get permission to build newpower lines. The ability to accurately andreliably classify the different types of fault, sothat single pole tripping and autoreclosingcan be used plays an important role in thismatter. The phase selection function isdesigned to accurately select the proper faultloop in the distance function dependent onthe fault type.

The heavy load transfer that is common inmany transmission networks may make faultresistance coverage difficult to achieve.Therefore, the function has a built inalgorithm for load encroachment, which givesthe possibility to enlarge the resistive settingof both the phase selection and themeasuring zones without interfering with theload.

The extensive output signals from the phaseselection gives also important informationabout faulty phase(s) which can be used forfault analysis.

A current-based phase selection is alsoincluded. The measuring elementscontinuously measure three phase currentsand the residual current and, compare themwith the set values.

Power swing detection ZMRPSB

Power swings may occur after disconnectionof heavy loads or trip of big generation plants.

Power swing detection function (ZMRPSB) isused to detect power swings and initiateblock of selected distance protection zones.Occurrence of earth-fault currents during apower swing inhibits the ZMRPSB function toallow fault clearance.


ABB 17

Power swing logic ZMRPSL

Additional logic is available to secure trippingfor faults during power swings and preventtripping at power swings started by a fault inthe network.

Pole slip protection PSPPPAM

Sudden events in an electrical power systemsuch as large changes in load, faultoccurrence or fault clearance, can causepower oscillations referred to as powerswings. In a non-recoverable situation, thepower swings become so severe that thesynchronism is lost, a condition referred to aspole slipping. The main purpose of the poleslip protection (PSPPPAM) is to detect,evaluate, and take the required action forpole slipping occurrences in the powersystem. The electrical system parts swingingto each other can be separated with the line/sclosest to the centre of the power swingallowing the two systems to be stable asseparated islands.

Phase preference logic PPLPHIZ

The optional phase preference logic mainpurpose is to provide a selective tripping forcross-country faults in isolated or highimpedance-earthed networks.

5. Current protection

Instantaneous phase overcurrentprotection PHPIOC

The instantaneous three phase overcurrentfunction has a low transient overreach andshort tripping time to allow use as a high setshort-circuit protection function.

Four step phase overcurrentprotection OC4PTOC

The four step phase overcurrent protectionfunction OC4PTOC has an inverse or definitetime delay independent for step 1 and 4

separately. Step 2 and 3 are always definitetime delayed.

All IEC and ANSI inverse time characteristicsare available together with an optional userdefined time characteristic.

The directional function is voltage polarizedwith memory. The function can be set to bedirectional or non-directional independentlyfor each of the steps.

A 2nd harmonic blocking can be setindividually for each step.

Instantaneous residual overcurrentprotection EFPIOC

The Instantaneous residual overcurrentprotection EFPIOC has a low transientoverreach and short tripping times to allowuse for instantaneous earth-fault protection,with the reach limited to less than typicaleighty percent of the transformer impedanceat minimum source impedance. EFPIOC canbe configured to measure the residual currentfrom the three-phase current inputs or thecurrent from a separate current input.EFPIOC can be blocked by activating theinput BLOCK.

Four step residual overcurrentprotection EF4PTOC

The four step residual overcurrent protectionEF4PTOC has an inverse or definite timedelay independent for each step separately.

All IEC and ANSI time-delayed characteristicsare available together with an optional userdefined characteristic.

The directional function includes 3 options

• voltage polarized• current polarized• dual polarized

EF4PTOC can be set directional or non-directional independently for each of the steps.

Second harmonic blocking can be setindividually for each step.

EF4PTOC can be configured to measure theresidual current from the three-phase current


18 ABB

inputs or the current from a separate currentinput.

Four step negative sequenceovercurrent protection NS4PTOC

Four step negative sequence overcurrentprotection (NS4PTOC) has an inverse ordefinite time delay independent for each stepseparately.

All IEC and ANSI time delayed characteristicsare available together with an optional userdefined characteristic.

The directional function is voltage polarizedor dual polarized.

NS4PTOC can be set directional or non-directional independently for each of the steps.

Sensitive directional residualovercurrent and power protectionSDEPSDE

In isolated networks or in networks withhigh impedance earthing, the earth faultcurrent is significantly smaller than the shortcircuit currents. In addition to this, themagnitude of the fault current is almostindependent on the fault location in thenetwork. The protection can be selected touse either the residual current or residualpower component 3U0·3I0·cos j, foroperating quantity with maintained shortcircuit capacity. There is also available onenondirectional 3I0 step and one 3U0overvoltage tripping step.

Thermal overload protection, onetime constant LPTTR

The increasing utilizing of the power systemcloser to the thermal limits has generated aneed of a thermal overload protection alsofor power lines.

A thermal overload will often not be detectedby other protection functions and theintroduction of the thermal overloadprotection can allow the protected circuit tooperate closer to the thermal limits.

The three-phase current measuring protection

has an I2t characteristic with settable timeconstant and a thermal memory.

An alarm level gives early warning to allowoperators to take action well before the lineis tripped.

Thermal overload protection, twotime constant TRPTTR

If a power transformer or generator reachesvery high temperatures the equipment mightbe damaged. The insulation within thetransformer/generator will have forcedageing. As a consequence of this the risk ofinternal phase-to-phase or phase-to-earthfaults will increase. High temperature willdegrade the quality of the transformer/generator insulation.

The thermal overload protection estimatesthe internal heat content of the transformer/generator (temperature) continuously. Thisestimation is made by using a thermal modelof the transformer/generator with two timeconstants, which is based on currentmeasurement.

Two warning levels are available. Thisenables actions in the power system to bedone before dangerous temperatures arereached. If the temperature continues toincrease to the trip value, the protectioninitiates a trip of the protected transformer/generator.

Breaker failure protection CCRBRF

Breaker failure protection (CCRBRF) ensuresfast back-up tripping of surrounding breakersin case the own breaker fails to open.CCRBRF can be current based, contact based,or an adaptive combination of these twoconditions.

Current check with extremely short reset timeis used as check criterion to achieve highsecurity against unnecessary operation.

Contact check criteria can be used where thefault current through the breaker is small.

CCRBRF can be single- or three-phaseinitiated to allow use with single phase


ABB 19

tripping applications. For the three-phaseversion of CCRBRF the current criteria can beset to operate only if two out of four forexample, two phases or one phase plus theresidual current start. This gives a highersecurity to the back-up trip command.

CCRBRF function can be programmed to givea single- or three-phase re-trip of the ownbreaker to avoid unnecessary tripping ofsurrounding breakers at an incorrectinitiation due to mistakes during testing.

Pole discordance protectionCCRPLD

An open phase can cause negative and zerosequence currents which cause thermal stresson rotating machines and can causeunwanted operation of zero sequence ornegative sequence current functions.

Normally the own breaker is tripped tocorrect such a situation. If the situationpersists the surrounding breakers should betripped to clear the unsymmetrical loadsituation.

The Polediscordance protection functionCCRPLD operates based on information fromauxiliary contacts of the circuit breaker forthe three phases with additional criteria fromunsymmetrical phase currents when required.

Directional over/underpowerprotection GOPPDOP/GUPPDUP

The directional over-/under-power protectionGOPPDOP/GUPPDUP can be used wherevera high/low active, reactive or apparent powerprotection or alarming is required. Thefunctions can alternatively be used to checkthe direction of active or reactive power flowin the power system. There are a number ofapplications where such functionality isneeded. Some of them are:

• detection of reversed active power flow• detection of high reactive power flow

Each function has two steps with definitetime delay. Reset times for both steps can beset as well.

Broken conductor check BRCPTOC

The main purpose of the function Brokenconductor check (BRCPTOC) is the detectionof broken conductors on protected powerlines and cables (series faults). Detection canbe used to give alarm only or trip the linebreaker.

Capacitor bank protection(CBPGAPC)

Shunt Capacitor Banks (SCB) are used in apower system to provide reactive powercompensation and power factor correction.They are as well used as integral parts ofStatic Var Compensators (SVC) or HarmonicFilters installations. Capacitor bank protection(CBPGAPC) function is specially designed toprovide protection and supervision featuresfor SCBs.

Negative sequence time overcurrentprotection for machines NS2PTOC

Negative-sequence time overcurrentprotection for machines NS2PTOC is intendedprimarily for the protection of generatorsagainst possible overheating of the rotorcaused by negative sequence component inthe stator current.

The negative sequence currents in agenerator may, among others, be caused by:

• Unbalanced loads• Line to line faults• Line to earth faults• Broken conductors• Malfunction of one or more poles of a

circuit breaker or a disconnector

NS2PTOC can also be used as a backupprotection, that is, to protect the generator incase line protections or circuit breakers fail toclear unbalanced system faults.

To provide an effective protection for thegenerator for external unbalanced conditions,NS2PTOC is able to directly measure thenegative sequence current. NS2PTOC also hasa time delay characteristic which matches the


20 ABB

heating characteristic of the generator

22I t K= as defined in standard IEEE C50.13.

where:

I2 is negative sequence currentexpressed in per unit of the ratedgenerator current

t is operating time in seconds

K is a constant which depends of thegenerators size and design

NS2PTOC has a wide range of K settings andthe sensitivity and capability of detecting andtripping for negative sequence currents downto the continuous capability of a generator.

A separate output is available as an alarmfeature to warn the operator of a potentiallydangerous situation.

6. Voltage protection

Two step undervoltage protectionUV2PTUV

Undervoltages can occur in the power systemduring faults or abnormal conditions. Twostep undervoltage protection (UV2PTUV)function can be used to open circuit breakersto prepare for system restoration at poweroutages or as long-time delayed back-up toprimary protection.

UV2PTUV has two voltage steps, each withinverse or definite time delay.

Two step overvoltage protectionOV2PTOV

Overvoltages may occur in the power systemduring abnormal conditions such as suddenpower loss, tap changer regulating failures,open line ends on long lines etc.

Two step overvoltage protection (OV2PTOV)function can be used to detect open lineends, normally then combined with adirectional reactive over-power function tosupervise the system voltage. When triggered,

the function will cause an alarm, switch inreactors, or switch out capacitor banks.

OV2PTOV has two voltage steps, each ofthem with inverse or definite time delayed.

OV2PTOV has an extremely high reset ratioto allow settings close to system servicevoltage.

Two step residual overvoltageprotection ROV2PTOV

Residual voltages may occur in the powersystem during earth faults.

Two step residual overvoltage protectionROV2PTOV function calculates the residualvoltage from the three-phase voltage inputtransformers or measures it from a singlevoltage input transformer fed from an opendelta or neutral point voltage transformer.

ROV2PTOV has two voltage steps, each withinverse or definite time delay.

Reset delay ensures operation for intermittentearth faults.

Overexcitation protectionOEXPVPH

When the laminated core of a powertransformer or generator is subjected to amagnetic flux density beyond its designlimits, stray flux will flow into non-laminatedcomponents not designed to carry flux andcause eddy currents to flow. The eddycurrents can cause excessive heating andsevere damage to insulation and adjacentparts in a relatively short time. The functionhas settable inverse operating curves andindependent alarm stages.

Voltage differential protectionVDCPTOV

A voltage differential monitoring function isavailable. It compares the voltages from twothree phase sets of voltage transformers andhas one sensitive alarm step and one trip step.

Loss of voltage check LOVPTUV

Loss of voltage check (LOVPTUV) is suitablefor use in networks with an automatic system


ABB 21

restoration function. LOVPTUV issues a three-pole trip command to the circuit breaker, ifall three phase voltages fall below the setvalue for a time longer than the set time andthe circuit breaker remains closed.

7. Frequency protection

Underfrequency protection SAPTUF

Underfrequency occurs as a result of lack ofgeneration in the network.

Underfrequency protection SAPTUF is usedfor load shedding systems, remedial actionschemes, gas turbine startup and so on.

SAPTUF is provided with an undervoltageblocking.

The operation is based on positive sequencevoltage measurement and requires two phase-phase or three phase-neutral voltages to beconnected. For information about how toconnect analog inputs, refer to Applicationmanual/IED application/Analog inputs/Setting guidelines

Overfrequency protection SAPTOF

Overfrequency protection function SAPTOF isapplicable in all situations, where reliabledetection of high fundamental power systemfrequency is needed.

Overfrequency occurs at sudden load dropsor shunt faults in the power network. Closeto the generating plant, generator governorproblems can also cause over frequency.

SAPTOF is used mainly for generationshedding and remedial action schemes. It isalso used as a frequency stage initiating loadrestoring.

SAPTOF is provided with an undervoltageblocking.

The operation is based on positive sequencevoltage measurement and requires two phase-phase or three phase-neutral voltages to beconnected. For information about how to

connect analog inputs, refer to Applicationmanual/IED application/Analog inputs/Setting guidelines

Rate-of-change frequencyprotection SAPFRC

Rate-of-change frequency protection function(SAPFRC) gives an early indication of a maindisturbance in the system. SAPFRC can beused for generation shedding, load sheddingand remedial action schemes. SAPFRC candiscriminate between positive or negativechange of frequency.

SAPFRC is provided with an undervoltageblocking. The operation is based on positivesequence voltage measurement and requirestwo phase-phase or three phase-neutralvoltages to be connected. For informationabout how to connect analog inputs, refer toApplication manual/IED application/Analog inputs/Setting guidelines.

8. Multipurposeprotection

General current and voltageprotection CVGAPC

The protection module is recommended as ageneral backup protection with manypossible application areas due to its flexiblemeasuring and setting facilities.

The built-in overcurrent protection featurehas two settable current levels. Both of themcan be used either with definite time orinverse time characteristic. The overcurrentprotection steps can be made directional withselectable voltage polarizing quantity.Additionally they can be voltage and/orcurrent controlled/restrained. 2nd harmonicrestraining facility is available as well. At toolow polarizing voltage the overcurrent featurecan be either blocked, made non directionalor ordered to use voltage memory inaccordance with a parameter setting.


22 ABB

Additionally two overvoltage and twoundervoltage steps, either with definite timeor inverse time characteristic, are availablewithin each function.

The general function suits applications withunderimpedance and voltage controlledovercurrent solutions. The general functioncan also be utilized for generator transformerprotection applications where positive,negative or zero sequence components ofcurrent and voltage quantities are typicallyrequired.

9. Secondary systemsupervision

Current circuit supervisionCCSRDIF

Open or short circuited current transformercores can cause unwanted operation of manyprotection functions such as differential,earth-fault current and negative-sequencecurrent functions.

It must be remembered that a blocking ofprotection functions at an occurrence of openCT circuit will mean that the situation willremain and extremely high voltages willstress the secondary circuit.

Current circuit supervision (CCSRDIF)compares the residual current from a threephase set of current transformer cores withthe neutral point current on a separate inputtaken from another set of cores on thecurrent transformer.

A detection of a difference indicates a fault inthe circuit and is used as alarm or to blockprotection functions expected to giveunwanted tripping.

Fuse failure supervision SDDRFUF

The aim of the fuse failure supervisionfunction (SDDRFUF) is to block voltagemeasuring functions at failures in thesecondary circuits between the voltage

transformer and the IED in order to avoidunwanted operations that otherwise mightoccur.

The fuse failure supervision function basicallyhas three different algorithms, negativesequence and zero sequence basedalgorithms and an additional delta voltageand delta current algorithm.

The negative sequence detection algorithm isrecommended for IEDs used in isolated orhigh-impedance earthed networks. It is basedon the negative-sequence measuringquantities, a high value of voltage 3U2

without the presence of the negative-sequence current 3I2.

The zero sequence detection algorithm isrecommended for IEDs used in directly orlow impedance earthed networks. It is basedon the zero sequence measuring quantities, ahigh value of voltage 3U0 without the

presence of the residual current 3I0.

For better adaptation to system requirements,an operation mode setting has beenintroduced which makes it possible to selectthe operating conditions for negativesequence and zero sequence based function.The selection of different operation modesmakes it possible to choose differentinteraction possibilities between the negativesequence and zero sequence based algorithm.

A criterion based on delta current and deltavoltage measurements can be added to thefuse failure supervision function in order todetect a three phase fuse failure, which inpractice is more associated with voltagetransformer switching during stationoperations.

10. Control

Synchrocheck, energizing check,and synchronizing SESRSYN

The Synchronizing function allows closing ofasynchronous networks at the correct


ABB 23

moment including the breaker closing time,which improves the network stability.

