REM615 - Motor

Relion® 615 series

Motor Protection and ControlREM615Product Guide

Contents

1. Description.....................................................................3

2. Standard configuration...................................................3

3. Protection functions........................................................9

4. Application.....................................................................9

5. Supported ABB solutions.............................................11

6. Control.........................................................................13

7. Measurement...............................................................14

8. Disturbance recorder....................................................14

9. Event log......................................................................14

10. Recorded data............................................................14

11. Condition monitoring ..................................................14

12. Trip-circuit supervision.................................................14

13. Self-supervision...........................................................14

14. Fuse failure supervision...............................................15

15. Current circuit supervision...........................................15

16. Access control............................................................15

17. Inputs and outputs......................................................15

18. Station communication................................................16

19. Technical data.............................................................21

20. Local HMI....................................................................46

21. Mounting methods......................................................47

22. IED case and IED plug-in unit......................................47

23. Selection and ordering data.........................................47

24. Accessories and ordering data....................................48

25. Tools...........................................................................49

26. Cyber security.............................................................50

27. Terminal diagrams.......................................................51

28. Certificates..................................................................54

29. References..................................................................54

30. Functions, codes and symbols....................................55

31. Document revision history...........................................57

Disclaimer

The information in this document is subject to change without notice and should not be construed as a commitment by ABB. ABB assumes no responsibility for any

errors that may appear in this document.

© Copyright 2014 ABB.

All rights reserved.

Trademarks

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

trademarks of their respective holders.

Motor Protection and Control 1MRS756890 HREM615 Product version: 5.0

2 ABB

1. DescriptionREM615 is a dedicated motor protection and control IED(intelligent electronic device) designed for the protection,control, measurement and supervision of asynchronousmotors in manufacturing and process industry. REM615 is a

member of ABB’s Relion® product family and part of its 615protection and control product series. The 615 series IEDsare characterized by their compactness and withdrawable-unit design.

Re-engineered from the ground up, the 615 series has beendesigned to unleash the full potential of the IEC 61850standard for communication and interoperability betweensubstation automation devices. Once the standardconfiguration IED has been given the application-specificsettings, it can directly be put into service.

The 615 series IEDs support a range of communicationprotocols including IEC 61850 with GOOSE messaging, IEC61850-9-2 LE (except in RED615), IEC 60870-5-103,

Modbus® and DNP3. Profibus DPV1 communication protocolis supported by using the protocol converter SPA-ZC 302.

2. Standard configurationREM615 is available in four alternative standardconfigurations. The standard signal configuration can bealtered by means of the graphical signal matrix or thegraphical application functionality of the Protection andControl IED Manager PCM600. Further, the applicationconfiguration functionality of the IED supports the creation ofmulti-layer logic functions using various logical elementsincluding timers and flip-flops. By combining protectionfunctions with logic function blocks, the IED configuration canbe adapted to user-specific application requirements.

The IED is delivered from the factory with default connectionsdescribed in the functional diagrams for binary inputs, binaryoutputs, function-to-function connections and alarm LEDs.The positive measuring direction of directional protectionfunctions is towards the outgoing feeder.

Motor Protection and Control 1MRS756890 HREM615 Product version: 5.0 Issued: 2014-01-24

Revision: H

ABB 3

CONDITION MONITORING AND SUPERVISION

1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 01 0 1 0 0 0 1 1 0 0 1 1 0 0 1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 0

ALSO AVAILABLE

- Disturbance and fault recorders- Event log and recorded data- High-Speed Output module (optional)- IED self-supervision - Local/Remote push button on LHMI- User management- Web HMI

ORAND

REMARKS

Optionalfunction

No. ofinstances

Alternative function to be defined when ordering

OR

Io/Uo

Calculatedvalue

3×

CONTROL AND INDICATION 1) MEASUREMENT

MOTOR PROTECTION AND CONTROL IED

PROTECTION LOCAL HMI

Analog interface types 1)

Current transformer

Voltage transformer

1) Conventional transformer inputs

ESTARTESTART

Object Ctrl 2) Ind 3)

CB 1 -

DC 2 3

ES 1 21) Check availability of binary inputs/outputs

from technical documentation2) Control and indication function for

primary object3) Status indication function for primary object

STANDARD CONFIGURATION

RL

ClearESCI

O

Configuration ASystemHMITimeAuthorization

RL

ClearESCI

O

U12 0. 0 kVP 0.00 kWQ 0.00 kVAr

IL2 0 A

A

18×MAPMAP

REM615

- I, Io- Limit value supervision- Load profile record- RTD/mA measurement (optional)- Symmetrical components

4

-

A

6xRTD2xmA

COMMUNICATION

Protocols: IEC 61850-8-1 Modbus®

IEC 60870-5-103 DNP3

Interfaces: Ethernet: TX (RJ45), FX (LC) Serial: Serial glass fiber (ST), RS-485, RS-232/485 D-sub 9, IRIG-B

Redundant protocols: HSR PRP RSTP

MCS 3IMCS 3I

3×ARC

50L/50NL

5×Master Trip

Lockout relay94/86

3I<37

2×I2>M46M

I2>>46R

3Ith>M49M

Is2t n<49, 66, 48, 51LR

3I>>>50P/51P

3I>/Io>BF51BF/51NBF

Ist>51LR

3I>51P-1

Io>>51N-2

Io>51N-1

2×TCSTCM

CBCMCBCM

OPTSOPTM

Io

Io

3I

Io

3×

GUID-4A93E0BB-46C2-4A06-BC4F-50C42B51366F V1 EN

Figure 1. Functionality overview for standard configuration A


4 ABB


1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 01 0 1 0 0 0 1 1 0 0 1 1 0 0 1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 0

ALSO AVAILABLE


ORAND

REMARKS

Optionalfunction

No. ofinstances


OR

Io/Uo

Calculatedvalue

3×





Current transformer

Voltage transformer


ESTARTESTART


CB 1 -

DC 2 3





RL

ClearESCI

O


RL

ClearESCI

O

U12 0. 0 kVP 0.00 kWQ 0.00 kVAr

IL2 0 A

A

18×MAPMAP

REM615


1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 01 0 1 0 0 0 1 1 0 0 1 1 0 0 1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 0