Synchrocheck, energizing check, andsynchronizing (SESRSYN) function checksthat the voltages on both sides of the circuitbreaker are in synchronism, or with at leastone side dead to ensure that closing can bedone safely.

SESRSYN function includes a built-in voltageselection scheme for double bus and 1½breaker or ring busbar arrangements.

Manual closing as well as automatic reclosingcan be checked by the function and can havedifferent settings.

For systems which are running asynchronousa synchronizing function is provided. Themain purpose of the synchronizing functionis to provide controlled closing of circuitbreakers when two asynchronous systems aregoing to be connected. It is used for slipfrequencies that are larger than those forsynchrocheck and lower than a set maximumlevel for the synchronizing function.

Apparatus control APC

The apparatus control functions are used forcontrol and supervision of circuit breakers,disconnectors and earthing switches within abay. Permission to operate is given afterevaluation of conditions from other functionssuch as interlocking, synchrocheck, operatorplace selection and external or internalblockings.

Apparatus control features:

• Select-Execute principle to give highreliability

• Selection function to prevent simultaneousoperation

• Selection and supervision of operator place• Command supervision• Block/deblock of operation• Block/deblock of updating of position

indications• Substitution of position indications• Overriding of interlocking functions

• Overriding of synchrocheck• Operation counter• Suppression of Mid position

Two types of command models can be used:

• Direct with normal security• SBO (Select-Before-Operate) with enhanced

security

In normal security, the command isprocessed and the resulting position is notsupervised. However with enhanced security,the command is processed and the resultingposition is supervised.

Normal security means that only thecommand is evaluated and the resultingposition is not supervised. Enhanced securitymeans that the command is evaluated with anadditional supervision of the status value ofthe control object. The command securitywith enhanced security is always terminatedby a CommandTermination service primitive.

Control operation can be performed from thelocal HMI under authority control if so defined.

Voltage control TR1ATCC,TR8ATCC, TCMYLTC and TCLYLTC

The voltage control functions, Automaticvoltage control for tap changer, single controlTR1ATCC, Automatic voltage control for tapchanger , parallel control TR8ATCC and Tapchanger control and supervision, 6 binaryinputs TCMYLTC as well as Tap changercontrol and supervision, 32 binary inputsTCLYLTC are used for control of powertransformers with a motor driven load tapchanger. The functions provide automaticregulation of the voltage on the secondaryside of transformers or alternatively on a loadpoint further out in the network.

Control of a single transformer, as well ascontrol of up to eight transformers in parallelis possible. For parallel control of powertransformers, three alternative methods areavailable, the master-follower method, thecirculating current method and the reversereactance method. The two former methodsrequire exchange of information between the


24 ABB

parallel transformers and this is provided forwithin IEC61850-8-1.

Voltage control includes many extra featuressuch as possibility of to avoid simultaneoustapping of parallel transformers, hot stand byregulation of a transformer in a group whichregulates it to a correct tap position eventhough the LV CB is open, compensation fora possible capacitor bank on the LV side bayof a transformer, extensive tap changermonitoring including contact wear andhunting detection, monitoring of the powerflow in the transformer so that for example,the voltage control can be blocked if thepower reverses etc.

Logic rotating switch for functionselection and LHMI presentationSLGGIO

The logic rotating switch for functionselection and LHMI presentation function(SLGGIO) (or the selector switch functionblock) is used to get a selector switchfunctionality similar to the one provided by ahardware selector switch. Hardware selectorswitches are used extensively by utilities, inorder to have different functions operating onpre-set values. Hardware switches arehowever sources for maintenance issues,lower system reliability and an extendedpurchase portfolio. The logic selectorswitches eliminate all these problems.

Selector mini switch VSGGIO

The Selector mini switch VSGGIO functionblock is a multipurpose function used for avariety of applications, as a general purposeswitch.

VSGGIO can be controlled from the menu orfrom a symbol on the single line diagram(SLD) on the local HMI.

Single point generic control 8signals SPC8GGIO

The Single point generic control 8 signals(SPC8GGIO) function block is a collection of8 single point commands, designed to bringin commands from REMOTE (SCADA) tothose parts of the logic configuration that do

not need extensive command receivingfunctionality (for example, SCSWI). In thisway, simple commands can be sent directlyto the IED outputs, without confirmation.Confirmation (status) of the result of thecommands is supposed to be achieved byother means, such as binary inputs andSPGGIO function blocks. The commands canbe pulsed or steady.

Single command, 16 signals

The IEDs can receive commands either froma substation automation system or from thelocal HMI. The command function block hasoutputs that can be used, for example, tocontrol high voltage apparatuses or for otheruser defined functionality.

11. Schemecommunication

Scheme communication logic forresidual overcurrent protectionECPSCH

To achieve fast fault clearance of earth faultson the part of the line not covered by theinstantaneous step of the residual overcurrentprotection, the directional residualovercurrent protection can be supported witha logic that uses communication channels.

In the directional scheme, information of thefault current direction must be transmitted tothe other line end. With directionalcomparison, a short operate time of theprotection including a channel transmissiontime, can be achieved. This short operatetime enables rapid autoreclosing functionafter the fault clearance.

The communication logic module fordirectional residual current protectionenables blocking as well as permissive under/overreaching schemes. The logic can also besupported by additional logic for weak-endinfeed and current reversal, included inCurrent reversal and weak-end infeed logic


ABB 25

for residual overcurrent protection(ECRWPSCH) function.

Current reversal and weak-endinfeed logic for residualovercurrent protection ECRWPSCH

The Current reversal and weak-end infeedlogic for residual overcurrent protectionECRWPSCH is a supplement to Schemecommunication logic for residual overcurrentprotection ECPSCH.

To achieve fast fault clearing for all earthfaults on the line, the directional earth-faultprotection function can be supported withlogic that uses communication channels.

The 670 series IEDs have for this reasonavailable additions to scheme communicationlogic.

If parallel lines are connected to commonbusbars at both terminals, overreachingpermissive communication schemes can tripunselectively due to fault current reversal.This unwanted tripping affects the healthyline when a fault is cleared on the other line.This lack of security can result in a total lossof interconnection between the two buses. Toavoid this type of disturbance, a fault currentreversal logic (transient blocking logic) canbe used.

Permissive communication schemes forresidual overcurrent protection can basicallyoperate only when the protection in theremote IED can detect the fault. Thedetection requires a sufficient minimumresidual fault current, out from this IED. Thefault current can be too low due to anopened breaker or high-positive and/or zero-sequence source impedance behind this IED.To overcome these conditions, weak-endinfeed (WEI) echo logic is used.

12. Logic

Tripping logic SMPPTRC

A function block for protection tripping isprovided for each circuit breaker involved inthe tripping of the fault. It provides pulseprolongation to ensure a trip pulse ofsufficient length, as well as all functionalitynecessary for correct co-operation withautoreclosing functions.

The trip function block includes functionalityfor evolving faults and breaker lock-out.

Trip matrix logic TMAGGIO

Trip matrix logic TMAGGIO function is usedto route trip signals and other logical outputsignals to different output contacts on the IED.

TMAGGIO output signals and the physicaloutputs allows the user to adapt the signalsto the physical tripping outputs according tothe specific application needs.

Fixed signal function block

The Fixed signals function (FXDSIGN)generates a number of pre-set (fixed) signalsthat can be used in the configuration of anIED, either for forcing the unused inputs inother function blocks to a certain level/value,or for creating certain logic.

13. Monitoring

Measurements CVMMXN, CMMXU,VNMMXU, VMMXU, CMSQI, VMSQI

The measurement functions are used to get on-line information from the IED. These servicevalues make it possible to display on-lineinformation on the local HMI and on theSubstation automation system about:


26 ABB

• measured voltages, currents, frequency,active, reactive and apparent power andpower factor

• primary and secondary phasors• positive, negative and zero sequence

currents and voltages• mA, input currents• pulse counters

Supervision of mA input signals

The main purpose of the function is tomeasure and process signals from differentmeasuring transducers. Many devices used inprocess control represent various parameterssuch as frequency, temperature and DCbattery voltage as low current values, usuallyin the range 4-20 mA or 0-20 mA.

Alarm limits can be set and used as triggers,e.g. to generate trip or alarm signals.

The function requires that the IED isequipped with the mA input module.

Event counter CNTGGIO

Event counter (CNTGGIO) has six counterswhich are used for storing the number oftimes each counter input has been activated.

Disturbance report DRPRDRE

Complete and reliable information aboutdisturbances in the primary and/or in thesecondary system together with continuousevent-logging is accomplished by thedisturbance report functionality.

Disturbance report DRPRDRE, alwaysincluded in the IED, acquires sampled data ofall selected analog input and binary signalsconnected to the function block with a,maximum of 40 analog and 96 binary signals.

The Disturbance report functionality is acommon name for several functions:

• Event list• Indications• Event recorder• Trip value recorder• Disturbance recorder

The Disturbance report function ischaracterized by great flexibility regardingconfiguration, starting conditions, recordingtimes, and large storage capacity.

A disturbance is defined as an activation ofan input to the AxRADR or BxRBDR functionblocks, which are set to trigger thedisturbance recorder. All signals from start ofpre-fault time to the end of post-fault timewill be included in the recording.

Every disturbance report recording is savedin the IED in the standard Comtrade format.The same applies to all events, which arecontinuously saved in a ring-buffer. The localHMI is used to get information about therecordings. The disturbance report files maybe uploaded to PCM600 for further analysisusing the disturbance handling tool.

Event list DRPRDRE

Continuous event-logging is useful formonitoring the system from an overviewperspective and is a complement to specificdisturbance recorder functions.

The event list logs all binary input signalsconnected to the Disturbance report function.The list may contain up to 1000 time-taggedevents stored in a ring-buffer.

Indications DRPRDRE

To get fast, condensed and reliableinformation about disturbances in theprimary and/or in the secondary system it isimportant to know, for example binarysignals that have changed status during adisturbance. This information is used in theshort perspective to get information via thelocal HMI in a straightforward way.

There are three LEDs on the local HMI(green, yellow and red), which will displaystatus information about the IED and theDisturbance report function (trigged).

The Indication list function shows all selectedbinary input signals connected to theDisturbance report function that havechanged status during a disturbance.


ABB 27

Event recorder DRPRDRE

Quick, complete and reliable informationabout disturbances in the primary and/or inthe secondary system is vital, for example,time-tagged events logged duringdisturbances. This information is used fordifferent purposes in the short term (forexample corrective actions) and in the longterm (for example functional analysis).

The event recorder logs all selected binaryinput signals connected to the Disturbancereport function. Each recording can containup to 150 time-tagged events.

The event recorder information is availablefor the disturbances locally in the IED.

The event recording information is anintegrated part of the disturbance record(Comtrade file).

Trip value recorder DRPRDRE

Information about the pre-fault and faultvalues for currents and voltages are vital forthe disturbance evaluation.

The Trip value recorder calculates the valuesof all selected analog input signals connectedto the Disturbance report function. The resultis magnitude and phase angle before andduring the fault for each analog input signal.

The trip value recorder information isavailable for the disturbances locally in theIED.

The trip value recorder information is anintegrated part of the disturbance record(Comtrade file).

Disturbance recorder DRPRDRE

The Disturbance recorder function suppliesfast, complete and reliable information aboutdisturbances in the power system. Itfacilitates understanding system behavior andrelated primary and secondary equipmentduring and after a disturbance. Recordedinformation is used for different purposes inthe short perspective (for example correctiveactions) and long perspective (for examplefunctional analysis).

The Disturbance recorder acquires sampleddata from selected analog- and binary signalsconnected to the Disturbance report function(maximum 40 analog and 96 binary signals).The binary signals available are the same asfor the event recorder function.

The function is characterized by greatflexibility and is not dependent on theoperation of protection functions. It canrecord disturbances not detected byprotection functions. Up to ten seconds ofdata before the trigger instant can be saved inthe disturbance file.

The disturbance recorder information for upto 100 disturbances are saved in the IED andthe local HMI is used to view the list ofrecordings.

Event function

When using a Substation Automation systemwith LON or SPA communication, time-tagged events can be sent at change orcyclically from the IED to the station level.These events are created from any availablesignal in the IED that is connected to theEvent function (EVENT). The event functionblock is used for LON and SPAcommunication.

Analog and double indication values are alsotransferred through EVENT function.

IEC61850 generic communicationI/O function SPGGIO

IEC61850 generic communication I/Ofunctions (SPGGIO) is used to send onesingle logical signal to other systems orequipment in the substation.

IEC61850 generic communicationI/O functions MVGGIO

IEC61850 generic communication I/Ofunctions (MVGGIO) function is used to sendthe instantaneous value of an analog outputto other systems or equipment in thesubstation. It can also be used inside thesame IED, to attach a RANGE aspect to ananalog value and to permit measurementsupervision on that value.


28 ABB

Measured value expander blockRANGE_XP

The current and voltage measurementsfunctions (CVMMXN, CMMXU, VMMXU andVNMMXU), current and voltage sequencemeasurement functions (CMSQI and VMSQI)and IEC 61850 generic communication I/Ofunctions (MVGGIO) are provided withmeasurement supervision functionality. Allmeasured values can be supervised with foursettable limits: low-low limit, low limit, highlimit and high-high limit. The measure valueexpander block (RANGE_XP) has beenintroduced to enable translating the integeroutput signal from the measuring functions to5 binary signals: below low-low limit, belowlow limit, normal, above high-high limit orabove high limit. The output signals can beused as conditions in the configurable logicor for alarming purpose.

14. Metering

Pulse counter logic PCGGIO

Pulse counter (PCGGIO) function countsexternally generated binary pulses, forinstance pulses coming from an externalenergy meter, for calculation of energyconsumption values. The pulses are capturedby the binary input module and then read bythe function. A scaled service value isavailable over the station bus. The specialBinary input module with enhanced pulsecounting capabilities must be ordered toachieve this functionality.

Function for energy calculation anddemand handling ETPMMTR

Outputs from the Measurements (CVMMXN)function can be used to calculate energyconsumption. Active as well as reactivevalues are calculated in import and exportdirection. Values can be read or generated aspulses. Maximum demand power values arealso calculated by the function.

15. Basic IED functions

Time synchronization

The time synchronization source selector isused to select a common source of absolutetime for the IED when it is a part of aprotection system. This makes it possible tocompare event- and disturbance databetween all IEDs in a station automationsystem possible.

16. Human machineinterface

Human machine interface

The local human machine interface isavailable in a small and a medium sizedmodel. The difference between the twomodels is the size of the LCD. The small sizeLCD can display seven lines of text and themedium size LCD can display the single linediagram with up to 15 objects on each page.Up to 12 single line diagram pages can bedefined, depending on the product capability.

The local HMI is divided into zones withdifferent functionality.

• Status indication LEDs.• Alarm indication LEDs, which consist of

15 LEDs (6 red and 9 yellow) with userprintable label. All LEDs are configurablefrom PCM600.

• Liquid crystal display (LCD).• Keypad with push buttons for control

and navigation purposes, switch forselection between local and remotecontrol and reset.

• Isolated RJ45 communication port.


ABB 29

IEC05000055-LITEN V1 EN

Figure 4. Small, alpha numeric HMI

IEC05000056-LITEN V1 EN

Figure 5. Medium graphic HMI, 15controllable objects

17. Stationcommunication

Overview

Each IED is provided with a communicationinterface, enabling it to connect to one ormany substation level systems or equipment,either on the Substation Automation (SA) busor Substation Monitoring (SM) bus.

Following communication protocols areavailable:

• IEC 61850-8-1 communication protocol• LON communication protocol• SPA or IEC 60870-5-103 communication

protocol• DNP3.0 communication protocol

Theoretically, several protocols can becombined in the same IED.

IEC 61850-8-1 communicationprotocol

The IED is equipped with single or doubleoptical Ethernet rear ports (order dependent)for IEC 61850-8-1 station bus communication.The IEC 61850-8-1 communication is alsopossible from the optical Ethernet front port.IEC 61850-8-1 protocol allows intelligentelectrical devices (IEDs) from differentvendors to exchange information andsimplifies system engineering. Peer-to-peercommunication according to GOOSE is partof the standard. Disturbance files uploadingis provided.

Serial communication, LON

Existing stations with ABB station bus LONcan be extended with use of the optical LONinterface. This allows full SA functionalityincluding peer-to-peer messaging andcooperation between existing ABB IED's andthe new IED 670.