ALSO AVAILABLE


ORAND

REMARKS

Optionalfunction

No. ofinstances


OR

Io/Uo

Calculatedvalue

3×





Current transformer

Voltage transformer


ESTARTESTART


CB 1 -

DC 2 3





RL

ClearESCI

O


RL

ClearESCI

O

U12 0. 0 kVP 0.00 kWQ 0.00 kVAr

IL2 0 A

A

18×MAPMAP

REM615

- I, U, Io, P, Q, E, pf, f- Limit value supervision- Load profile record- RTD/mA measurement (optional)- Symmetrical components

4

3

COMMUNICATION

Protocols: IEC 61850-8-1/-9-2LE Modbus®

IEC 60870-5-103 DNP3



5×Master Trip

Lockout relay94/86

Io>>51N-2

Io>→67N-1

3×ARC

50L/50NL

3I<37

2×I2>M46M

I2>>46R

3Ith>M49M

Is2t n<49, 66, 48, 51LR

3I>>>50P/51P

3I>/Io>BF51BF/51NBF

Ist>51LR

3I>51P-1

CBCMCBCM

FUSEF60

MCS 3IMCS 3I

2×TCSTCM

OPTSOPTM

3U<27

U2>47O-

U1<47U+

2×f>/f<,df/dt81

3I

Io

Io

B

Io

Uo

3I Io

UL1UL2UL3 UL1

UL2

UL3

6xRTD2xmA

3×

UL1

UL2

UL3

GUID-521A1FAA-FF73-4988-BA61-33AA451F33E0 V1 EN

Figure 2. Functionality overview for standard configuration B


ABB 5


1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 01 0 1 0 0 0 1 1 0 0 1 1 0 0 1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 0

ALSO AVAILABLE


ORAND

REMARKS

Optionalfunction

No. ofinstances


OR

Io/Uo

Calculatedvalue

3×





Current transformer

Voltage transformer


ESTARTESTART


CB 1 -

DC 2 3





RL

ClearESCI

O


RL

ClearESCI

O

U12 0. 0 kVP 0.00 kWQ 0.00 kVAr

IL2 0 A

A

18×MAPMAP

REM615


1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 01 0 1 0 0 0 1 1 0 0 1 1 0 0 1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 0

ALSO AVAILABLE


ORAND

REMARKS

Optionalfunction

No. ofinstances


OR

Io/Uo

Calculatedvalue

3×





Current transformer

Voltage transformer


ESTARTESTART


CB 1 -

DC 2 3





RL

ClearESCI

O


RL

ClearESCI

O

U12 0. 0 kVP 0.00 kWQ 0.00 kVAr

IL2 0 A

A

18×MAPMAP

REM615

- I, U, Io, Uo, P, Q, E, pf, f- Limit value supervision- Load profile record- Symmetrical components

4

5

C

COMMUNICATION


IEC 60870-5-103 DNP3



2) One of the five inputs is reserved for future applications

2)

5×Master Trip

Lockout relay94/86

CBCMCBCM

FUSEF60

Io>→67N-1

3U<27

U2>47O-

U1<47U+

2×f>/f<,df/dt81

MCS 3IMCS 3I

2×TCSTCM

OPTSOPTM

3×ARC

50L/50NL

3I<37

2×I2>M46M

I2>>46R

3Ith>M49M

Is2t n<49, 66, 48, 51LR

3I>>>50P/51P

3I>/Io>BF51BF/51NBF

Ist>51LR

3I>51P-1

Io>>51N-2

Uo

Io

3I Io

Io

3I

Io

UL1UL2UL3

UL1

UL2

UL3

UL1

UL2

UL3

Uo

3×

GUID-C6EEADA8-8AB0-4BE0-8D58-97351C7B0D07 V1 EN

Figure 3. Functionality overview for standard configuration C


6 ABB


1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 01 0 1 0 0 0 1 1 0 0 1 1 0 0 1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 0

ALSO AVAILABLE


ORAND

REMARKS

Optionalfunction

No. ofinstances


OR

Io/Uo

Calculatedvalue

3×





Current transformer

Voltage transformer


ESTARTESTART


CB 1 -

DC 2 3





RL

ClearESCI

O


RL

ClearESCI

O

U12 0. 0 kVP 0.00 kWQ 0.00 kVAr

IL2 0 A

A

18×MAPMAP

REM615


1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 01 0 1 0 0 0 1 1 0 0 1 1 0 0 1 0 1 0 0 0 1 1 0 0 1 1 0 01 0 1 1 0 0 1 0 1 1 1 0 0 1 01 1 0 0 1 1 1 0 1 1 0 1 01 0 1 1 0 1 1 0 1 1 0 1 0 0

ALSO AVAILABLE


ORAND

REMARKS

Optionalfunction

No. ofinstances


OR

Io/Uo

Calculatedvalue

3×





Current transformer

Voltage transformer


ESTARTESTART


CB 1 -

DC 2 3





RL

ClearESCI

O


RL

ClearESCI

O

U12 0. 0 kVP 0.00 kWQ 0.00 kVAr

IL2 0 A

A

18×MAPMAP

REM615

- I, U, Io, P, Q, E, pf, f- Limit value supervision- Load profile record- RTD/mA measurement (optional)- Symmetrical components

D

2) One of the five inputs is reserved for future applications

2)

4

5

5×Master Trip

Lockout relay94/86

Io>→67N-1

3U<27

U2>47O-

U1<47U+

2×f>/f<,df/dt81

3×ARC

50L/50NL

3I<37

2×I2>M46M

I2>>46R

3Ith>M49M

Is2t n<49, 66, 48, 51LR

3I>>>50P/51P

3I>/Io>BF51BF/51NBF

Ist>51LR

3I>51P-1

CBCMCBCM

FUSEF60

MCS 3IMCS 3I

2×TCSTCM

OPTSOPTM

Io>>51N-2

3I

Io

Uo

Io

Io

Io

3I

UL1UL2UL3

COMMUNICATION


IEC 60870-5-103 DNP3



UL1

UL2

UL3

3×

GUID-13051FBE-3F18-43EF-9309-7DE749EDA262 V1 EN

Figure 4. Functionality overview for standard configuration D

Table 1. Standard configuration

Description Std.conf.

Motor protection, with current based protection, CB condition monitoring, CB control and optional RTD/mA inputs A

Motor protection with current, voltage and frequency based protection and measurement functions, CB conditionmonitoring, CB control and optional RTD/mA inputs B

Motor protection with current, voltage and frequency based protection and measurements functions, CB conditionmonitoring and CB control C

Motor protection with current, voltage and frequency based protection and measurements functions , CB conditionmonitoring, CB control and sensor inputs for phase currents and phase voltages D


ABB 7

Table 2. Supported functions

Function IEC 61850 A B C D

Protection1)

Three-phase non-directional overcurrent protection, low stage PHLPTOC 1 1 1 1Three-phase non-directional overcurrent protection,instantaneous stage PHIPTOC 1 1 1 1

Non-directional earth-fault protection, low stage EFLPTOC 1 2)

Non-directional earth-fault protection, high stage EFHPTOC 1 2) 1 3) 1 3) 1 3)

Directional earth-fault protection, low stage DEFLPDEF 1 2)4) 1 2)5) 1 3)6)

Three-phase undervoltage protection PHPTUV 1 1 1Positive-sequence undervoltage protection PSPTUV 1 1 1Negative-sequence overvoltage protection NSPTOV 1 1 1Frequency protection FRPFRQ 2 2 2Negative-sequence overcurrent protection for motors MNSPTOC 2 2 2 2Loss of load supervision LOFLPTUC 1 1 1 1Motor load jam protection JAMPTOC 1 1 1 1Motor start-up supervision STTPMSU 1 1 1 1Phase reversal protection PREVPTOC 1 1 1 1Thermal overload protection for motors MPTTR 1 1 1 1Circuit breaker failure protection CCBRBRF 1 1 1 1Master trip TRPPTRC 2(5) 7) 2 (5) 7) 2 (5) 7) 2 (5) 7)

Arc protection ARCSARC (3) (3) (3) (3)

Multi-purpose protection 8) MAPGAPC 18 18 18 18ControlCircuit-breaker control CBXCBR 1 1 1 1Disconnector control DCXSWI 2 2 2 2Earthing switch control ESXSWI 1 1 1 1Disconnector position indication DCSXSWI 3 3 3 3Earthing switch indication ESSXSWI 2 2 2 2Emergency startup ESMGAPC 1 1 1 1Condition monitoringCircuit-breaker condition monitoring SSCBR 1 1 1 1Trip circuit supervision TCSSCBR 2 2 2 2Current circuit supervision CCRDIF 1 1 1 1Fuse failure supervision SEQRFUF 1 1 1Runtime counter for machines and devices MDSOPT 1 1 1 1MeasurementDisturbance recorder RDRE 1 1 1 1Load profile record LDPMSTA 1 1 1 1Three-phase current measurement CMMXU 1 1 1 1Sequence current measurement CSMSQI 1 1 1 1Residual current measurement RESCMMXU 1 1 1 1Three-phase voltage measurement VMMXU 1 1 1Residual voltage measurement RESVMMXU 1 Sequence voltage measurement VSMSQI 1 1 1Three-phase power and energy measurement PEMMXU 1 1 1RTD/mA measurement XRGGIO130 (1) (1) Frequency measurement FMMXU 1 1 1

IEC 61850-9-2 LE (Voltage sharing) 9) SMVSENDER (1) (1) (1)1, 2, ... = number of included instances() = optional

1) The instances of a protection function represent the number of identical protection function blocks available in the standard configuration.2) Io selectable by parameter, "Io measured" as default3) Io selectable by parameter, "Io calculated" as default4) Uo calculated and negative sequence voltage selectable by parameter, "Uo calculated" as default5) Uo selectable by parameter, "Uo measured" as default6) "Uo calculated" is always used.7) Master trip included and connected to the corresponding HSO in the configuration only when the BIO0007 module is used. If the ARC option is selected additionally, ARCSARC is

connected to the corresponding master trip input in the configuration.8) Multi-purpose protection is used, for example, for RTD/mA-based protection or analog GOOSE.


8 ABB

9) Only available with COM0031-COM0034

3. Protection functionsThe IED offers all the functionality needed to manage motorstarts and normal operation, also including protection andfault clearance in abnormal situations. The main features ofthe IED include thermal overload protection, motor start-uptime supervision, locked rotor protection and protectionagainst too frequent motor starts. The IED also incorporatesnon-directional earth-fault protection, negative phase-sequence current unbalance protection and backupovercurrent protection. Furthermore, the IED offers motorrunning stall protection, loss-of-load supervision and phase-reversal protection.

Standard configurations B, C and D additionally offerdirectional earth-fault protection, three phase undervoltageprotection, negative phase-sequence overvoltage andpositive sequence undervoltage protection. Further, the B, Cand D configurations offer frequency protection includingoverfrequency, underfrequency and rate-of-change frequencyprotection modes.

The RTD/mA module offered as an option for standardconfigurations A and B enable the use of the optionalmultipurpose protection function which can be used fortripping and alarm purposes using RTD/mA measuring dataor analog values via GOOSE messages.

In certain motor drives of special importance there must be apossibility to override the motor thermal overload protectionto perform an emergency start of a hot motor. To enable anemergency hot start, REM615 offers a forced start executionfeature.

Enhanced with optional hardware and software, the IED alsofeatures three light detection channels for arc fault protectionof the circuit breaker, busbar and cable compartment ofmetal-enclosed indoor switchgear.

The arc-fault protection sensor interface is available on theoptional communication module. Fast tripping increases staffsafety and security and limits material damage in an arc faultsituation. A binary input and output module can be selectedas an option - having three high speed binary outputs (HSO) itfurther decreases the total operate time with typically 4...6 mscompared to the normal power outputs.

4. ApplicationREM615 constitutes main protection for asynchronousmotors and the associated drives. Typically, the motor IED is

used with circuit breaker or contactor controlled HV motors,and contactor controlled medium sized and large LV motorsin a variety of drives, such as pumps and conveyors, crushersand choppers, mixers and agitators, fans and aerators.

The motor IED is thoroughly adapted for earth-faultprotection. Using cable current transformers sensitive andreliable earth-fault protection can be achieved. Phase currenttransformers in Holmgreen (summation) connection can alsobe used for earth-fault protection. In that case possibleunwanted operations of the earth-fault protection at motorstart-up due to CT saturation can be prevented using theIED's internal interlocking features or a suitable stabilizingresistor in the common neutral return.