SPA communication protocol

A single glass or plastic port is provided forthe ABB SPA protocol. This allows extensions


30 ABB

of simple substation automation systems butthe main use is for Substation MonitoringSystems SMS.

IEC 60870-5-103 communicationprotocol

A single glass or plastic port is provided forthe IEC60870-5-103 standard. This allowsdesign of simple substation automationsystems including equipment from differentvendors. Disturbance files uploading isprovided.

DNP3.0 communication protocol

An electrical RS485 and an optical Ethernetport is available for the DNP3.0communication. DNP3.0 Level 2communication with unsolicited events, timesynchronizing and disturbance reporting isprovided for communication to RTUs,Gateways or HMI systems.

Multiple command and transmit

When 670 IED's are used in SubstationAutomation systems with LON, SPA orIEC60870-5-103 communication protocols theEvent and Multiple Command function blocksare used as the communication interface forvertical communication to station HMI andgateway and as interface for horizontal peer-to-peer communication (over LON only).

Duo driver configuration DUODRV

Redundant station bus communication isused to assure communication, even thoughone communication channels might not beavailable for some reason. Redundantcommunication over station bus running IEC61850-8-1 use both port AB and CD on OEMmodule and IEC 62439-PRP protocol.

18. Remotecommunication

Analog and binary signal transferto remote end

Three analog and eight binary signals can beexchanged between two IEDs. Thisfunctionality is mainly used for the linedifferential protection. However it can beused in other products as well. An IED cancommunicate with up to 4 remote IEDs.

Binary signal transfer to remoteend, 192 signals

If the communication channel is used fortransfer of binary signals only, up to 192binary signals can be exchanged betweentwo IEDs. For example, this functionality canbe used to send information such as status ofprimary switchgear apparatus or intertrippingsignals to the remote IED. An IED cancommunicate with up to 4 remote IEDs.

Line data communication module,short and medium range LDCM

The line data communication module (LDCM)is used for communication between the IEDssituated at distances <60 km or from the IEDto optical to electrical converter with G.703or G.703E1 interface located on a distances<3 km away. The LDCM module sends andreceives data, to and from another LDCMmodule. The IEEE/ANSI C37.94 standardformat is used.

Galvanic interface G.703 resp G.703E1

The external galvanic data communicationconverter G.703/G.703E1 makes an optical-to-galvanic conversion for connection to amultiplexer. These units are designed for 64kbit/s resp 2Mbit/s operation. The converteris delivered with 19” rack mountingaccessories.


ABB 31

19. Hardware description

Hardware modules

Power supply module PSM

The power supply module is used to providethe correct internal voltages and full isolationbetween the terminal and the battery system.An internal fail alarm output is available.

Binary input module BIM

The binary input module has 16 opticallyisolated inputs and is available in twoversions, one standard and one withenhanced pulse counting capabilities on theinputs to be used with the pulse counterfunction. The binary inputs are freelyprogrammable and can be used for the inputof logical signals to any of the functions.They can also be included in the disturbancerecording and event-recording functions. Thisenables extensive monitoring and evaluationof operation of the IED and for all associatedelectrical circuits.

Binary output module BOM

The binary output module has 24independent output relays and is used fortrip output or any signaling purpose.

Static binary output module SOM

The static binary output module has six faststatic outputs and six change over outputrelays for use in applications with high speedrequirements.

Binary input/output module IOM

The binary input/output module is usedwhen only a few input and output channelsare needed. The ten standard output channelsare used for trip output or any signalingpurpose. The two high speed signal outputchannels are used for applications whereshort operating time is essential. Eightoptically isolated binary inputs cater forrequired binary input information.

mA input module MIM

The milli-ampere input module is used tointerface transducer signals in the –20 to +20mA range from for example OLTC position,temperature or pressure transducers. Themodule has six independent, galvanicallyseparated channels.

Optical ethernet module OEM

The optical fast-ethernet module is used toconnect an IED to the communication buses(like the station bus) that use the IEC61850-8-1 protocol (port A, B). The modulehas one or two optical ports with STconnectors.

Serial and LON communication moduleSLM, supports SPA/IEC 60870-5-103, LONand DNP 3.0

The serial and LON communication module(SLM) is used for SPA, IEC 60870-5-103,DNP3 and LON communication. The modulehas two optical communication ports forplastic/plastic, plastic/glass or glass/glass.One port is used for serial communication(SPA, IEC 60870-5-103 and DNP3 port ordedicated IEC 60870-5-103 port depending onordered SLM module) and one port isdedicated for LON communication.

Line data communication module LDCM

Each module has one optical port, one foreach remote end to which the IEDcommunicates.

Alternative cards for Medium range (1310 nmsingle mode) and Short range (850 nm multimode) are available.

Galvanic RS485 serial communicationmodule

The Galvanic RS485 communication module(RS485) is used for DNP3.0 communication.The module has one RS485 communicationport. The RS485 is a balanced serialcommunication that can be used either in 2-wire or 4-wire connections. A 2-wireconnection uses the same signal for RX andTX and is a multidrop communication with


32 ABB

no dedicated Master or slave. This variantrequires however a control of the output. The4-wire connection has separated signals forRX and TX multidrop communication with adedicated Master and the rest are slaves. Nospecial control signal is needed in this case.

GPS time synchronization module GTM

This module includes a GPS receiver used fortime synchronization. The GPS has one SMAcontact for connection to an antenna. It alsoincludes an optical PPS ST-connector output.

IRIG-B Time synchronizing module

The IRIG-B time synchronizing module isused for accurate time synchronizing of theIED from a station clock.

Electrical (BNC) and optical connection (ST)for 0XX and 12X IRIG-B support.

Transformer input module TRM

The transformer input module is used togalvanically separate and transform the

secondary currents and voltages generated bythe measuring transformers. The module hastwelve inputs in different combinations ofcurrents and voltage inputs.

Alternative connectors of Ring lug orCompression type can be ordered.

High impedance resistor unit

The high impedance resistor unit, withresistors for pick-up value setting and avoltage dependent resistor, is available in asingle phase unit and a three phase unit.Both are mounted on a 1/1 19 inch apparatusplate with compression type terminals.

Layout and dimensions

Dimensions

xx05000003.vsd

CB

E

F

A

D

IEC05000003 V1 EN

Figure 6. 1/2 x 19” case with rear cover


ABB 33

xx05000004.vsd

IEC05000004 V1 EN

Figure 7. Side-by-side mounting

Case size A B C D E F

6U, 1/2 x 19” 265.9 223.7 201.1 242.1 252.9 205.7

6U, 3/4 x 19” 265.9 336.0 201.1 242.1 252.9 318.0

6U, 1/1 x 19” 265.9 448.1 201.1 242.1 252.9 430.3

(mm)

Mounting alternatives

The following mounting alternatives areavailable (IP40 protection from the front):

• 19” rack mounting kit• Flush mounting kit with cut-out

dimensions:

1/2 case size (h) 254.3 mm (w) 210.1mm

3/4 case size (h) 254.3 mm (w) 322.4mm

1/1 case size (h) 254.3 mm (w) 434.7mm

• Wall mounting kit

See ordering for details about availablemounting alternatives.


34 ABB

20. Connection diagrams

Table 1. Designations for 1/2 x 19” casing with 1 TRM slot

1MRK002801-AC 2 670 1.2 PG V1 EN

Module Rear Positions

PSM X11

BIM, BOM, SOM, IOM orMIM

X31 and X32 etc. to X51and X52

SLM X301:A, B, C, D

LDCM, IRIG-B or RS485 X302

LDCM or RS485 X303

OEM X311:A, B, C, D

LDCM, RS485 or GTM X312, 313

TRM X401


ABB 35


1MRK002801-AC 3 670 1.2 PG V1 EN


PSM X11


X31 and X32 etc. toX101 and X102

SLM X301:A, B, C, D


LDCM or RS485 X303

OEM X311:A, B, C, D

LDCM, RS485 or GTM X312, X313

TRM X401


36 ABB


1MRK002801-AC 4 670 1.2 PG V1 EN


PSM X11


X31 and X32 etc. to X71 andX72

SLM X301:A, B, C, D


LDCM or RS485 X303

OEM X311:A, B, C, D

LDCM, RS485 or GTM X312, X313, X322, X323

TRM 1 X401

TRM 2 X411


ABB 37


1MRK002801-AC 5 670 1.2 PG V1 EN


PSM X11

BIM, BOM, SOM,IOM or MIM


SLM X301:A, B, C, D

LDCM, IRIG-B orRS485

X302

LDCM or RS485 X303

OEM X311:A, B, C, D

LDCM,RS485 orGTM

X312, X313

TRM X401

Table 5. Designations for 1/1 x 19” casing with 2 TRM slots

1MRK002801-AC 6 670 1.2 PG V1 EN


PSM X11

BIM, BOM, SOM,IOM or MIM


SLM X301:A, B, C, D

LDCM, IRIG-B orRS485

X302

LDCM or RS485 X303

OEM X311:A, B, C, D

LDCM, RS485 orGTM

X312, X313, X322, X323

TRM 1 X401

TRM 2 X411


38 ABB

1MRK002801-AC 10 670 1.2 PG V1 EN

Figure 8. Transformer input module (TRM)

Indicates high polarity

CT/VT-input designation according to figure 8

Curr

ent/

volt

age

confi

gura

tion

(50/

60 H

z)

AI01 AI02 AI03 AI04 AI05 AI06 AI07 AI08 AI09 AI10 AI11 AI12

12I, 1A 1A 1A 1A 1A 1A 1A 1A 1A 1A 1A 1A 1A

12I, 5A 5A 5A 5A 5A 5A 5A 5A 5A 5A 5A 5A 5A

9I+3U,1A

1A 1A 1A 1A 1A 1A 1A 1A 1A 110-220V 110-220V 110-220V

9I+3U,5A

5A 5A 5A 5A 5A 5A 5A 5A 5A 110-220V 110-220V 110-220V

5I, 1A+4I, 5A+3U

1A 1A 1A 1A 1A 5A 5A 5A 5A 110-220V 110-220V 110-220V

7I+5U,1A

1A 1A 1A 1A 1A 1A 1A 110-220V 110-220V 110-220V 110-220V 110-220V

7I+5U,5A

5A 5A 5A 5A 5A 5A 5A 110-220V 110-220V 110-220V 110-220V 110-220V

6I, 5A+1I, 1A+5U

5A 5A 5A 5A 5A 5A 1A 110-220V 110-220V 110-220V 110-220V 110-220V

3I, 5A+4I, 1A+5U

5A 5A 5A 1A 1A 1A 1A 110-220V 110-220V 110-220V 110-220V 110-220V

3IM, 1A+4IP,1A+5U

1AM*)

1AM*)

1AM*)

1A 1A 1A 1A 110-220V 110-220V 110-220V 110-220V 110-220V

3IM, 5A+4IP,5A+5U

5AM*)

5AM*)

5AM*)

5A 5A 5A 5A 110-220V 110-220V 110-220V 110-220V 110-220V

6I+6U,1A

1A 1A 1A 1A 1A 1A 110-220V 110-220V 110-220V 110-220V 110-220V 110-220V

6I+6U,5A

5A 5A 5A 5A 5A 5A 110-220V 110-220V 110-220V 110-220V 110-220V 110-220V


ABB 39

3I, 5A+3I, 1A+6U

5 A 5 A 5 A 1A 1A 1A 110-220V 110-220V 110-220V 110-220V 110-220V 110-220V

6I, 1A 1A 1A 1A 1A 1A 1A - - - - - -

6I, 5A 5A 5A 5A 5A 5A 5A - - - - - -

*) Metering

Note that internal polarity can be adjusted by setting of analog input CT neutral direction and/or on SMAI pre-processing function blocks.

1MRK002801-AC 11 670 1.2 PG V1 EN

Figure 9. Binary input module (BIM). Inputcontacts named XA corresponds torear position X31, X41, and so on,and input contacts named XB torear position X32, X42, and so on.

1MRK002801-AC 15 670 1.2 PG V1 EN

Figure 10. mA input module (MIM)


40 ABB

1MRK002801-AC 8 670 1.2 PG V1 EN

Figure 11. IED with basic functionality and communication interfaces

1MRK002801-AC 7 670 1.2 PG V1 EN

Figure 12. Power supply module (PSM)


ABB 41

1MRK002801-AC 12 670 1.2 PG V1 EN

Figure 13. Binary output module (BOM). Output contacts named XA corresponds to rearposition X31, X41, and so on, and output contacts named XB to rear positionX32, X42, and so on.

1MRK002801-AC 13 670 1.2 PG V1 EN

Figure 14. Static output module (SOM)


42 ABB

1MRK002801-AC 14 670 1.2 PG V1 EN

Figure 15. Binary in/out module (IOM). Input contacts named XA corresponds to rear positionX31, X41, and so on, and output contacts named XB to rear position X32, X42,and so on.


ABB 43

21. Technical data

General

Definitions

Referencevalue

The specified value of an influencing factor to which are referred thecharacteristics of the equipment

Nominalrange

The range of values of an influencing quantity (factor) within which, underspecified conditions, the equipment meets the specified requirements

Operativerange

The range of values of a given energizing quantity for which the equipment,under specified conditions, is able to perform its intended functionsaccording to the specified requirements

Energizing quantities, rated valuesand limits

Analog inputs

Table 6. TRM - Energizing quantities, rated values and limits for protection transformermodules

Quantity Rated value Nominal range

Current Ir = 1 or 5 A (0.2-40) × Ir

Operative range (0-100) x Ir

Permissive overload 4 × Ir cont.

100 × Ir for 1 s *)

Burden < 150 mVA at Ir = 5 A

< 20 mVA at Ir = 1 A

Ac voltage Ur = 110 V 0.5–288 V

Operative range (0–340) V

Permissive overload 420 V cont.450 V 10 s

Burden < 20 mVA at 110 V

Frequency fr = 50/60 Hz ± 5%

*) max. 350 A for 1 s when COMBITEST test switch is included.


44 ABB

Table 7. TRM - Energizing quantities, rated values and limits for measuring transformermodules


Current Ir = 1 or 5 A (0-1.8) × Irat Ir = 1 A

(0-1.6) × Irat Ir = 5 A

Permissive overload 1.1 × Ir cont.