The optional RTD/mA module offered for standardconfigurations A and B facilitates the measurement of up toeight analog signals via the six RTD inputs or the two mAinputs using transducers. The RTD and mA inputs can beused for temperature monitoring of motor bearings and statorwindings, thus expanding the functionality of the thermaloverload protection and preventing premature aging of themotor. Furthermore, the RTD/mA inputs can be used formeasuring the ambient cooling air temperature. The analogtemperature values can, if required, be sent to other IEDsusing analog horizontal GOOSE messaging. Temperaturevalues can also, vice versa, be received from other IEDs overthe station bus, thus increasing the extent of relevantinformation.

The standard configuration D includes one conventionalresidual current (Io) input and three combi-sensor inputs forphase currents and phase voltages. The connection of thethree combi-sensors is made with RJ-45 type of connectors.

Sensors offer certain benefits compared to conventionalcurrent and voltage instrument transformers, for example,current sensors are not saturating at high currents, theyconsume less energy and they have a lower weight while involtage sensors the risk of ferro-resonance is eliminated. Thesensor inputs also enable the use of the IED in compactmedium voltage switchgears, such as ABB’s UniGear Digital,SafeRing and SafePlus, with limited space for conventionalmeasuring transformers, thus requiring the use of sensortechnology. Further, the adapters also enable the use ofsensors with Twin-BNC connectors.


ABB 9

3U Uo

REU615Std. conf.

ANSI IEC

47O-/59

47U+/27

50L/50NL1)

59G

81

81LSH

U2>/3U>

U1</3U<

ARC1)

Uo>

f</f>,df/dt

UFLS/R

A

Io

3I

Io

3I

REM615Std. conf.

ANSI IEC

37

46R

47O-/59

47U+/27

49,66,48,51LR

49M

50L/50NL

50N/51N-1/51N-2

50P/51P

51LR

51P/51N

3I<

I2>>

U2>/3U>

U1</3U<

Is2t n<

3Ith>M

ARC

Io>>>/Io>>/Io>

3I>>>

Ist>

3I/Io

B

RTD RTD

1) Light detection only

Io

3I

REF615Std. conf.

ANSI IEC

46

50L/50NL

50P/51P

50N/51N-1/51N-2

51BF/51NBF

68

I2>

ARC

3I>>>

Io>>>/Io>>/Io>

3I>/Io>BF

3I2f>

C/D

REM615Std. conf.

ANSI IEC

37

46R

49,66,48,51LR

49M

50L/50NL

50N/51N-1/51N-2

50P/51P

51LR

51P/51N

3I<

I2>>

Is2t n<

3Ith>M

ARC

Io>>>/Io>>/Io>

3I>>>

Ist>

3I/Io

A

GUID-52860380-D410-4969-A44E-7C7311221D0F V4 EN

Figure 5. Motor protection and control of contactor and circuit breaker controlled motors using standard configurations A and B

Example of motor protection and control of contactor andcircuit breaker controlled motors using standardconfigurations A and B. To prevent possible power systeminstability due to busbar voltage collapse, the simultaneous

starting of several motors can be inhibited over "restartinhibit" input of REM615. The optional RTD/mA inputs areutilized for motor winding and bearing temperaturesupervision.


10 ABB

Io

3I

3U

RTD

Io

3I

3U

RTD

Io

3I

3U

REF615Std. conf.

ANSI IEC

47O-/59

47U+/27

50L/50NL

50P/51P

51BF/51NBF

67

U2>/3U>

U1</3U<

ARC

3I>>>

3I>/Io>BF

3I→

L

REM615Std. conf.

ANSI IEC

37

46R

47O-/59

47U+/27

49,66,48,51LR

49M

50L/50NL

50P/51P

51LR

51P/51N

3I<

I2>>

U2>/3U>

U1</3U<

Is2t n<

3Ith>M

ARC

3I>>>

Ist>

3I/Io

D

REM615Std. conf.

ANSI IEC

37

46R

47O-/59

47U+/27

49,66,48,51LR

49M

50L/50NL

50P/51P

51LR

51P/51N

3I<

I2>>

U2>/3U>

U1</3U<

Is2t n<

3Ith>M

ARC

3I>>>

Ist>

3I/Io

D

GUID-1D463521-838D-4518-BFE5-438DD6F8E0A8 V1 EN

Figure 6. Motor protection and control of contactor and circuit breaker controlled motors using standard configuration D

Example of motor protection and control of contactor andcircuit breaker controlled motors using standard configurationD. In this configuration current sensors (Rogowski coil) andvoltage sensors (voltage divider) are used for themeasurements. To prevent possible power system instabilitydue to busbar voltage collapse, the simultaneous starting ofseveral motors can be inhibited over "restart inhibit" input of

REM615. The optional RTD/mA inputs are utilized for motorwinding and bearing temperature supervision.

The standard configuration D has been pre-configuredespecially for ABB switchgears, for example, UniGear Digital.The use of this configuration is not restricted for that purposeonly.

5. Supported ABB solutionsABB’s 615 series protection and control IEDs together withthe grid automation controller COM600 constitute a genuineIEC 61850 solution for reliable power distribution in utility andindustrial power systems. To facilitate and streamline thesystem engineering, ABB's IEDs are supplied withconnectivity packages. The connectivity packages include acompilation of software and IED-specific information,

including single-line diagram templates and a full IED datamodel. The data model also includes event and parameterlists. With the connectivity packages, the IEDs can be readilyconfigured using PCM600 and integrated with the gridautomation controller COM600 or the network control andmanagement system MicroSCADA Pro.


ABB 11

The 615 series IEDs offer native support for the IEC 61850standard also including binary and analog horizontal GOOSEmessaging. In addition, process bus with sampled values ofanalog phase voltages is supported. Process bus withsampled values of analog phase voltages is also supported.Compared to traditional hard-wired, inter-device signaling,peer-to-peer communication over a switched Ethernet LANoffers an advanced and versatile platform for power systemprotection. Among the distinctive features of the protectionsystem approach, enabled by the full implementation of theIEC 61850 substation automation standard, are fastcommunication capability, continuous supervision of theintegrity of the protection and communication system, and aninherent flexibility regarding reconfiguration and upgrades.

At substation level, COM600 uses the data content of the bay-level IEDs to enhance substation level functionality. COM600features a Web browser-based HMI, which provides acustomizable graphical display for visualizing single-line mimicdiagrams for switchgear bay solutions. The SLD feature isespecially useful when 615 series IEDs without the optionalsingle-line diagram feature are used. The Web HMI ofCOM600 also provides an overview of the whole substation,including IED-specific single-line diagrams, which makesinformation easily accessible. Substation devices and

processes can also be remotely accessed through the WebHMI, which improves personnel safety.

In addition, COM600 can be used as a local data warehousefor the substation's technical documentation and for thenetwork data collected by the IEDs. The collected networkdata facilitates extensive reporting and analyzing of networkfault situations, by using the data historian and event handlingfeatures of COM600. The history data can be used foraccurate monitoring of process and equipment performance,using calculations based on both real-time and history values.A better understanding of the process dynamics is achievedby combining time-based process measurements withproduction and maintenance events.

COM600 can also function as a gateway and providesseamless connectivity between the substation IEDs andnetwork-level control and management systems, such asMicroSCADA Pro and System 800xA.

GOOSE Analyzer interface in COM600 enables the followingand analyzing the horizontal IEC 61850 application duringcommissioning and operation at station level. It logs allGOOSE events during substation operation to enableimproved system supervision.

Table 3. Supported ABB solutions

Product Version

Grid automation controller COM600 4.0 SP1 or later

MicroSCADA Pro SYS 600 9.3 FP2 or later

System 800xA 5.1 or later


12 ABB

PCM600Ethernet switch

Utility: IEC 60870-5-104Industry: OPC

COM600Web HMI

ABBMicroSCADA Pro/

System 800xA

Analog and binary horizontal GOOSE communication IEC 61850

PCM600Ethernet switch

COM600Web HMI

Analog and binary horizontal GOOSE communication IEC 61850

GUID-4D002AA0-E35D-4D3F-A157-01F1A3044DDB V1 EN

Figure 7. ABB power system example using Relion IEDs, Grid Automation controller COM600 and MicroSCADA Pro/System 800xA

6. ControlREM615 integrates functionality for the control of a circuitbreaker via the front panel HMI or by means of remotecontrols. In addition to the circuit breaker control the IEDfeatures two control blocks which are intended for motor-operated control of disconnectors or circuit breaker truck andfor their position indications. Further, the IED offers onecontrol block which is intended for motor-operated control ofone earthing switch control and its position indication.

Two physical binary inputs and two physical binary outputsare needed in the IED for each controllable primary devicetaken into use. Depending on the chosen standardconfiguration of the IED the number of unused binary inputsand binary outputs varies. Further, some standardconfigurations also offer optional hardware modules thatincrease the number of available binary inputs and outputs.

In case the amount of available binary inputs and/or outputsof the chosen standard configuration is not sufficient, thefollowing alternatives are recommended:

• To modify the chosen standard configuration of the IED inorder to release some binary inputs or binary outputs whichhave originally been configured for other purposes, whenapplicable.

• To integrate an external input or output module forexample, RIO600 to the IED. The binary inputs and outputsof the external I/O module can be used for the less timecritical binary signals of the application. The integrationenables releasing of some initially reserved binary inputsand outputs of the IED in the standard configuration.

The suitability of the binary outputs of the IED which havebeen selected for controlling of primary devices should becarefully verified, for example the make and carry as well asthe breaking capacity. In case the requirements for thecontrol-circuit of the primary device are not met, the use ofexternal auxiliary relays should to be considered.

The optional large graphical LCD of the IED's HMI includes asingle-line diagram (SLD) with position indication for therelevant primary devices. Interlocking schemes required by


ABB 13

the application are configured using the signal matrix or theapplication configuration functionality of PCM600.

The IED is provided with a load profile recorder. The loadprofile feature stores the historical load data captured at aperiodical time interval (demand interval). The records are inCOMTRADE format.

7. MeasurementThe IED continuously measures the phase currents and theneutral current. Furthermore, the IED measures the phasevoltages and the residual voltage. Depending on the standardconfiguration, the IED also offers frequency measurement. Inaddition, the IED calculates the symmetrical components ofthe currents and voltages, maximum current demand valueover a user-selectable pre-set time frame, the active andreactive power, the power factor and the active and reactiveenergy values. Calculated values are also obtained from theprotection and condition monitoring functions of the IED.

For standard configuration A and B RTD/mA inputs areoffered as an option. By means of the optional RTD/mAmodule the IED can measure up to eight analog signals suchas stator winding and bearing temperatures via the six RTDinputs or the two mA inputs using transducers.

The values measured can be accessed locally via the userinterface on the IED front panel or remotely via thecommunication interface of the IED. The values can also beaccessed locally or remotely using the Web browser-baseduser interface.

8. Disturbance recorderThe IED is provided with a disturbance recorder with up to 12analog and 64 binary signal channels. The analog channelscan be set to record either the waveform or the trend of thecurrents and voltages measured.

The analog channels can be set to trigger the recordingfunction when the measured value falls below, or exceeds,the set values. The binary signal channels can be set to starta recording either on the rising or the falling edge of thebinary signal or on both.

By default, the binary channels are set to record external orinternal IED signals, for example, the start or trip signals ofthe IED stages, or external blocking or control signals. BinaryIED signals, such as protection start and trip signals, or anexternal IED control signal via a binary input, can be set totrigger the recording. The recorded information is stored in anon-volatile memory and can be uploaded for subsequentfault analysis.

9. Event logTo collect sequence-of-events information, the IED has a non-volatile memory with a capacity of storing 1024 events with

associated time stamps. The non-volatile memory retains itsdata also in case the IED temporarily loses its auxiliary supply.The event log facilitates detailed pre- and post-fault analysesof feeder faults and disturbances. The increased capacity toprocess and store data and events in the IED offersprerequisites to support the growing information demand offuture network configurations.

The sequence-of-events information can be accessed eitherlocally via the user interface on the IED front panel, orremotely via the communication interface of the IED. Theinformation can also be accessed using the Web browser-based user interface, either locally or remotely.

10. Recorded dataThe IED has the capacity to store the records of the 128latest fault events. The records enable the user to analyze thepower system events. Each record includes current, voltageand angle values, time stamp and so on. The fault recordingcan be triggered by the start signal or the trip signal of aprotection block, or by both. The available measurementmodes include DFT, RMS and peak-to-peak. Fault recordsstore IED measurement values at the moment when anyprotection function starts. In addition, the maximum demandcurrent with time stamp is separately recorded. By default,the records are stored in the nonvolatile memory.