1.8 × Ir for 30 min at Ir =

1 A1.6 × Ir for 30 min at Ir =

5 A

Burden < 350 mVA at Ir = 5 A

< 200 mVA at Ir = 1 A

Ac voltage Ur = 110 V 0.5–288 V

Operative range (0–340) V

Permissive overload 420 V cont.450 V 10 s

Burden < 20 mVA at 110 V

Frequency fr = 50/60 Hz ± 5%

Table 8. MIM - mA input module

Quantity: Rated value: Nominal range:

Input resistance Rin = 194 Ohm -

Input range ± 5, ± 10, ± 20mA0-5, 0-10, 0-20, 4-20mA

-

Power consumptioneach mA-boardeach mA input

£ 2 W£ 0.1 W

-

Table 9. OEM - Optical ethernet module

Quantity Rated value

Number of channels 1 or 2

Standard IEEE 802.3u 100BASE-FX

Type of fiber 62.5/125 mm multimode fibre

Wave length 1300 nm

Optical connector Type ST

Communication speed Fast Ethernet 100 MB


ABB 45

Auxiliary DC voltage

Table 10. PSM - Power supply module


Auxiliary dc voltage, EL (input) EL = (24 - 60) VEL = (90 - 250) V

EL ± 20%EL ± 20%

Power consumption 50 W typically -

Auxiliary DC power in-rush < 5 A during 0.1 s -

Binary inputs and outputs

Table 11. BIM - Binary input module


Binary inputs 16 -

DC voltage, RL 24/30 V48/60 V110/125 V220/250 V

RL ± 20%RL ± 20%RL ± 20%RL ± 20%

Power consumption24/30 V48/60 V110/125 V220/250 V

max. 0.05 W/inputmax. 0.1 W/inputmax. 0.2 W/inputmax. 0.4 W/input

-

Counter input frequency 10 pulses/s max -

Oscillating signal discriminator Blocking settable 1–40 HzRelease settable 1–30 Hz


46 ABB

Table 12. BIM - Binary input module with enhanced pulse counting capabilities


Binary inputs 16 -


RL ± 20%RL ± 20%RL ± 20%RL ± 20%



-

Counter input frequency 10 pulses/s max -

Balanced counter input frequency 40 pulses/s max -

Oscillating signal discriminator Blocking settable 1–40 HzRelease settable 1–30 Hz

Table 13. IOM - Binary input/output module


Binary inputs 8 -


RL ± 20%RL ± 20%RL ± 20%RL ± 20%



-


ABB 47

Table 14. IOM - Binary input/output module contact data (reference standard: IEC61810-2)

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 AC, DC

Test voltage across open contact, 1 min 1000 V rms 800 V DC

Current carrying capacityContinuous1 s

8 A10 A

8 A10 A

Making capacity at inductive load withL/R>10 ms0.2 s1.0 s

30 A10 A

0.4 A0.4 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 < 40ms

48 V/1 A110 V/0.4 A125 V/0.35 A220 V/0.2 A250 V/0.15 A

48 V/1 A110 V/0.4 A125 V/0.35 A220 V/0.2 A250 V/0.15 A

Maximum capacitive load - 10 nF


48 ABB

Table 15. SOM - Static Output Module (reference standard: IEC 61810-2): Static binaryoutputs

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 opencontact, 1 min

No galvanic separation No galvanic separation

Current carrying capacity:

Continuous 5A 5A

1.0s 10A 10A

Making capacity at capacitiveload with the maximumcapacitance of 0.2 μF :

0.2s 30A 30A

1.0s 10A 10A

Breaking capacity for DC with L/R ≤ 40ms

48V / 1A 110V / 0.4A

60V / 0,75A 125V / 0.35A

220V / 0.2A

250V / 0.15A

Operating time <1ms <1ms


ABB 49

Table 16. SOM - Static Output module data (reference standard: IEC 61810-2):Electromechanical relay outputs

Function of quantity Trip and signal relays

Max system voltage 250V AC/DC

Number of outputs 6

Test voltage across open contact, 1 min 1000V rms

Current carrying capacity:

Continuous 8A

1.0s 10A

Making capacity at capacitive load with themaximum capacitance of 0.2 μF:

0.2s 30A

1.0s 10A

Breaking capacity for DC with L/R ≤ 40ms 48V / 1A

110V / 0.4A

125V / 0,35A

220V / 0,2A

250V / 0.15A

Table 17. 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

Current carrying capacityContinuous1 s

8 A10 A

Making capacity at inductive load with L/R>10 ms0.2 s1.0 s

30 A10 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 A110 V/0.4 A125 V/0.35 A220 V/0.2 A250 V/0.15 A


50 ABB

Influencing factors

Table 18. Temperature and humidity influence

Parameter Reference value Nominal range Influence

Ambienttemperature, operatevalue

+20 °C -10 °C to +55 °C 0.02% /°C

Relative humidityOperative range

10%-90%0%-95%

10%-90% -

Storage temperature -40 °C to +70 °C - -

Table 19. Auxiliary DC supply voltage influence on functionality during operation

Dependence on Referencevalue

Withinnominal range

Influence

Ripple, in DC auxiliary voltageOperative range

max. 2%Full waverectified

15% of EL 0.01% /%

Auxiliary voltage dependence,operate value

± 20% of EL 0.01% /%

Interrupted auxiliary DC voltage

24-60 V DC ±20%90-250 V DC ±20%

Interruptioninterval0–50 ms

No restart

0–∞ s Correct behaviour atpower down

Restart time <180 s


ABB 51

Table 20. Frequency influence (reference standard: IEC 60255–1)

Dependence on Within nominal range Influence

Frequency dependence, operatevalue

fr ± 2.5 Hz for 50 Hz


± 1.0% / Hz

Frequency dependence fordistance protection operate value



±2.0% / Hz

Harmonic frequencydependence (20% content)

2nd, 3rd and 5th harmonic of fr ± 1.0%

Harmonic frequencydependence for distanceprotection (10% content)

2nd, 3rd and 5th harmonic of fr ± 6.0%

Harmonic frequencydependence for high impedancedifferential protection (10%content)

2nd, 3rd and 5th harmonic of fr ±5.0%


52 ABB

Type tests according to standards

Table 21. Electromagnetic compatibility

Test Type test values Reference standards

1 MHz burst disturbance 2.5 kV IEC 60255-22-1

100 kHz slow damped oscillatorywave 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, oscillatory4.0 kV, fast transient

IEEE/ANSI C37.90.1

Electrostatic dischargeDirect applicationIndirect application

15 kV air discharge8 kV contact discharge8 kV contact discharge

IEC 60255-22-2, Class IV IEC 61000-4-2, Class IV

Electrostatic dischargeDirect applicationIndirect application

15 kV air discharge8 kV contact discharge8 kV contact discharge

IEEE/ANSI C37.90.1

Fast transient disturbance 4 kV IEC 60255-22-4, Class A

Surge immunity test 1-2 kV, 1.2/50 mshigh energy

IEC 60255-22-5

Power frequency immunity test 150-300 V, 50 Hz IEC 60255-22-7, Class A

Conducted common modeimmunity test

15 Hz-150 kHz IEC 61000-4-16, Class IV

Power frequency magnetic field test 1000 A/m, 3 s100 A/m, cont.

IEC 61000-4-8, Class V

Damped oscillatory magnetic fieldtest

100 A/m IEC 61000-4-10, Class V

Radiated electromagnetic fielddisturbance

20 V/m, 80-1000 MHz 1.4-2.7 GHz

IEC 60255-22-3

Radiated electromagnetic fielddisturbance

35 V/m26-1000 MHz

IEEE/ANSI C37.90.2

Conducted electromagnetic fielddisturbance

10 V, 0.15-80 MHz IEC 60255-22-6

Radiated emission 30-1000 MHz IEC 60255-25

Conducted emission 0.15-30 MHz IEC 60255-25


ABB 53

Table 22. Insulation

Test Type test values Reference standard

Dielectric test 2.0 kV AC, 1 min. IEC 60255-5

Impulse voltage test 5 kV, 1.2/50 ms, 0.5 J

Insulation resistance >100 MW at 500 VDC

Table 23. Environmental tests

Test Type test value Reference standard

Cold test Test Ad for 16 h at -25°C IEC 60068-2-1

Storage test Test Ad for 16 h at -40°C IEC 60068-2-1

Dry heat test Test Bd for 16 h at +70°C IEC 60068-2-2

Damp heat test, steady state Test Ca for 4 days at +40 °C andhumidity 93%

IEC 60068-2-78

Damp heat test, cyclic Test Db for 6 cycles at +25 to +55°C and humidity 93 to 95% (1 cycle= 24 hours)

IEC 60068-2-30

Table 24. CE compliance

Test According to

Immunity EN 50263

Emissivity EN 50263

Low voltage directive EN 50178

Table 25. 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 II 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


54 ABB


Table 26. Transformer differential protection T2WPDIF, T3WPDIF

Function Range or value Accuracy

Operating characteristic Adaptable ± 1.0% of Ir for I < Ir± 1.0% of Ir for I > Ir

Reset ratio >95% -

Unrestrained differential currentlimit

(100-5000)%ofIBase on highvoltage winding

± 1.0% of set value

Base sensitivity function (10-60)% of IBase ± 1.0% of Ir

Second harmonic blocking (5.0-100.0)% offundamentaldifferential current

± 2.0% of Ir

Fifth harmonic blocking (5.0-100.0)% offundamentaldifferential current

± 5.0% of Ir

Connection type for each of thewindings

Y or D -

Phase displacement between highvoltage winding, W1 and each ofthe windings, W2 and W3. Hournotation

0–11 -

Operate time, restrained function 25 ms typically at0 to 2 x Ib

-

Reset time, restrained function 20 ms typically at2 to 0 x Ib

-

Operate time, unrestrainedfunction

12 ms typically at0 to 5 x Ib

-

Reset time, unrestrained function 25 ms typically at5 to 0 x Ib

-

Critical impulse time 2 ms typically at 0to 5 x Ib

-


ABB 55

Table 27. Restricted earth fault protection, low impedance REFPDIF


Operate characteristic Adaptable ± 1.0% of Ir for I < IBase

± 1.0% of I for I > IBase

Reset ratio >95% -

Base sensitivity function (4.0-100.0)% of IBase ± 1.0% of Ir

Directional characteristic Fixed 180 degrees or ± 60to ± 90 degrees

± 2.0 degree

Operate time, trip function 20 ms typically at 0 to 10x IdMin

-

Reset time, trip function 25 ms typically at 10 to 0x IdMin

-

Second harmonic blocking (5.0-100.0)% offundamental

± 2.0% of IrBase

Table 28. 1Ph High impedance differential protection HZPDIF


Operate voltage (20-400) VI=U/R

± 1.0% of Ir

Reset ratio >95% -

Maximum continuous voltage U>Trip2/series resistor ≤200 W -

Operate time 10 ms typically at 0 to 10 x Ud -

Reset time 90 ms typically at 10 to 0 x Ud -

Critical impulse time 2 ms typically at 0 to 10 x Ud -


56 ABB


Table 29. Distance measuring zone, Quad ZMQPDIS


Number of zones 5 with selectabledirection

-

Minimum operateresidual current, zone 1

(5-1000)% ofIBase

-

Minimum operate current,phase-to-phase and phase-to-earth

(10-1000)% ofIBase

-

Positive sequencereactance

(0.10-3000.00) Ω/phase

± 2.0% static accuracy± 2.0 degrees static angular accuracyConditions:Voltage range: (0.1-1.1) x Ur

Current range: (0.5-30) x IrAngle: at 0 degrees and 85 degrees

Positive sequenceresistance

(0.01-1000.00) Ω/phase

Zero sequence reactance (0.10-9000.00) Ω/phase

Zero sequence resistance (0.01-3000.00) Ω/phase

Fault resistance, phase-to-earth

(0.10-9000.00) Ω/loop

Fault resistance, phase-to-phase

(0.10-3000.00) Ω/loop

Dynamic overreach <5% at 85degreesmeasured withCVT’s and0.5<SIR<30

-

Impedance zone timers (0.000-60.000) s ± 0.5% ± 10 ms

Operate time 24 ms typically -

Reset ratio 105% typically -

Reset time 30 ms typically -


ABB 57

Table 30. Distance measuring zone, quadrilateral characteristic for series compensatedlines ZMCPDIS, ZMCAPDIS


Number of zones 5 with selectable direction -


(5-1000)% of IBase -

Minimum operate current,Ph-Ph and Ph-E

(10-1000)% of IBase -


(0.10-3000.00) Ω/phase ± 2.0% static accuracy± 2.0 degrees static angular accuracyConditions:Voltage range: (0.1-1.1) x Ur



(0.10-1000.00) Ω/phase



Fault resistance, Ph-E (0.10-9000.00) Ω/loop

Fault resistance, Ph-Ph (0.10-3000.00) Ω/loop

Dynamic overreach <5% at 85 degreesmeasured with CCVT’sand 0.5<SIR<30

-






58 ABB

Table 31. Phase selection, quadrilateral characteristic with fixed angle FDPSPDIS


Minimum operate current (5-500)% of IBase -

Reactive reach, positivesequence

(0.50–3000.00) Ω/phase ± 2.0% static accuracy± 2.0 degrees static angular accuracyConditions:Voltage range: (0.1-1.1) x Ur


Resistive reach, positivesequence

(0.10–1000.00) Ω/phase

Reactive reach, zerosequence

(0.50–9000.00) Ω/phase

Resistive reach, zerosequence

(0.50–3000.00) Ω/phase

Fault resistance, phase-to-earth faults, forward andreverse

(1.00–9000.00) Ω/loop

Fault resistance, phase-to-phase faults, forward andreverse

(0.50–3000.00) Ω/loop

Load encroachmentcriteria:Load resistance, forwardand reverseSafety load impedanceangle

(1.00–3000.00) Ω/phase(5-70) degrees



ABB 59

Table 32. Full-scheme distance protection, Mho characteristic ZMHPDIS


Number of zones withselectable directions

5 with selectabledirection

-

Minimum operate current (10–30)% of IBase -

Positive sequenceimpedance, phase-to-earth loop

(0.005–3000.000) W/phase

± 2.0% static accuracyConditions:Voltage range: (0.1-1.1) x Ur


Positive sequenceimpedance angle, phase-to-earth loop

(10–90) degrees

Reverse reach, phase-to-earth loop (Magnitude)

(0.005–3000.000) Ω/phase

Magnitude of earth returncompensation factor KN

(0.00–3.00)

Angle for earthcompensation factor KN

(-180–180) degrees

Dynamic overreach <5% at 85 degreesmeasured with CVT’sand 0.5<SIR<30

-

Timers (0.000-60.000) s ± 0.5% ± 10 ms

Operate time 20 ms typically (withstatic outputs)

-




60 ABB

Table 33. Full-scheme distance protection, quadrilateral for earth faults ZMMPDIS


Number of zones 5 with selectable direction -



(0.50-3000.00) W/phase ± 2.0% static accuracy± 2.0 degrees static angular accuracyConditions:Voltage range: (0.1-1.1) x Ur



(0.10-1000.00) Ω/phase



Fault resistance, Ph-E (1.00-9000.00) W/loop

Dynamic overreach <5% at 85 degreesmeasured with CCVT’sand 0.5<SIR<30

-





Table 34. Faulty phase identification with load encroachment FMPSPDIS


Minimum operate current (5-30)% of IBase ± 1.0% of Ir

Load encroachmentcriteria: Load resistance,forward and reverse

(0.5–3000) W/phase(5–70) degrees

± 2.0% static accuracyConditions:Voltage range: (0.1–1.1) x Ur

Current range: (0.5–30) x IrAngle: at 0 degrees and 85degrees


ABB 61

Table 35. Distance measuring zone, quadrilateral characteristic, separate settingsZMRPDIS, ZMRAPDIS


Number of zones 5 with selectabledirection

-


(5-1000)% ofIBase

-

Minimum operate current,phase-to-phase and phase-to-earth

(10-1000)% ofIBase

-


(0.10-3000.00) Ω/phase

± 2.0% static accuracy± 2.0 degrees static angular accuracyConditions:Voltage range: (0.1-1.1) x Ur



(0.01-1000.00) Ω/phase



Fault resistance, phase-to-earth

(0.10-9000.00) Ω/loop

Fault resistance, phase-to-phase

(0.10-3000.00) Ω/loop

Dynamic overreach <5% at 85degreesmeasured withCVT’s and0.5<SIR<30

-






62 ABB

Table 36. Phase selection with load encroachment, quadrilateral characteristicFRPSPDIS



Reactive reach, positivesequence

(0.50–3000.00) Ω/phase ± 2.0% static accuracy± 2.0 degrees static angular accuracyConditions:Voltage range: (0.1-1.1) x IrCurrent range: (0.5-30) x IBaseAngle: at 0 degrees and 85 degrees

Resistive reach, positivesequence

(0.10–1000.00) Ω/phase

Reactive reach, zerosequence

(0.50–9000.00) Ω/phase

Resistive reach, zerosequence

(0.50–3000.00) Ω/phase

Fault resistance, phase-to-earth faults, forward andreverse

(1.00–9000.00) Ω/loop

Fault resistance, phase-to-phase faults, forward andreverse

(0.50–3000.00) Ω/loop

Load encroachmentcriteria:Load resistance, forwardand reverseSafety load impedanceangle

(1.00–3000.00) Ω/phase(5-70) degrees


Table 37. Power swing detection ZMRPSB


Reactive reach (0.10-3000.00) W/phase

± 2.0% static accuracyConditions:Voltage range: (0.1-1.1) x Ur

Current range: (0.5-30) x IrAngle: at 0 degrees and 85 degreesResistive reach (0.10–1000.00)W/loop

Timers (0.000-60.000) s ± 0.5% ± 10 ms


ABB 63

Table 38. Pole slip protection PSPPPAM


Impedance reach (0.00–1000.00)% of Zbase ± 2.0% of Ur/Ir

Characteristic angle (72.00–90.00) degrees ± 5.0 degrees

Start and trip angles (0.0–180.0) degrees ± 5.0 degrees

Zone 1 and Zone 2 tripcounters

(1-20) -

Table 39. Phase preference logic PPLPHIZ


Operate value, phase-to-phase and phase-to-neutral undervoltage

(10.0 - 100.0)% of UBase ± 0,5% of Ur

Reset ratio, undervoltage < 105% -

Operate value, residualvoltage

(5.0 - 70.0)% of UBase ± 0,5% of Ur

Reset ratio, residualvoltage

> 95% -

Operate value, residualcurrent

(10 - 200)% of IBase ± 1,0% of Ir for I < Ir± 1,0% of I for I > Ir

Reset ratio, residualcurrent

> 95% -

Timers (0.000 - 60.000) s ± 0,5% ± 10 ms

Operating mode No Filter, NoPrefCyclic: 1231c, 1321cAcyclic: 123a, 132a, 213a,231a, 312a, 321a


64 ABB

Current protection

Table 40. Instantaneous phase overcurrent protection PHPIOC


Operate current (1-2500)% of lBase ± 1.0% of Ir at I £ Ir± 1.0% of I at I > Ir

Reset ratio > 95% -

Operate time 25 ms typically at 0 to 2 x Iset -

Reset time 25 ms typically at 2 to 0 x Iset -

Critical impulse time 10 ms typically at 0 to 2 x Iset -




Dynamic overreach < 5% at t = 100 ms -


ABB 65

Table 41. Four step phase overcurrent protection OC4PTOC

Function Setting range Accuracy

Operate current (1-2500)% of lBase ± 1.0% of Ir at I ≤ Ir± 1.0% of I at I > Ir

Reset ratio > 95% -

Min. operating current (1-100)% of lBase ± 1.0% of Ir at I ≤ Ir±1.0% of I at I > Ir

Relay characteristic angle(RCA)

(-70.0– -50.0) degrees ± 2.0 degrees

Maximum forward angle (40.0–70.0) degrees ± 2.0 degrees

Minimum forward angle (75.0–90.0) degrees ± 2.0 degrees

2nd harmonic blocking (5–100)% of fundamental ± 2.0% of Ir

Independent time delay (0.000-60.000) s ± 0.5% ±10 ms

Minimum operate time (0.000-60.000) s ± 0.5% ±10 ms

Inverse characteristics,see table 103, table 104and table 105

19 curve types See table 103, table 104and table 105

Operate time, startfunction

25 ms typically at 0 to 2 x Iset -

Reset time, start function 25 ms typically at 2 to 0 x Iset -


Impulse margin time 15 ms typically -


66 ABB

Table 42. Instantaneous residual overcurrent protection EFPIOC



Reset ratio > 95% -







Dynamic overreach < 5% at t = 100 ms -


ABB 67

Table 43. Four step residual overcurrent protection EF4PTOC



Reset ratio > 95% -

Operate current fordirectional comparison

(1–100)% of lBase ± 1.0% of Ir

Timers (0.000-60.000) s ± 0.5% ±10 ms



Second harmonic restrainoperation

(5–100)% of fundamental ± 2.0% of Ir

Relay characteristic angle (-180 to 180) degrees ± 2.0 degrees

Minimum polarizingvoltage

(1–100)% of UBase ± 0.5% of Ur

Minimum polarizingcurrent

(1-30)% of IBase ±0.25% of Ir

Real part of source Zused for currentpolarization

(0.50-1000.00) W/phase -

Imaginary part of sourceZ used for currentpolarization

(0.50–3000.00) W/phase -







68 ABB

Table 44. Four step negative sequence overcurrent protection NS4PTOC


Operate value, negativesequence current, step 1-4

(1-2500)% of lBase ± 1.0% of Ir at I £ Ir± 1.0% of I at I > Ir

Reset ratio > 95% -

Timers (0.000-60.000) s ± 0.5% ± 10 ms



Minimum operate currentfor step 1 - 4

(1.00 - 10000.00)% of IBase ± 1.0% of Ir at I < Ir± 1.0% of I at I > Ir

Operate value, negativecurrent for directionalrelease

(1–100)% of IBase ± 1.0% of Ir

Relay characteristic angle (-180 to 180) degrees ± 2.0 degrees

Minimum polarizingvoltage

(1–100)% of UBase ± 0.5% of Ur

Minimum polarizingcurrent

(2-100)% of IBase ±1.0% of Ir

Real part of negativesequence sourceimpedance used forcurrent polarization

(0.50-1000.00) W/phase -

Imaginary part ofnegative sequence sourceimpedance used forcurrent polarization

(0.50–3000.00) W/phase -


25 ms typically at 0.5 to 2 x Iset -

Reset time, start function 25 ms typically at 2 to 0.5 x Iset -

Critical impulse time, startfunction


Impulse margin time,start function

15 ms typically -

Transient overreach <10% at τ = 100 ms -


ABB 69

Table 45. Sensitive directional residual overcurrent and power protection SDEPSDE


Operate level for 3I0·cosjdirectional residualovercurrent

(0.25-200.00)% of lBase At low setting:(2.5-10) mA(10-50) mA

± 1.0% of Ir at I £ Ir± 1.0% of I at I > Ir ±0.5 mA±1.0 mA

Operate level for 3I0·3U0

· cosj directional residualpower

(0.25-200.00)% of SBase At low setting:(0.25-5.00)% of SBase

± 1.0% of Sr at S £ Sr

± 1.0% of S at S > Sr

± 10% of set value

Operate level for 3I0 and

j residual overcurrent


± 1.0% of Ir at £ Ir± 1.0% of I at I > Ir ±0.5 mA±1.0 mA

Operate level for non-directional overcurrent

(1.00-400.00)% of lBase At low setting:(10-50) mA

± 1.0% of Ir at I £ Ir± 1.0% of I at I > Ir ± 1.0 mA

Operate level for non-directional residualovervoltage

(1.00-200.00)% of UBase ± 0.5% of Ur at U£Ur

± 0.5% of U at U > Ur

Residual release currentfor all directional modes


± 1.0% of Ir at I £ Ir± 1.0% of I at I > Ir ±0.5 mA± 1.0 mA

Residual release voltagefor all directional modes

(0.01-200.00)% of UBase ± 0.5% of Ur at U£Ur

± 0.5% of U at U > Ur

Reset ratio > 95% -

Timers (0.000-60.000) s ± 0.5% ±10 ms



Relay characteristic angleRCA

(-179 to 180) degrees ± 2.0 degrees

Relay open angle ROA (0-90) degrees ± 2.0 degrees


70 ABB

Table 45. Sensitive directional residual overcurrent and power protection SDEPSDE,continued


Operate time, non-directional residual overcurrent


Reset time, non-directional residual overcurrent





Table 46. Thermal overload protection, one time constant LPTTR


Reference current (0-400)% of IBase ± 1.0% of Ir

Reference temperature (0-400)°C ± 1.0°C

Operate time:

2 2

2 2ln p

b

I It

I It

æ ö-ç ÷= ×ç ÷-è ø

EQUATION1356 V1 EN (Equation 1)

I = actual measuredcurrentIp = load current before

overload occursIb = base current, IBase

Time constant t = (0–1000) minutes

IEC 60255-8, class 5 + 200 ms

Alarm temperature (0-200)°C ± 2.0% of heat content trip

Trip temperature (0-400)°C ± 2.0% of heat content trip

Reset level temperature (0-400)°C ± 2.0% of heat content trip


ABB 71

Table 47. Thermal overload protection, two time constants TRPTTR


Base current 1 and 2 (30–250)% of IBase ± 1.0% of Ir

Operate time:

2 2

2 2ln p

b

I It

I It

æ ö-ç ÷= ×ç ÷-è ø


I = Imeasured

Ip = load current before

overload occurs

Time constant τ = (1–500)minutes

IEC 60255–8, class 5 + 200 ms

Alarm level 1 and 2 (50–99)% of heat contenttrip value

± 2.0% of heat content trip

Operate current (50–250)% of IBase ± 1.0% of Ir

Reset level temperature (10–95)% of heat contenttrip

± 2.0% of heat content trip

Table 48. Breaker failure protection CCRBRF


Operate phase current (5-200)% of lBase ± 1.0% of Ir at I £ Ir± 1.0% of I at I > Ir

Reset ratio, phase current > 95% -

Operate residual current (2-200)% of lBase ± 1.0% of Ir at I £ Ir± 1.0% of I at I > Ir

Reset ratio, residual current > 95% -

Phase current level forblocking of contact function

(5-200)% of lBase ± 1.0% of Ir at I £ Ir± 1.0% of I at I > Ir

Reset ratio > 95% -

Timers (0.000-60.000) s ± 0.5% ±10 ms

Operate time for currentdetection

10 ms typically -

Reset time for currentdetection

15 ms maximum -


72 ABB

Table 49. Pole discordance protection CCRPLD


Operate current (0–100)% of IBase ± 1.0% of Ir

Time delay (0.000-60.000) s ± 0.5% ± 10 ms

Table 50. Directional underpower protection GUPPDUP


Power level (0.0–500.0)% of SBase At low setting:(0.5-2.0)% of SBase(2.0-10)% of SBase

± 1.0% of Sr at S < Sr

± 1.0% of S at S > Sr

< ± 50% of set value< ± 20% of set value

Characteristic angle (-180.0–180.0) degrees 2 degrees

Timers (0.00-6000.00) s ± 0.5% ± 10 ms

Table 51. Directional overpower protection GOPPDOP


Power level (0.0–500.0)% of Sbase

At low setting:(0.5-2.0)% of Sbase

(2.0-10)% of Sbase

± 1.0% of Sr at S < Sr

± 1.0% of S at S > Sr

< ± 50% of set value< ± 20% of set value

Characteristic angle (-180.0–180.0) degrees 2 degrees

Timers (0.00-6000.00) s ± 0.5% ± 10 ms

Table 52. Broken conductor check BRCPTOC


Minimum phase current foroperation

(5–100)% of IBase ± 0.1% of Ir

Unbalance current operation (0–100)% of maximumcurrent

± 0.1% of Ir

Timer (0.00-6000.00) s ± 0.5% ± 10 ms


ABB 73

Table 53. Capacitor bank protection CBPGAPC


Operate value, overcurrent (0-900)% of lBase ± 1.0% of Ir at I < Ir± 1.0% of I at I > Ir

Reset ratio, overcurrent >95% -

Operate time, start 10 ms typically -

Reset time, start 30 ms typically -

Critical impulse time, overcurrentprotection start

2 ms typically at 0.5 to.2xIset1 ms typically at 0.5 to 10xIset

-

Impulse margin time, overcurrentprotection start

15 ms typically

Operate value, undercurrent (5-100)% of IBase ± 1.0% of Ir at I < Ir± 1.0% of I at I > Ir

Reset ratio, undercurrent <105% -

Operate value, reconnectioninhibit function

(4-1000)% of IBase ± 1.0% of Ir at I < Ir± 1.0% of I at I > Ir

Operate value, reactive poweroverload function

(5-900)% ± 1.0% of Sr at S < Sr

± 1.0% of S at S > Sr

Operate value, voltage protectionfunction for harmonic overload(Definite time)

(5-500)% ± 0.5% of Ur at U<Ur

± 0.5% of U at U>Ur

Operate value, voltage protectionfunction for harmonic overload(Inverse time)

(80-200)% ± 0.5% of Ur at U<Ur

± 0.5% of U at U>Ur

Inverse time characteristic According to IEC60871-1 (2005)and IEEE/ANSI C37.99 (2000)

Class 10 + 50 ms

Maximum trip delay, harmonicoverload IDMT

(0.05-6000.00) s ± 0.5% ± 10 ms

Minimum trip delay, harmonicoverload IDMT

(0.05-60.00) s ± 0.5% ± 10 ms

Timers (0.00-6000.00) s ± 0.5% ± 10 ms


74 ABB

Table 54. Negative sequence time overcurrent protection for machines NS2PTOC


Operate value, step 1 and 2,negative sequenceovercurrent

(3-500)% of IBase ± 1.0% of Ir at I < Ir± 1.0% of I at I > Ir

Reset ratio, step 1 and 2 >95% -

Operate time, start 20 ms typically at 0 to 2 x Iset

15 ms typically at 0 to 10 x Iset

-

Reset time, start 30 ms typically at 2 to 0 x Iset -

Time characteristics Definite or Inverse -

Inverse time characteristic

step 1, 22I t K=

K=1.0-99.0 Class 5 + 40 ms

Reset time, inversecharacteristic step 1,

22I t K=

K=0.01-20.00 Class 10 + 40 ms

Maximum trip delay, step 1IDMT

(0.00-6000.00) s ± 0.5% ± 10 ms

Minimum trip delay, step 1IDMT

(0.000-60.000) s ± 0.5% ± 10 ms

Timers (0.00-6000.00) s ± 0.5% ± 10 ms


ABB 75

Voltage protection

Table 55. Two step undervoltage protection UV2PTUV


Operate voltage, low andhigh step

(1–100)% of UBase ± 0.5% of Ur

Absolute hysteresis (0–100)% of UBase ± 0.5% of Ur

Internal blocking level, lowand high step

(1–100)% of UBase ± 0.5% of Ur

Inverse time characteristicsfor low and high step, seetable 107

- See table 107

Definite time delays (0.000-60.000) s ± 0.5% ±10 ms

Minimum operate time,inverse characteristics

(0.000–60.000) s ± 0.5% ± 10 ms

Operate time, start function 25 ms typically at 2 to 0 x Uset -

Reset time, start function 25 ms typically at 0 to 2 x Uset -

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


Table 56. Two step overvoltage protection OV2PTOV



(1-200)% of UBase ± 0.5% of Ur at U < Ur

± 0.5% of U at U > Ur

Absolute hysteresis (0–100)% of UBase ± 0.5% of Ur at U < Ur

± 0.5% of U at U > Ur


- See table 106

Definite time delays (0.000-60.000) s ± 0.5% ± 10 ms

Minimum operate time,Inverse characteristics

(0.000-60.000) s ± 0.5% ± 10 ms



Critical impulse time 10 ms typically at 0 to 2 x Uset -



76 ABB

Table 57. Two step residual overvoltage protection ROV2PTOV



(1-200)% of UBase ± 0.5% of Ur at U < Ur

± 1.0% of U at U > Ur

Absolute hysteresis (0–100)% of UBase ± 0.5% of Ur at U < Ur

± 1.0% of U at U > Ur


- See table 108

Definite time setting (0.000–60.000) s ± 0.5% ± 10 ms

Minimum operate time (0.000-60.000) s ± 0.5% ± 10 ms





Table 58. Overexcitation protection OEXPVPH


Operate value, start (100–180)% of (UBase/frated) ± 0.5% of U

Operate value, alarm (50–120)% of start level ± 0.5% of Ur at U ≤ Ur

± 0.5% of U at U > Ur

Operate value, high level (100–200)% of (UBase/frated) ± 0.5% of U

Curve type IEEE or customer defined

2

(0.18 ):

( 1)k

IEEE tM

×=

-


where M = (E/f)/(Ur/fr)

Class 5 + 40 ms

Minimum time delay forinverse function

(0.000–60.000) s ± 0.5% ± 10 ms

Maximum time delay forinverse function

(0.00–9000.00) s ± 0.5% ± 10 ms

Alarm time delay (0.000–60.000) s ± 0.5% ± 10 ms


ABB 77

Table 59. Voltage differential protection VDCPTOV


Voltage difference foralarm and trip

(0.0–100.0) % of UBase ± 0.5 % of Ur

Under voltage level (0.0–100.0) % of UBase ± 0.5% of Ur

Timers (0.000–60.000)s ± 0.5% ± 10 ms

Table 60. Loss of voltage check LOVPTUV


Operate voltage (0–100)% of UBase ± 0.5% of Ur

Pulse timer (0.050–60.000) s ± 0.5% ± 10 ms

Timers (0.000–60.000) s ± 0.5% ± 10 ms


78 ABB


Table 61. Underfrequency protection SAPTUF


Operate value, start function (35.00-75.00) Hz ± 2.0 mHz

Operate time, start function 100 ms typically -

Reset time, start function 100 ms typically -

Operate time, definite time function (0.000-60.000)s ± 0.5% ± 10 ms

Reset time, definite time function (0.000-60.000)s ± 0.5% ± 10 ms

Voltage dependent time delay

( )ExponentU UMin

t tMax tMin tMinUNom UMin

-= × - +

-é ùê úë û


U=Umeasured

Settings:UNom=(50-150)% ofUbase

UMin=(50-150)% of Ubase

Exponent=0.0-5.0tMax=(0.000-60.000)stMin=(0.000-60.000)s

Class 5 + 200 ms

Table 62. Overfrequency protection SAPTOF


Operate value, start function (35.00-75.00) Hz ± 2.0 mHz atsymmetricalthree-phasevoltage