11. Condition monitoringThe condition monitoring functions of the IED constantlymonitors the performance and the condition of the circuitbreaker. The monitoring comprises the spring charging time,SF6 gas pressure, the travel time and the inactivity time of thecircuit breaker.

The monitoring functions provide operational circuit breakerhistory data, which can be used for scheduling preventivecircuit breaker maintenance.

In addition, the IED includes a runtime counter for monitoringof how many hours the motor has been in operation thusenabling scheduling of time-based preventive maintenance ofthe motor.

12. Trip-circuit supervisionThe trip-circuit supervision continuously monitors theavailability and operability of the trip circuit. It provides open-circuit monitoring both when the circuit breaker is in itsclosed and in its open position. It also detects loss of circuit-breaker control voltage.

13. Self-supervisionThe IED’s built-in self-supervision system continuouslymonitors the state of the IED hardware and the operation ofthe IED software. Any fault or malfunction detected is usedfor alerting the operator.


14 ABB

A permanent IED fault blocks the protection functions toprevent incorrect operation.

14. Fuse failure supervisionThe IED includes fuse failure supervision functionality. Thefuse failure supervision detects failures between the voltagemeasurement circuit and the IED. The failures are detectedeither by the negative sequence-based algorithm or by thedelta voltage and delta current algorithm. Upon the detectionof a failure, the fuse failure supervision function activates analarm and blocks voltage-dependent protection functionsfrom unintended operation.

15. Current circuit supervisionThe IED includes current circuit supervision. Current circuitsupervision is used for detecting faults in the currenttransformer secondary circuits. On detecting of a fault thecurrent circuit supervision function activates an alarm LEDand blocks certain protection functions to avoid unintendedoperation. The current circuit supervision function calculatesthe sum of the phase currents from the protection cores andcompares the sum with the measured single reference currentfrom a core balance current transformer or from separatecores in the phase current transformers.

16. Access controlTo protect the IED from unauthorized access and to maintaininformation integrity, the IED is provided with a four-level, role-based authentication system with administrator-programmable individual passwords for the viewer, operator,engineer and administrator level. The access control appliesto the front-panel user interface, the Web browser-baseduser interface and PCM600.

17. Inputs and outputsThe IED is equipped with three phase-current inputs, oneresidual-current input, three phase-voltage inputs and oneresidual voltage input. The phase-current inputs and theresidual current inputs are rated 1/5 A, that is, the inputsallow connection of either 1 A or 5 A secondary current

transformers. The optional residual-current input 0.2/1 A isnormally used in applications requiring sensitive earth-faultprotection and featuring core-balance current transformers.The three phase-voltage inputs and the residual-voltage inputcovers the rated voltages 60-210 V. Both phase-to-phasevoltages and phase-to-earth voltages can be connected.

The standard configuration D includes one conventionalresidual current (Io 0.2/1 A) input and three sensor inputs forthe direct connection of three combi-sensors with RJ-45connectors. As an alternative to combi-sensors, separatecurrent and voltage sensors can be utilized using adapters.Furthermore, the adapters also enable the use of sensorswith Twin-BNC connectors.

The rated values of the current and voltage inputs aresettable parameters of the IED. In addition, the binary inputthresholds are selectable within the range of 16…176 V DCby adjusting the IED’s parameter settings.

All binary inputs and outputs contacts are freely configurablewith the signal matrix or application configuration functionalityof PCM600.

As an option for standard configurations A and B, the IEDoffers six RTD inputs and two mA inputs. By means of theoptional RTD/mA module the IED can measure up to eightanalog signals such as temperature, pressure and tapchanger position values via the six RTD inputs or the two mAinputs using transducers. The values can, apart frommeasuring and monitoring purposes, be used for tripping andalarm purposes using the offered optional multipurposeprotection functions.

Optionally, a binary input and output module can be selected.It has three high speed binary outputs (HSO) and it decreasesthe total operate time with typically 4...6 ms compared to thenormal power outputs.

Please refer to the Input/output overview table and theterminal diagrams for more detailed information about theinputs and outputs.


ABB 15

Table 4. Input/output overview

Std. conf. Order code digit Analog channels Binary channels

5-6 7-8 CT VT Combisensor

BI BO RTD mA

A

AC / AD

AB 4 - - 4 4 PO + 2 SO - -

AD 4 - - 12 4 PO + 6 SO - -

FE 4 - - 12 4 PO + 2SO + 3 HSO

- -

AG / AH AB 4 - - 4 4 PO + 2SO6

6 2

B

CA / CB

AH 4 3 - 8 4 PO + 6 SO - -

AJ 4 3 - 14 4 PO + 9 SO - -

FD 4 3 - 8 4 PO + 2SO + 3 HSO

- -

FF 4 3 - 14 4 PO + 5SO + 3 HSO

- -

CC / CD

AH 4 3 - 8 4 PO + 6 SO 6 2

FD 4 3 - 8 4 PO + 2SO + 3 HSO

6 2

C AE / AF

AG 4 5 - 16 4 PO + 6 SO - -

FC 4 5 - 16 4 PO + 2SO + 3 HSO

- -

D DA

AH 1 - 3 8 4 PO + 6 SO - -

FD 1 - 3 8 4 PO + 2SO + 3 HSO

- -

18. Station communicationThe IED supports a range of communication protocols

including IEC 61850, IEC 61850-9-2 LE, Modbus® andDNP3. Profibus DPV1 communication protocol is supportedwith using the protocol converter SPA-ZC 302. Operationalinformation and controls are available through theseprotocols. However, some communication functionality, forexample, horizontal communication between the IEDs, is onlyenabled by the IEC 61850 communication protocol.

The IEC 61850 communication implementation supportsmonitoring and control functions. Additionally, parametersettings, disturbance recordings and fault records can beaccessed using the IEC 61850 protocol. Disturbancerecordings are available to any Ethernet-based application inthe standard COMTRADE file format. The IED supportssimultaneous event reporting to five different clients on thestation bus. The IED can exchange signals with other IEDsusing the IEC 61860 protocol.