Operate time, start function 100 ms typically at fset -0.5 Hz to

fset +0.5 Hz

-

Reset time, start function 100 ms typically -

Operate time, definite time function (0.000-60.000)s ± 0.5% ± 10 ms

Reset time, definite time function (0.000-60.000)s ± 0.5% ± 10 ms

Table 63. Rate-of-change frequency protection SAPFRC


Operate value, start function (-10.00-10.00) Hz/s ± 10.0 mHz/s

Operate value, internal blockinglevel

(0-100)% of UBase ± 0.5% of Ur

Operate time, start function 100 ms typically -


ABB 79


Table 64. 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

-

Base current (1 - 99999) A -

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

-

Base voltage (0.05 - 2000.00) kV -

Start overcurrent, step 1 and 2 (2 - 5000)% of IBase ± 1.0% of Ir for I<Ir± 1.0% of I for I>Ir

Start undercurrent, step 1and 2

(2 - 150)% of IBase ± 1.0% of Ir for I<Ir± 1.0% of I for I>Ir

Definite time delay (0.00 - 6000.00) s ± 0.5% ± 10 ms

Operate time startovercurrent


Reset time start overcurrent 25 ms typically at 2 to 0 x Iset -

Operate time startundercurrent


Reset time start undercurrent 25 ms typically at 0 to 2 x Iset -

See table 103 and table 104 Parameter ranges for customerdefined characteristic no 17:k: 0.05 - 999.00A: 0.0000 - 999.0000B: 0.0000 - 99.0000C: 0.0000 - 1.0000P: 0.0001 - 10.0000PR: 0.005 - 3.000TR: 0.005 - 600.000CR: 0.1 - 10.0

See table 103 and table 104


80 ABB

Table 64. General current and voltage protection CVGAPC , continued


Voltage level where voltagememory takes over

(0.0 - 5.0)% of UBase ± 0.5% of Ur

Start overvoltage, step 1 and 2 (2.0 - 200.0)% of UBase ± 0.5% of Ur for U<Ur

± 0.5% of U for U>Ur

Start undervoltage, step 1and 2

(2.0 - 150.0)% of UBase ± 0.5% of Ur for U<Ur


Operate time, startovervoltage

25 ms typically at 0 to 2 x Uset -

Reset time, start overvoltage 25 ms typically at 2 to 0 x Uset -

Operate time startundervoltage

25 ms typically 2 to 0 x Uset -

Reset time start undervoltage 25 ms typically at 0 to 2 x Uset -

High and low voltage limit,voltage dependent operation

(1.0 - 200.0)% of UBase ± 1.0% of Ur for U<Ur


Directional function Settable: NonDir, forward andreverse

-

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:



Overvoltage:




ABB 81

Table 64. General current and voltage protection CVGAPC , continued


Undervoltage:




82 ABB


Table 65. Current circuit supervision CCSRDIF


Operate current (5-200)% of Ir ± 10.0% of Ir at I £ Ir± 10.0% of I at I > Ir

Block current (5-500)% of Ir ± 5.0% of Ir at I £ Ir± 5.0% of I at I > Ir

Table 66. Fuse failure supervision SDDRFUF


Operate voltage, zero sequence (1-100)% of UBase ± 1.0% of Ur

Operate current, zero sequence (1–100)% of IBase ± 1.0% of Ir

Operate voltage, negativesequence

(1–100)% of UBase ± 0.5% of Ur

Operate current, negativesequence

(1–100)% of IBase ± 1.0% of Ir

Operate voltage change level (1–100)% of UBase ± 5.0% of Ur

Operate current change level (1–100)% of IBase ± 5.0% of Ir

Operate phase voltage (1-100)% of UBase ± 0.5% of Ur

Operate phase current (1-100)% of IBase ± 1.0% of Ir

Operate phase dead line voltage (1-100)% of UBase ± 0.5% of Ur

Operate phase dead line current (1-100)% of IBase ± 1.0% of Ir

Operate time, start function 25 ms typically at 1 to 0Ubase

-

Reset time, start function 35 ms typically at 0 to 1Ubase

-


ABB 83

Control

Table 67. Synchronizing, synchrocheck and energizing check SESRSYN


Phase shift, jline - jbus (-180 to 180) degrees -

Voltage ratio, Ubus/Uline (0.40-25.000) % ofUBaseBus and UBaseLIne

-

Voltage high limit for synchronizingand synchrocheck

(50.0-120.0)% ofUBaseBus and UBaseLIne

± 0.5% of Ur at U ≤ Ur

± 0.5% of U at U >Ur

Reset ratio, synchrocheck > 95% -

Frequency difference limit betweenbus and line

(0.003-1.000) Hz ± 2.0 mHz

Phase angle difference limitbetween bus and line

(5.0-90.0) degrees ± 2.0 degrees

Voltage difference limit betweenbus and line

(0.02-0.5) p.u ± 0.5% of Ur

Time delay output for synchrocheck (0.000-60.000) s ± 0.5% ± 10 ms

Voltage high limit for energizingcheck

(50.0-120.0)% ofUBaseBus and UBaseLIne



Reset ratio, voltage high limit > 95% -

Voltage low limit for energizingcheck

(10.0-80.0)% of UBase ± 0.5% of Ur

Reset ratio, voltage low limit < 105% -

Maximum voltage for energizing (50.0-180.0)% ofUBaseBus and/orUBaseLIne



Time delay for energizing check (0.000-60.000) s ± 0.5% ± 10 ms

Operate time for synchrocheckfunction

160 ms typically -

Operate time for energizing function 80 ms typically -


84 ABB

Table 68. Voltage control TR1ATCC, TR8ATCC, TCMYLTC and TLCYLTC


Transformer reactance (0.1–200.0)Ω, primary -

Time delay for lower commandwhen fast step down mode isactivated

(1.0–100.0) s -

Voltage control set voltage (85.0–120.0)% of UB ±0.25% of Ur

Outer voltage deadband (0.2–9.0)% of UB -

Inner voltage deadband (0.1–9.0)% of UB -

Upper limit of busbar voltage (80–180)% of UB ± 1.0% of Ur

Lower limit of busbar voltage (70–120)% of UB ± 1.0% of Ur

Undervoltage block level (0–120)% of UB ± 1.0% of Ur

Time delay (long) for automaticcontrol commands

(3–1000) s ± 0.5% ± 10 ms

Time delay (short) for automaticcontrol commands

(1–1000) s ± 0.5% ± 10 ms

Minimum operating time in inversemode

(3–120) s ± 0.5% ± 10 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 UB -

Load voltage auto correction (-20.0–20.0)% of UB -

Duration time for the reverse actionblock signal

(30–6000) s ± 0.5% ± 10 ms

Current limit for reverse actionblock

(0–100)% of I1Base -

Overcurrent block level (0–250)% 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, maxoperations/window

(3–30) operations/window -


ABB 85

Table 68. Voltage control TR1ATCC, TR8ATCC, TCMYLTC and TLCYLTC, continued


Alarm level of active power inforward and reverse direction

(-9999.99–9999.99) MW ± 1.0% of Sr

Alarm level of reactive power inforward and reverse direction

(-9999.99–9999.99) MVAr ± 1.0% of Sr

Time delay for alarms from powersupervision

(1–6000) s ± 0.5% ± 10 ms

Tap position for lowest and highestvoltage

(1–63) -

mA for lowest and highest voltagetap position

(0.000–25.000) mA -

Type of code conversion BIN, BCD, GRAY, SINGLE, mA -

Time after position change beforethe value is accepted

(1–60) s ± 0.5% ± 10 ms

Tap changer constant time-out (1–120) s ± 0.5% ± 10 ms

Raise/lower command output pulseduration

(0.5–10.0) s ± 0.5% ± 10 ms


86 ABB


Table 69. Scheme communication logic for residual overcurrent protection ECPSCH


Scheme type Permissive UnderreachingPermissive OverreachingBlocking

-

Communication schemecoordination time

(0.000-60.000) s ± 0.5% ± 10 ms

Table 70. Current reversal and weak-end infeed logic for residual overcurrent protectionECRWPSCH


Operating mode of WEIlogic

OffEchoEcho & Trip

-

Operate voltage 3Uo for

WEI trip

(5-70)% of UBase ± 0.5% of Ur

Reset ratio >95% -

Operate time for currentreversal logic

(0.000-60.000) s ± 0.5% ± 10 ms

Delay time for currentreversal

(0.000-60.000) s ± 0.5% ± 10 ms

Coordination time forweak-end infeed logic

(0.000–60.000) s ± 0.5% ± 10 ms


ABB 87

Logic

Table 71. Tripping logic SMPPTRC


Trip action 3-ph, 1/3-ph, 1/2/3-ph -

Minimum trip pulse length (0.000-60.000) s ± 0.5% ± 10 ms

Timers (0.000-60.000) s ± 0.5% ± 10 ms

Table 72. Configurable logic blocks

Logic block Quantity with cycle time Range or value Accuracy

fast medium normal

LogicAND 60 60 160 - -

LogicOR 60 60 160 - -

LogicXOR 10 10 20 - -

LogicInverter 30 30 80 - -

LogicSRMemory 10 10 20 - -

LogicRSMemory 10 10 20 - -

LogicGate 10 10 20 - -

LogicTimer 10 10 20 (0.000–90000.000) s ± 0.5% ± 10 ms

LogicPulseTimer 10 10 20 (0.000–90000.000) s ± 0.5% ± 10 ms

LogicTimerSet 10 10 20 (0.000–90000.000) s ± 0.5% ± 10 ms

LogicLoopDelay 10 10 20 (0.000–90000.000) s ± 0.5% ± 10 ms

Trip Matrix Logic 6 6 - - -

Boolean 16 toInteger

4 4 8 - -

Boolean 16 tointeger withLogic Node

4 4 8 - -

Integer toBoolean 16

4 4 8 - -

Integer toBoolean 16 withLogic Node

4 4 8 - -


88 ABB

Monitoring

Table 73. Measurements CVMMXN


Frequency (0.95-1.05) × fr ± 2.0 mHz

Voltage (0.1-1.5) ×Ur ± 0.5% of Ur at U£Ur

± 0.5% of U at U > Ur

Connected current (0.2-4.0) × Ir ± 0.5% of Ir at I £ Ir± 0.5% of I at I > Ir

Active power, P 0.1 x Ur< U < 1.5 x Ur

0.2 x Ir < I < 4.0 x Ir

± 1.0% of Sr at S ≤ Sr

± 1.0% of S at S > Sr

Conditions:0.8 x Ur < U < 1.2 Ur

0.2 x Ir < I < 1.2 Ir

Reactive power, Q 0.1 x Ur< U < 1.5 x Ur

0.2 x Ir < I < 4.0 x Ir

Apparent power, S 0.1 x Ur < U < 1.5 x Ur

0.2 x Ir< I < 4.0 x Ir

Power factor, cos (φ) 0.1 x Ur < U < 1.5 x Ur

0.2 x Ir< I < 4.0 x Ir

± 0.02

Table 74. Supervision of mA input signals


mA measuring function ± 5, ± 10, ± 20 mA0-5, 0-10, 0-20, 4-20 mA

± 0.1 % of set value ± 0.005 mA

Max current oftransducer to input

(-20.00 to +20.00) mA

Min current oftransducer to input

(-20.00 to +20.00) mA

Alarm level for input (-20.00 to +20.00) mA

Warning level for input (-20.00 to +20.00) mA

Alarm hysteresis forinput

(0.0-20.0) mA

Table 75. Event counter CNTGGIO


Counter value 0-10000 -

Max. count up speed 10 pulses/s -


ABB 89

Table 76. 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 99

Maximum number of analog inputs 30 + 10 (external +internally derived)

-

Maximum number of binary inputs 96 -

Maximum number of phasors in the TripValue recorder per recording

30 -

Maximum number of indications in adisturbance report

96 -

Maximum number of events in the Eventrecording per recording

150 -

Maximum number of events in the Eventlist

1000, first in - first out -

Maximum total recording time (3.4 srecording time and maximum number ofchannels, typical value)

340 seconds (100recordings) at 50 Hz, 280seconds (80 recordings)at 60 Hz

-

Sampling rate 1 kHz at 50 Hz1.2 kHz at 60 Hz

-

Recording bandwidth (5-300) Hz -

Table 77. Event list

Function Value

Buffer capacity Maximum number of events inthe list

1000

Resolution 1 ms

Accuracy Depending on timesynchronizing


90 ABB

Table 78. Indications

Function Value

Buffer capacity Maximum number of indications presentedfor single disturbance

96

Maximum number of recorded disturbances 100

Table 79. 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 ontimesynchronizing

Table 80. Trip value recorder

Function Value

Buffer capacity

Maximum number of analog inputs 30


Table 81. Disturbance recorder

Function Value

Buffer capacity Maximum number of analog inputs 40

Maximum number of binary inputs 96


Maximum total recording time (3.4 s recording time andmaximum number of channels, typical value)

340 seconds (100 recordings)at 50 Hz280 seconds (80 recordings) at60 Hz


ABB 91

Metering

Table 82. Pulse counter PCGGIO

Function Setting range Accuracy

Input frequency See Binary Input Module (BIM) -

Cycle time for report ofcounter value

(1–3600) s -

Table 83. Energy metering ETPMMTR


Energy metering kWh Export/Import,kvarh Export/Import

Input from MMXU. No extra errorat steady load


92 ABB


Table 84. IEC 61850-8-1 communication protocol

Function Value

Protocol IEC 61850-8-1

Communication speed for the IEDs 100BASE-FX

Table 85. LON communication protocol

Function Value

Protocol LON

Communication speed 1.25 Mbit/s

Table 86. SPA communication protocol

Function Value

Protocol SPA

Communication speed 300, 1200, 2400, 4800, 9600, 19200 or 38400 Bd

Slave number 1 to 899

Table 87. IEC60870-5-103 communication protocol

Function Value


Communication speed 9600, 19200 Bd

Table 88. SLM – LON port

Quantity Range or value

Optical connector Glass fibre: type STPlastic fibre: type HFBR snap-in

Fibre, optical budget Glass fibre: 11 dB (1000 m typically *)Plastic fibre: 7 dB (10 m typically *)

Fibre diameter Glass fibre: 62.5/125 mmPlastic fibre: 1 mm

*) depending on optical budget calculation


ABB 93

Table 89. SLM – SPA/IEC 60870-5-103/DNP3 port


Optical connector Glass fibre: type STPlastic fibre: type HFBR snap-in

Fibre, optical budget Glass fibre: 11 dB (3000ft/1000 m typically *)Plastic fibre: 7 dB (80ft/25 m typically *)

Fibre diameter Glass fibre: 62.5/125 mmPlastic fibre: 1 mm

*) depending on optical budget calculation

Table 90. Galvanic RS485 communication module


Communication speed 2400–19200 bauds

External connectors RS-485 6-pole connectorSoft ground 2-pole connector

Table 91. Duo driver configuration DUODRV

Function Value


Communication speed 100 Base-FX


94 ABB

Remote communication

Table 92. Line data communication module

Characteristic Range or value

Type of LDCM Short range(SR)

Medium range(MR)

Long range (LR)

Type of fibre Graded-indexmultimode62.5/125 µmor 50/125 µm

Singlemode9/125 µm

Singlemode 9/125 µm

Wave length 850 nm 1310 nm 1550 nm

Optical budgetGraded-index multimode62.5/125 mm, Graded-index multimode50/125 mm

13 dB (typicaldistanceabout 3 km *)9 dB (typicaldistanceabout 2 km *)

22 dB (typicaldistance 80 km *)

26 dB (typical distance110 km *)

Optical connector Type ST Type FC/PC Type FC/PC

Protocol C37.94 C37.94implementation**)

C37.94 implementation **)

Data transmission Synchronous Synchronous Synchronous

Transmission rate / Data rate 2 Mb/s / 64kbit/s

2 Mb/s / 64 kbit/s

2 Mb/s / 64 kbit/s

Clock source Internal orderived fromreceivedsignal

Internal orderived fromreceived signal

Internal or derived fromreceived signal

*) depending on optical budget calculation**) C37.94 originally defined just for multimode; using same header, configuration and dataformat as C37.94