The IED can send binary and analog signals to other IEDs (socalled horizontal communication) using the IEC 61850-8-1

GOOSE (Generic Object Oriented Substation Event) profile.Binary GOOSE messaging can, for example, be employed forprotection and interlocking-based protection schemes. TheIED meets the GOOSE performance requirements for trippingapplications in distribution substations, as defined by the IEC61850 standard. The IED also supports the sending andreceiving of analog values using GOOSE messaging. AnalogGOOSE messaging enables easy transfer of analogmeasurement values over the station bus, thus facilitating forexample sharing of RTD input values, such as surroundingtemperature values, to other IED applications.

The IED also supports IEC 61850 process bus with sampledvalues of analog phase voltages. With this functionality thegalvanic interpanel wiring can be replaced with Ethernetcommunication. The measured values are transferred assampled values using IEC 61850-9-2 LE protocol. Theintended application for sampled values shares the phasevoltages to other 615 series IEDs, having phase voltagebased functions and 9-2 support. 615 IEDs with process busbased applications use IEEE 1588 for high accuracy timesynchronization.


16 ABB

For redundant Ethernet communication, the IED offers eithertwo optical or two galvanic Ethernet network interfaces. Athird port with galvanic Ethernet network interface is alsoavailable. The third Ethernet interface provides connectivityfor any other Ethernet device to an IEC 61850 station businside a switchgear bay, for example connection of a RemoteI/O. The high accuracy time synchronization method IEEE1588 support is included in all variants that have a redundantEthernet communication module.

Ethernet network redundancy can be achieved using the high-availability seamless redundancy (HSR) protocol or theparallel redundancy protocol (PRP) or a with self-healing ringusing RSTP in managed switches. Ethernet redundancy canbe applied to Ethernet-based IEC 61850, Modbus and DNP3protocols.

The IEC 61850 standard specifies network redundancy whichimproves the system availability for the substation

communication. The network redundancy is based on twocomplementary protocols defined in the IEC 62439-3standard: PRP and HSR protocols. Both the protocols areable to overcome a failure of a link or switch with a zeroswitch-over time. In both the protocols, each network nodehas two identical Ethernet ports dedicated for one networkconnection. The protocols rely on the duplication of alltransmitted information and provide a zero switch-over time ifthe links or switches fail, thus fulfilling all the stringent real-time requirements of substation automation.

In PRP, each network node is attached to two independentnetworks operated in parallel. The networks are completelyseparated to ensure failure independence and can havedifferent topologies. The networks operate in parallel, thusproviding zero-time recovery and continuous checking ofredundancy to avoid failures.

Ethernet switchIEC 61850 PRPEthernet switch

REF615 REF620 RET620 REM620 REF615

SCADACOM600

GUID-334D26B1-C3BD-47B6-BD9D-2301190A5E9D V1 EN

Figure 8. Parallel redundancy protocol (PRP) solution

HSR applies the PRP principle of parallel operation to a singlering. For each message sent, the node sends two frames,one through each port. Both the frames circulate in oppositedirections over the ring. Every node forwards the frames itreceives from one port to another to reach the next node.When the originating sender node receives the frame it sent,

the sender node discards the frame to avoid loops. The HSRring with 615 series IEDs supports the connection of up tothirty IEDs. If more than 30 IEDs are to be connected, it isrecommended to split the network into several rings toguarantee the performance for real-time applications.


ABB 17

Ethernet switch

RedundancyBox

IEC 61850 HSR

RedundancyBox

RedundancyBox

REF615 REF620 RET620 REM620 REF615

SCADA Devices not supporting HSRCOM600

GUID-7996332D-7FC8-49F3-A4FE-FB4ABB730405 V1 EN

Figure 9. High availability seamless redundancy (HSR) solution

The choice between the HSR and PRP redundancy protocolsdepends on the required functionality, cost and complexity.

The self-healing Ethernet ring solution enables a cost-efficientcommunication ring controlled by a managed switch withstandard Rapid Spanning Tree Protocol (RSTP) support. Themanaged switch controls the consistency of the loop, routesthe data and corrects the data flow in case of a

communication switch-over. The IEDs in the ring topology actas unmanaged switches forwarding unrelated data traffic. TheEthernet ring solution supports the connection of up to thirty615 series IEDs. If more than 30 IEDs are to be connected, itis recommended to split the network into several rings. Theself-healing Ethernet ring solution avoids single point of failureconcerns and improves the reliability of the communication.


18 ABB

Managed Ethernet switchwith RSTP support

Managed Ethernet switchwith RSTP support

Client BClient A

Network ANetwork B

GUID-AB81C355-EF5D-4658-8AE0-01DC076E519C V4 EN

Figure 10. Self-healing Ethernet ring solution

All communication connectors, except for the front portconnector, are placed on integrated optional communicationmodules. The IED can be connected to Ethernet-basedcommunication systems via the RJ-45 connector (100Base-TX) or the fibre-optic LC connector (100Base-FX). Ifconnection to a serial bus is required, the 10-pin RS-485screw-terminal or the fibre-optic ST connector can be used.

Modbus implementation supports RTU, ASCII and TCPmodes. Besides standard Modbus functionality, the IEDsupports retrieval of time-stamped events, changing theactive setting group and uploading of the latest fault records.If a Modbus TCP connection is used, five clients can beconnected to the IED simultaneously. Further, Modbus serialand Modbus TCP can be used in parallel, and if required bothIEC 61850 and Modbus protocols can be run simultaneously.

The IEC 60870-5-103 implementation supports two parallelserial bus connections to two different masters. Besidesbasic standard functionality, the IED supports changing of theactive setting group and uploading of disturbance recordingsin IEC 60870-5-103 format. Further, IEC 60870-5-103 canbe used at the same time with the IEC 61850 protocol.

DNP3 supports both serial and TCP modes for connection upto five masters. Changing of the active setting and readingfault records are supported. DNP serial and DNP TCP can be

used in parallel. If required, both IEC 61850 and DNPprotocols can be run simultaneously.

615 series supports Profibus DPV1 with support of SPA-ZC302 Profibus adapter. If Profibus is required the IED must beordered with Modbus serial options. Modbus implementationincludes SPA-protocol emulation functionality. Thisfunctionality enables connection to SPA-ZC 302.

When the IED uses the RS-485 bus for the serialcommunication, both two- and four wire connections aresupported. Termination and pull-up/down resistors can beconfigured with jumpers on the communication card soexternal resistors are not needed.