ABB 95

Hardware

IED

Table 93. Case

Material Steel sheet

Front plate Steel sheet profile with cut-out for HMI

Surface treatment Aluzink preplated steel

Finish Light grey (RAL 7035)

Table 94. Water and dust protection level according to IEC 60529

Front IP40 (IP54 with sealing strip)

Rear, sides, topand bottom

IP20

Table 95. Weight

Case size Weight

6U, 1/2 x 19” £ 10 kg

6U, 3/4 x 19” £ 15 kg

6U, 1/1 x 19” £ 18 kg

Connection system

Table 96. CT and VT circuit connectors

Connector type Rated voltage andcurrent

Maximum conductorarea

Screw compression type 250 V AC, 20 A 4 mm2 (AWG12)

2 x 2.5 mm2 (2 x AWG14)

Terminal blocks suitable for ringlug terminals

250 V AC, 20 A 4 mm2 (AWG12)

Table 97. Binary I/O connection system

Connector type Rated voltage Maximum conductorarea

Screw compression type 250 V AC 2.5 mm2 (AWG14)

2 × 1 mm2 (2 x AWG18)

Terminal blocks suitable for ringlug terminals

300 V AC 3 mm2 (AWG14)


96 ABB

Basic IED functions

Table 98. Self supervision with internal event list

Data Value

Recording manner Continuous, event controlled

List size 1000 events, first in-first out

Table 99. Time synchronization, time tagging

Function Value

Time tagging resolution, events and sampled measurement values 1 ms

Time tagging error with synchronization once/min (minute pulsesynchronization), events and sampled measurement values

± 1.0 ms typically

Time tagging error with SNTP synchronization, sampledmeasurement values

± 1.0 ms typically

Table 100. GPS time synchronization module (GTM)


Receiver – ±1µs relative UTC

Time to reliable time reference withantenna in new position or after powerloss longer than 1 month

<30 minutes –

Time to reliable time reference after apower loss longer than 48 hours

<15 minutes –

Time to reliable time reference after apower loss shorter than 48 hours

<5 minutes –

Table 101. 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 endTNC in antenna end


ABB 97

Table 102. IRIG-B

Quantity Rated value

Number of channels IRIG-B 1

Number of channels PPS 1

Electrical connector IRIG-B BNC

Optical connector PPS and IRIG-B Type ST

Type of fibre 62.5/125 μm multimode fibre

Pulse-width modulated 5 Vpp

Amplitude modulated– low level– high level

1-3 Vpp3 x low level, max 9 Vpp


98 ABB

Inverse characteristic

Table 103. ANSI Inverse time characteristics


Operating characteristic:

( )1= + ×

-

æ öç ÷ç ÷è ø

P

At B k

I

EQUATION1249-SMALL V1 EN

Reset characteristic:

( )2 1= ×

-

trt kI


I = Imeasured/Iset

k = (0.05-999) in steps of 0.01unless otherwise stated

-

ANSI Extremely Inverse A=28.2, B=0.1217, P=2.0 , tr=29.1 ANSI/IEEE C37.112,class 5 + 40 ms

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 ExtremelyInverse

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 k=(0.05-999) in steps of 0.01A=0.086, B=0.185, P=0.02, tr=4.6


ABB 99

Table 104. IEC Inverse time characteristics


Operating characteristic:

( )1= ×

-


P

At k

I


I = Imeasured/Iset

k = (0.05-999) in steps of 0.01 -

Time delay to reset, IEC inversetime

(0.000-60.000) s ± 0.5% of set time ±10 ms

IEC Normal Inverse A=0.14, P=0.02 IEC 60255-3, class 5+ 40 ms

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 characteristicOperate characteristic:

( )= + ×

-


P

At B k

I C


Reset characteristic:

( )= ×

-PR

TRt k

I CR


I = Imeasured/Iset

k = (0.05-999) in steps of 0.01A=(0.005-200.000) in steps of 0.001B=(0.00-20.00) in steps of 0.01C=(0.1-10.0) in steps of 0.1P=(0.005-3.000) in steps of 0.001TR=(0.005-100.000) in steps of 0.001CR=(0.1-10.0) in steps of 0.1PR=(0.005-3.000) in steps of 0.001

IEC 60255, class 5 +40 ms


100 ABB

Table 105. RI and RD type inverse time characteristics


RI type inverse characteristic

1

0.2360.339

= ×

-

t k

I


I = Imeasured/Iset

k = (0.05-999) in steps of 0.01 IEC 60255-3, class 5+ 40 ms

RD type logarithmic inversecharacteristic

5.8 1.35= - ×æ öç ÷è ø

tI

Ink


I = Imeasured/Iset

k = (0.05-999) in steps of 0.01 IEC 60255-3, class 5+ 40 ms


ABB 101

Table 106. Inverse time characteristics for overvoltage protection


Type A curve:

=- >

>

æ öç ÷è ø

tk

U U

U


U> = Uset

U = Umeasured

k = (0.05-1.10) in steps of0.01 unless otherwise stated

Class 5 +40 ms

Type B curve:

2.0

480

32 0.5 0.035

=×

- >× - -

>

æ öç ÷è ø

tk

U U

U



Type C curve:

3.0

480

32 0.5 0.035

=×

- >× - -

>

æ öç ÷è ø

tk

U U

U



Programmable curve:

×= +

- >× -

>

æ öç ÷è ø

P

k At D

U UB C

U


k = (0.05-1.10) in steps of0.01 unless otherwise statedA = (0.005-200.000) in stepsof 0.001B = (0.50-100.00) in steps of0.01C = (0.0-1.0) in steps of 0.1D = (0.000-60.000) in stepsof 0.001P = (0.000-3.000) in steps of0.001


102 ABB

Table 107. Inverse time characteristics for undervoltage protection


Type A curve:

=< -

<

æ öç ÷è ø

kt

U U

U


U< = Uset

U = UVmeasured


Class 5 +40 ms

Type B curve:

2.0

4800.055

32 0.5

×= +

< -× -

<

æ öç ÷è ø

kt

U U

U


U< = Uset

U = Umeasured


Programmable curve:

×= +

< -× -

<

é ùê úê úê úæ öê úç ÷ë è ø û

P

k At D

U UB C

U


U< = Uset

U = Umeasured

k = (0.05-1.10) in steps of0.01 unless otherwise statedA = (0.005-200.000) in stepsof 0.001B = (0.50-100.00) in steps of0.01C = (0.0-1.0) in steps of 0.1D = (0.000-60.000) in stepsof 0.001P = (0.000-3.000) in steps of0.001


ABB 103

Table 108. Inverse time characteristics for residual overvoltage protection


Type A curve:

=- >

>

æ öç ÷è ø

tk

U U

U


U> = Uset

U = Umeasured

k = (0.05-1.10) insteps of 0.01

Class 5 +40 ms

Type B curve:

2.0

480

32 0.5 0.035

=×

- >× - -

>

æ öç ÷è ø

tk

U U

U


k = (0.05-1.10) insteps of 0.01

Type C curve:

3.0

480

32 0.5 0.035

=×

- >× - -

>

æ öç ÷è ø

tk

U U

U


k = (0.05-1.10) insteps of 0.01

Programmable curve:

×= +

- >× -

>

æ öç ÷è ø

P

k At D

U UB C

U


k = (0.05-1.10) insteps of 0.01A = (0.005-200.000)in steps of 0.001B = (0.50-100.00) insteps of 0.01C = (0.0-1.0) insteps of 0.1D = (0.000-60.000)in steps of 0.001P = (0.000-3.000) insteps of 0.001


104 ABB

22. Ordering

Guidelines

Carefully read and follow the set of rules to ensure problem-free order management. Be aware that certainfunctions can only be ordered in combination with other functions and that some functions require specifichardware selections.

Please refer to the available functions table for included application functions.

Product specification

Basic IED 670 platform and common functions housed in selected casing

RET670 Quantity: 1MRK 002 816-AC

Default:

The IED connect CD contains configuration alternative. Use the PCM600 to create or modify the configuration. ThePCM600 can also be used for adaptation of an included example configuration.

Option:

Customer specific configuration On request

Connection type for Power supply modules and I/O modules

Rule: Same connection type for Power supply modules and I/O modules must be ordered

Compression terminals 1MRK 002 960-AA

Ring lug terminals 1MRK 002 960-BA

Power supply module

Rule: One Power supply module must be specified

Power supply module (PSM) 24-60 VDC 1MRK 002 239-AB

90-250 VDC 1MRK 002 239-BB


Rule: One of Differential protection must be ordered

Transformer differential protection, two winding (T2WPDIF)

Qty: 1 2

1MRK 002 901-AC

Transformer differential protection, three winding (T3WPDIF)

Qty: 1 2 1MRK 002 901-CC


ABB 105

Logic

Rule: One Tripping logic must be ordered

Tripping logic (SMPPTRC) Qty: 1 2 3 4 5 6 1MRK 002 917-AC

Optional functions


1Ph High impedance differential protection (HZPDIF)

Qty:

1 2 3 4 5 6 1MRK 002 901-HB

Restricted earth fault protection, low impedance (REFPDIF)

Qty:

1 2 3 1MRK 002 901-EB


106 ABB


Rule: One and only one of the alternatives (Alt. 1-4) can be ordered

Alternative 1:Rule: Distance protection and Directional impedancemust be ordered togetherNote: Phase selection FDPSPDIS always included in thispackage)Distance protection zones, quadrilateral characteristic(ZMQPDIS, ZMQAPDIS)

Qty:

1 2 3 4 5

1MRK 002 904-XB

Directional impedance quadrilateral (ZDRDIR)

Qty:

1 2 1MRK 002 904-YB

Phase selection, quadrilateral characteristic with fixedangle (FDPSPDIS)

Qty:

1 2 1MRK 002 904-AD

Alternative 2:Rule: All functions within the alternative must be orderedNote: Phase selection FDPSPDIS always included in thispackage)Distance measuring zone, quadrilateral characteristic forseries compensated lines (ZMCPDIS, ZMCAPDIS)

Qty:

1 2 3 4 5

1MRK 002 925-AB

Directional impedance quadrilateral, including seriescompensation (ZDSRDIR, 21D)

Qty:

1 2 1MRK 002 925-CB

Phase selection, quadrilateral characteristic with fixedangle (FDPSPDIS)

Qty:

1 2 1MRK 002 904-AD

Alternative 3:Rule: All functions within the alternative must be orderedFull scheme distance protection, mho characteristic(ZMHPDIS)

Qty:

1 2 3 4 5

1MRK 002 925-EB

Full scheme distance protection, quadrilateral for earthfaults (ZMMPDIS, ZMMAPDIS)

Qty:

1 2 3 4 5 1MRK 002 925-GB

Directional impedance element for mho characteristic(ZDMRDIR)

Qty:

1 2 1MRK 002 924-PA

Additional distance protection directional function forearth faults (ZDARDIR)

Qty: 1MRK 002 908-VA

Mho impedance supervision logic (ZSMGAPC) Qty: 1MRK 002 908-UB

Faulty phase identification with load enchroachment(FMPSPDIS)

Qty:

1 2 1MRK 002 925-BB

Alternative 4:Rule: All functions within the alternative must be orderedDistance protection zone, quadrilateral characteristic,separate settings (ZMRPDIS, ZMRAPDIS)

Qty:

1 2 3 4 5

1MRK 002 925-VA


ABB 107

Phase selection, quadrilateral characteristic with settableangle (FRPSPDIS)

Qty:

1 2 1MRK 002 925-XA

Directional impedance quadrilateral (ZDRDIR)

Qty:

1 2 1MRK 002 904-YB

Note: Optional with alternative 1Directional impedance element for mho characteristic(ZDMRDIR)

Qty:

1 2

1MRK 002 924-PA

Note: Optional with alternative 1, 2 and 4Faulty phase identification with load encroachment(FMPSPDIS)

Qty:

1 2

1MRK 002 925-BB

Note: Optional with alternative 3Phase selection, quadrilateral characteristic with fixedangle (FDPSPDIS)

Qty:

1 2

1MRK 002 904-AD

Power swing detection (ZMRPSB) Qty: 1MRK 002 904-NB

Power swing logic (ZMRPSL) Qty: 1MRK 002 924-RB

Pole slip/out-of-step protection (PSPPPAM) Qty: 1MRK 002 925-LB

Phase preference logic (PPLPHIZ) Qty: 1MRK 002 908-LB


108 ABB

Current protection

Instantaneous phase overcurrent protection (PHPIOC)

Qty:

1 2 3 4

5 6 7 8

1MRK 002 906-AC

Four step phase overcurrent protection (OC4PTOC)

Qty:

1 2 3 4

5 6 7 8

1MRK 002 906-BD

Instantaneous residual overcurrent protection (EFPIOC)

Qty: 1 2 3 4

5 6 7 8

1MRK 002 906-CC

Four step residual overcurrent protection (EF4PTOC)

Qty:

1 2 3 4

5 6 7 8

1MRK 002 906-DD

Four step directional negative phase sequenceovercurrent protection (NS4PTOC)

Qty: 1 2 3 4

5 6 7 8

1MRK 002 906-DM

Sensitive directional residual overcurrent and powerprotection (SDEPSDE)

Qty:

1 2 3 1MRK 002 907-DC

Thermal overload protection, one time constant (LPTTR)

Qty:

1 2 1MRK 002 906-LD

Thermal overload protection, two time constants(TRPTTR)

Qty:

1 2 3 4 5 6 1MRK 002 906-NC

Breaker failure protection (CCRBRF)

Qty:

1 2 3 4 5 6 1MRK 002 906-RC

Pole discordance protection (CCRPLD)

Qty:

1 2 1MRK 002 907-AC

Directional underpower protection (GUPPDUP)

Qty:

1 2 1MRK 002 902-FB

Directional overpower protection (GOPPDUP)

Qty:

1 2 1MRK 002 902-GB

Capacitor bank protection (CBPGAPC)

Qty:

1 2 3 4 5 6 1MRK 002 902-MA

Negative sequence time overcurrent protection formachines (NS2PTOC)

Qty:

1 2 1MRK 002 902-LA


ABB 109

Voltage protection

Two step undervoltage protection (UV2PTUV)

Qty:

1 2 3 1MRK 002 908-AC

Two step overvoltage protection (OV2PTOV)

Qty:

1 2 3 1MRK 002 908-DC

Two step residual overvoltage protection (ROV2PTOV)

Qty:

1 2 3 1MRK 002 908-GC

Overexcitation protection (OEXPVPH)

Qty:

1 2 1MRK 002 908-MC

Voltage differential protection (VDCPTOV)

Qty:

1 2 1MRK 002 924-TB


Underfrequency protection (SAPTUF)

Qty:

1 2 3 4 5 6 1MRK 002 908-NC

Overfrequency protection (SAPTOF)

Qty:

1 2 3 4 5 6 1MRK 002 908-RC

Rate-of-change frequency protection (SAPFRC)

Qty:

1 2 3 4 5 6 1MRK 002 908-SB


General current and voltage protection (CVGAPC)

Qty:

1 2 3 4 5 6

7 8 9 10 11 12

1MRK 002 902-AB


Current circuit supervision (CCSRDIF)

Qty:

1 2 3 4 5 1MRK 002 914-AB

Fuse failure supervision (SDDRFUF)

Qty:

1 2 3 4 1MRK 002 914-GC


110 ABB

Control

Synchrocheck, energizing check and synchronizing(SESRSYN)

Qty:

1 2 3 4 5 6 1MRK 002 916-SD

Apparatus control for up to 6 bays, max 30 apparatuses(6CBs) incl. interlocking

1MRK 002 916-RD

Rule: Only one of (TR1ATCC, TR8ATCC) can be ordered.If TR1ATCC or TR8ATCC is ordered then one ofTCMYLTC or TCLYLTC must be ordered.Automatic voltage control for tapchanger, singletransformer (TR1ATCC)

Qty:

1 2 3 4 1MRK 002 916-YC

Automatic voltage control for tapchanger, parallelcontrol (TR8ATCC)

Qty:

1 2 3 4 1MRK 002 916-ZC

Tap changer control and supervision, 6 binary inputs,coded binary (Binary, BCD, Gray) (TCMYLTC)

Qty:

1 2 3 4 1MRK 002 925-PC

Tap changer control and supervision, 32 binary inputs,one per position (TCLYLTC)

Qty:

1 2 3 4 1MRK 002 924-UB


Scheme communication logic for residual overcurrent protection (ECPSCH) 1MRK 002 906-GA

Current reversal and weak end infeed logic for residual overcurrent protection(ECRWPSCH)

1MRK 002 906-HB


Duo driver configuration (DUODRV) 1MRK 002 924-YA

First local HMI user dialogue language

Rule: One must be ordered

HMI language, English IEC 1MRK 002 930-AA

HMI language, English US 1MRK 002 930-BA

Additional local HMI user dialogue language

Rule: Maximum one alternative

HMI language, German 1MRK 002 920-AB

HMI language, Spanish 1MRK 002 920-DB

HMI language, Swedish 1MRK 002 920-KB

Optional hardware


ABB 111

Human machine hardware interface

Rule: One must be ordered. “Medium size - graphic display” HMI is required inorder to be able to give Raise/Lower commands, in the manual operating mode, tothe OLTC from IED 670 via Voltage control (VCTR) function.

Display type Keypad symbol Case size

Small, alpha numeric IEC 1/2 19" 1MRK 000 008-HB

Small, alpha numeric IEC 3/4 19" 1MRK 000 008-PB

Small, alpha numeric IEC 1/1 19" 1MRK 000 008-KB

Medium, graphic display IEC 1/2 19" 1MRK 000 008-LB

Medium, graphic display IEC 1/1 19" 1MRK 000 008-MB

Medium, graphic display IEC 3/4 19" 1MRK 000 008-NB

Medium, graphic display ANSI 1/2 19" 1MRK 000 008-LC

Medium, graphic display ANSI 3/4 19" 1MRK 000 008-NC

Medium, graphic display ANSI 1/1 19" 1MRK 000 008-MC


112 ABB

Analog system

Rule: One Transformer input module must be orderedNote: The same type of connection terminals has to be ordered for both TRMs

Transformer input module, compression terminals 12I, 1A, 50/60 Hz

Qty:

1 2 1MRK 002 247-CG


Qty:

1 2 1MRK 002 247-CH

Transformer input module, compression terminals 9I+3U, 1A, 50/60 Hz

Qty:

1 2 1MRK 002 247-BG


Qty:

1 2 1MRK 002 247-BH

Transformer input module, compression terminals 5I, 1A+4I, 5A+3U,50/60 Hz

Qty:

1 2 1MRK 002 247-BK


Qty:

1 2 1MRK 002 247-AP


Qty:

1 2 1MRK 002 247-AR


Qty:

1 2 1MRK 002 247-AU


Qty:

1 2 1MRK 002 247-AV

Transformer input module, compression terminals 3IM, 1A+4IP, 1A+5U,50/60 Hz

Qty: 1 2 1MRK 002 247-EA

Transformer input module, compression terminals 3IM, 5A+4IP, 5A+5U,50/60 Hz

Qty: 1 2 1MRK 002 247-EB


Qty:

1 2 1MRK 002 247-AG


Qty:

1 2 1MRK 002 247-AH


Qty:

1 2 1MRK 002 247-AE


Qty:

1 2 1MRK 002 247-DH


Qty:

1 1MRK 002 247-DG


ABB 113


Qty:

1 1MRK 002 247-DH

Transformer input module, ring lug terminals 12I, 1A, 50/60 Hz

Qty:

1 2 1MRK 002 247-CC


Qty:

1 2 1MRK 002 247-CD

Transformer input module, ring lug terminals 9I+3U, 1A, 50/60 Hz

Qty:

1 2 1MRK 002 247-BC

Transformer input module, ring lug terminals 9I+3U, 5A, 50/60 Hz Qty:

1 2 1MRK 002 247-BD

Transformer input module, ring lug terminals 5I, 1A+4I, 5A+3U,50/60 Hz

Qty:

1 2 1MRK 002 247-BF


Qty: 1 2 1MRK 002 247-AS

Transformer input module, ring lug terminals 7I+5U, 5A, 50/60 Hz Qty:

1 2 1MRK 002 247-AT


Qty:

1 2 1MRK 002 247-AX


Qty:

1 2 1MRK 002 247-AY

Transformer input module, ring lug terminals 3IM, 1A+4IP, 1A+5U,50/60 Hz

Qty: 1 2 1MRK 002 247-EC

Transformer input module, ring lug terminals 3IM, 5A+4IP, 5A+5U,50/60 Hz

Qty: 1 2 1MRK 002 247-ED


Qty:

1 2 1MRK 002 247-AC


Qty:

1 2 1MRK 002 247-AD


Qty:

1 2 1MRK 002 247-AF


114 ABB


Qty:

1 1MRK 002 247-DC


Qty:

1 1MRK 002 247-DD

Note: One Analog digital conversion module, with time synchronization is always delivered with each Transformerinput module.

Case size

When ordering I/O modules, observe the maximum quantities according to tables below.

Note: Standard order of location for I/O modules is BIM-BOM-SOM-IOM-MIM from left to right as seen from therear side of the IED, but can also be freely placed.

Note: Maximum quantity of I/O modules depends on the type of connection terminals.

Maximum quantity of I/O modules

Case sizes BIM IOM BOM/SOM

MIM Maximum in case

1/1 x 19”, one (1) TRM 14 6 4 4 14 (max 4 BOM+SOM+MIM)

1MRK 000 151-NC

1/1 x 19”, two (2) TRM 11 6 4 4 11 (max 4 BOM+SOM+MIM)

1MRK 000 151-ND

3/4 x 19”, one (1) TRM 8 6 4 1 8 (max 4 BOM+SOM+1MIM)

1MRK 000 151-NB

3/4 x 19”, two (2) TRM 5 5 4 1 5 (max 4 BOM+SOM+1MIM)

1MRK 000 151-NE

1/2 x 19”, one (1) TRM 3 3 3 0 3 1MRK 000 151-NA

Maximum quantity of I/O modules, with ring lug terminals,module limits see above

Case sizes Maximum in case Possible locations for I/O moduleswith ringlugs

1/1 x 19”, one (1) TRM 7 P3, P5, P7, P9, P11, P13, P15 1MRK 000 151-NC

1/1 x 19”, two (2) TRM 5 P3, P5, P7, P9, P11 1MRK 000 151-ND

3/4 x 19”, one (1) TRM 4 P3, P5, P7, P9 1MRK 000 151-NB

3/4 x 19”, two (2) TRM 2 P3, P5 1MRK 000 151-NE

1/2 x 19”, one (1) TRM 1 P3 1MRK 000 151-NA


ABB 115

Binary input/output modules

Make BIM with 50 mA inrush current the primary choice. BIM with 50 mA inrush currentfulfill additional standards. As a consequence the EMC withstand capability is furtherincreased.BIM with 30 mA inrush current is still available.For pulse counting, for example kWh metering, the BIM with enhanced pulse countingcapabilities must be used.

Binary input module (BIM) 16 inputs

RL 24-30 VDC, 30 mA Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-DB

RL 48-60 VDC, 30 mA Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-AB

RL 110-125 VDC, 30 mA Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-BB

RL 220-250 VDC, 30 mA Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-CB

RL 24-30 VDC, 50 mA Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-DD

RL 48-60 VDC, 50 mA Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-AD

RL 110-125 VDC, 50 mA Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-BD


116 ABB

RL 220-250 VDC, 50 mA Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-CD

Binary input module (BIM) with enhanced pulsecounting capabilities, 16 inputs

RL 24-30 VDC Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-HA

RL 48-60 VDC Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-EA

RL 110-125 VDC Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-FA

RL 220-250 VDC Qty: 1 2 3 4 5 6

8 9 10 11 12 13

7

14

1MRK 000 508-GA

Binary output module 24 output relays (BOM) Qty: 1 2 3 4 1MRK 000 614-AB

Static binary output module (SOM)

RL 48-60 VDC Qty: 1 2 3 4 1MRK 002 614-BA

RL 110-250 VDC Qty: 1 2 3 4 1MRK 002 614-CA


ABB 117

Make IOM with 50 mA inrush current the primary choice. IOM with 50 mA inrush currentfulfill additional standards. As a consequence the EMC withstand capability is furtherincreased.IOM with 30 mA inrush current is still available.

Binary input/output module (IOM) 8 inputs, 10 outputs, 2 high-speed outputs

RL 24-30 VDC, 30 mA Qty: 1 2 3 4 5 6 1MRK 000 173-GB

RL 48-60 VDC, 30 mA Qty: 1 2 3 4 5 6 1MRK 000 173-AC

RL 110-125 VDC, 30 mA Qty: 1 2 3 4 5 6 1MRK 000 173-BC

RL 220-250 VDC, 30 mA Qty: 1 2 3 4 5 6 1MRK 000 173-CC

RL 24-30 VDC, 50 mA Qty: 1 2 3 4 5 6 1MRK 000 173-GD

RL 48-60 VDC, 50 mA Qty: 1 2 3 4 5 6 1MRK 000 173-AE

RL 110-125 VDC, 50 mA Qty: 1 2 3 4 5 6 1MRK 000 173-BE

RL 220-250 VDC, 50 mA Qty: 1 2 3 4 5 6 1MRK 000 173-CE

Binary input/output module (IOM with MOV), 8 inputs, 10 outputs, 2 high-speed outputs

RL 24-30 VDC Qty: 1 2 3 4 5 6 1MRK 000 173-GC

RL 48-60 VDC Qty: 1 2 3 4 5 6 1MRK 000 173-AD

RL 110-125 VDC Qty: 1 2 3 4 5 6 1MRK 000 173-BD

RL 220-250 VDC Qty: 1 2 3 4 5 6 1MRK 000 173-CD

mA input module 6 channels (MIM) Qty: 1 2 3 4 1MRK 000 284-AB


118 ABB

Station communication ports

Note: Optical ethernet module, 2 glass interfaces is not allowed together with SLM.

Optical ethernet module, 1 channel glass 1MRK 002 266-AA

Optical ethernet module, 2 channel glass 1MRK 002 266-BA

Serial and LON communication module, supports SPA/IEC 60870-5-103, LON and DNP3.0

Serial/LON plastic interface 1MRK 001 608-AA

Serial plastic/LON glass interface 1MRK 001 608-BA

Serial/LON glass interface 1MRK 001 608-CA

Serial IEC 60870-5-103 plastic interface 1MRK 001 608-DA

Serial IEC 60870-5-103 plastic/glass interface 1MRK 001 608--EA

Serial IEC 60870-5-103 glass interface 1MRK 001 608-FA

Galvanic RS485 communication module for DNP 3.0 1MRK 002 309-AA

Remote end serial communication for C37.94

Rule: Max two LDCM can be ordered

Optical short range line data communication module(Multi mode 850 nm) (SR LDCM)

Qty:

1 2 1MRK 002 122-AB

Optical medium range line data communication module(Single mode 1310 nm) (MR LDCM)

Qty:

1 2 1MRK 002 311-AA

Time synchronization

Rule: Only one Time synchronization can be ordered.

GPS Time module (GTM) 1MRK 002 282-AB

IRIG-B Time synchronization module 1MRK 002 305-AA

Engineering facilities

19” rack mounting kit for 1/2 x 19” case or 2 x RHGS6 or RHGS12 Quantity: 1MRK 002 420-BB

19” rack mounting kit for 3/4 x 19” case or 3 x RHGS6 Quantity: 1MRK 002 420-BA

19” rack mounting kit for 1/1 x 19” case Quantity: 1MRK 002 420-CA


ABB 119

Note: Wall mounting not recommended with communication moduleswith fibre connection (SLM, OEM, LDCM)Wall mounting kit for terminal

Quantity: 1MRK 002 420-DA

Flush mounting kit for terminal Quantity: 1MRK 000 020-Y

Flush mounting kit + IP54 sealing (factory mounted). Cannot beordered separately thus must be specified when ordering a terminal.

Quantity: 1MRK 002 420-EA

Accessories

GPS antenna and mounting details

GPS antenna, including mounting kits Quantity: 1MRK 001 640-AA

Cable for antenna, 20 m Quantity: 1MRK 001 665-AA

Cable for antenna, 40 m Quantity: 1MRK 001 665-BA

Interface converter (for remote end data communication)

External interface converter from C37.94 to G703 Quantity: 1 2 1MRK 002 245-AA

External interface converter from C37.94 to G703.E1 Quantity: 1 2 1MRK 002 245-BA

Test switch

The test system COMBITEST intended for usewith the IED 670 products is described in1MRK 512 001-BEN and 1MRK 001024-CA.Please refer to the website: www.abb.com/substationautomation for detailed information.

Due to the high flexibility of our product andthe wide variety of applications possible thetest switches needs to be selected for eachspecific application.

Select your suitable test switch based on theavailable contacts arrangements shown in thereference documentation.

However our proposals for suitable variantsare:

Two winding transformer with internalneutral on current circuits. Two pcs can beused in applications for three windingtransformers in single or multi-breakerarrangement (ordering number RK926 215-BD)

Two winding transformer with externalneutral on current circuits. Two pcs can beused in applications for three windingtransformers in single or multi-breakerarrangement (ordering number RK926 215-BH).

Three winding transformer with internalneutral on current circuits (ordering numberRK926 215-BX).

The normally open "In test mode" contact29-30 on the RTXP test switches should beconnected to the input of the test function


120 ABB

HTTP://WWW.ABB.COM/SUBSTATIONAUTOMATION


block to allow activation of functionsindividually during testing.

Test switches type RTXP 24 is orderedseparately. Please refer to Section "Relateddocuments" for reference to correspondingdocuments.

RHGS 6 Case or RHGS 12 Case with mountedRTXP 24 and the on/off switch for dc-supplyare ordered separately. Please refer to Section"Related documents" for reference tocorresponding documents.

Protection cover

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-AC

Protective cover for rear side of terminal, 6U, 3/4 x 19” Quantity: 1MRK 002 420-AB

Protective cover for rear side of terminal, 6U, 1/1 x 19” Quantity: 1MRK 002 420-AA

External resistor unit

High impedance resistor unit 1-ph with resistor and voltagedependent resistor for 20-100V operating voltage

Quantity:

1 2 3 RK795101-MA


Quantity: RK795101-MB


Quantity:

1 2 3 RK795101-CB


Quantity: RK795101-DC

Combiflex

Key switch for settings

Key switch for lock-out of settings via LCD-HMI Quantity: 1MRK 000 611-A

Note: To connect the key switch, leads with 10 A Combiflex socket on one end must be used.

Side-by-side mounting kit Quantity: 1MRK 002 420-Z

Configuration and monitoring tools

Front connection cable between LCD-HMI and PC Quantity: 1MRK 001 665-CA


ABB 121

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

Note: One (1) IED Connect CD containing user documentation (Operator’s manual, Technical referencemanual, Installation and 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 CD requested. Quantity: 1MRK 002 290-AB

User documentation

Rule: Specify the number of printed manuals requestedOperator’s manual

IEC Quantity: 1MRK 504 114-UEN

ANSI Quantity: 1MRK 504 114-UUS

Technical reference manual IEC Quantity: 1MRK 504 113-UEN


Installation and commissioning manual IEC Quantity: 1MRK 504 115-UEN


Application manual IEC Quantity: 1MRK 504 116-UEN


Engineering guide IED 670 products Quantity: 1MRK 511 179-UEN


122 ABB

Reference information

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

Documents related to RET670 Identity number

Operator’s manual 1MRK 504 114-UEN

Installation and commissioning manual 1MRK 504 115-UEN

Technical reference manual 1MRK 504 113-UEN

Application manual 1MRK 504 116-UEN

Product guide customized 1MRK 504 117-BEN

Product guide pre-configured 1MRK 504 118-BEN

Product guide IEC 61850-9-2 1MRK 504 104-BEN

Sample specification SA2005-001283

Connection and Installation components 1MRK 513 003-BEN

Test system, COMBITEST 1MRK 512 001-BEN

Accessories for 670 series IEDs 1MRK 514 012-BEN

670 series SPA and signal list 1MRK 500 092-WEN

IEC 61850 Data objects list for 670 series 1MRK 500 091-WEN

Engineering manual 670 series 1MRK 511 240-UEN

Communication set-up for Relion 670 series 1MRK 505 260-UEN

More information can be found on www.abb.com/substationautomation.


ABB 123


124

Contact us

ABB ABSubstation Automation ProductsSE-721 59 Västerås, SwedenPhone +46 (0) 21 32 50 00Fax +46 (0) 21 14 69 18

www.abb.com/substationautomation

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