The IED supports the following time synchronization methodswith a time-stamping resolution of 1 ms.

Ethernet-based• SNTP (Simple Network Time Protocol)

With special time synchronization wiring• IRIG-B (Inter-Range Instrumentation Group - Time Code

Format B)


ABB 19

The IED supports the following high accuracy timesynchronization method with a time-stamping resolution of 4µs required especially in process bus applications.• PTP (IEEE 1588) v2 with Power Profile

The IEEE 1588 support is included in all variants having aredundant Ethernet communication module.

IEEE 1588 v2 features• Ordinary Clock with Best Master Clock algorithm• One-step Transparent Clock for Ethernet ring topology• 1588 v2 Power Profile• Receive (slave): 1-step/2-step• Transmit (master): 1-step• Layer 2 mapping• Peer to peer delay calculation• Multicast operation

Required accuracy of grandmaster clock is +/-1 µs. IED canwork as master clock per BMC algorithm if externalgrandmaster clock is not available for short term.

The IEEE 1588 support is included in all variants having aredundant Ethernet communication module.

In addition, the IED supports time synchronization via thefollowing serial communication protocols.• Modbus• DNP3• IEC 60870-5-103

Table 5. Supported station communication interfaces and protocols

Interfaces/Protocols Ethernet Serial

100BASE-TX RJ-45 100BASE-FX LC RS-232/RS-485 Fibre-optic ST

IEC 61850-8-1 - -

IEC 61850-9-2 LE - -

MODBUS RTU/ASCII - -

MODBUS TCP/IP - -

DNP3 (serial) - -

DNP3 TCP/IP - -

IEC 60870-5-103 - - = Supported


20 ABB

19. Technical data

Table 6. Dimensions

Description Value

Width frame 177 mm

case 164 mm

Height frame 177 mm (4U)

case 160 mm

Depth 201 mm (153 + 48 mm)

Weight complete IED 4.1 kg

plug-in unit only 2.1 kg

Table 7. Power supply

Description Type 1 Type 2

Nominal auxiliary voltage Un 100, 110, 120, 220, 240 V AC, 50 and 60 Hz 24, 30, 48, 60 V DC

48, 60, 110, 125, 220, 250 V DC

Maximum interruption time in the auxiliaryDC voltage without resetting the IED

50 ms at Un

Auxiliary voltage variation 38...110% of Un (38...264 V AC) 50...120% of Un (12...72 V DC)

80...120% of Un (38.4...300 V DC)

Start-up threshold 19.2 V DC (24 V DC * 80%)

Burden of auxiliary voltage supply underquiescent (Pq)/operating condition

DC < 12.0 W (nominal)/< 18.0 W (max)AC< 16.0 W (nominal)/< 21.0W (max)

DC < 12.0 W (nominal)/< 18.0 W (max)

Ripple in the DC auxiliary voltage Max 15% of the DC value (at frequency of 100 Hz)

Fuse type T4A/250 V

Table 8. Energizing inputs

Description Value

Rated frequency 50/60 Hz

Current inputs Rated current, In 0.2/1 A1) 1/5 A2)

Thermal withstand capability:

• Continuously 4 A 20 A

• For 1 s 100 A 500 A

Dynamic current withstand:

• Half-wave value 250 A 1250 A

Input impedance <100 mΩ <20 mΩ

Voltage inputs Rated voltage 60...210 V AC

Voltage withstand:

• Continuous 240 V AC

• For 10 s 360 V AC

Burden at rated voltage <0.05 VA

1) Ordering option for residual current input2) Residual current and/or phase current


ABB 21

Table 9. Binary inputs

Description Value

Operating range ±20% of the rated voltage

Rated voltage 24...250 V DC

Current drain 1.6...1.9 mA

Power consumption 31.0...570.0 mW

Threshold voltage 16...176 V DC

Reaction time <3 ms

Table 10. RTD/mA measurement (XRGGIO130)

Description Value

RTD inputs Supported RTD sensors 100 Ω platinum250 Ω platinum100 Ω nickel120 Ω nickel250 Ω nickel10 Ω copper

TCR 0.00385 (DIN 43760)TCR 0.00385TCR 0.00618 (DIN 43760)TCR 0.00618TCR 0.00618TCR 0.00427

Supported resistance range 0...2 kΩ

Maximum lead resistance (three-wire measurement) 25 Ω per lead

Isolation 2 kV (inputs to protective earth)

Response time <4 s

RTD/resistance sensing current Maximum 0.33 mA rms

Operation accuracy Resistance Temperature

± 2.0% or ±1 Ω ±1°C10 Ω copper: ±2°C

mA inputs Supported current range 0…20 mA

Current input impedance 44 Ω ± 0.1%

Operation accuracy ±0.5% or ±0.01 mA

Table 11. Signal output X100: SO1

Description Value

Rated voltage 250 V AC/DC

Continuous contact carry 5 A

Make and carry for 3.0 s 15 A


Breaking capacity when the control-circuit time constant L/R<40 ms 1 A/0.25 A/0.15 A

Minimum contact load 100 mA at 24 V AC/DC


22 ABB

Table 12. Signal outputs and IRF output

Description Value




Make and carry 0.5 s 15 A

Breaking capacity when the control-circuit time constant L/R<40 ms, at48/110/220 V DC

1 A/0.25 A/0.15 A


Table 13. Double-pole power output relays with TCS function

Description Value





Breaking capacity when the control-circuit time constant L/R<40 ms, at48/110/220 V DC (two contacts connected in series)

5 A/3 A/1 A


Trip-circuit supervision (TCS):

• Control voltage range 20...250 V AC/DC

• Current drain through the supervision circuit ~1.5 mA

• Minimum voltage over the TCS contact 20 V AC/DC (15...20 V)

Table 14. Single-pole power output relays

Description Value


Continuous contact carry 8A



Breaking capacity when the control-circuit time constant L/R<40 ms, at48/110/220 V DC

5 A/3 A/1 A



ABB 23

Table 15. High-speed output HSO with BIO0007

Description Value





Breaking capacity when the control-circuit time constant L/R <40 ms, at48/110/220 V DC

5 A/3 A/1 A

Start 1 ms

Reset 20 ms, resistive load

Table 16. Front port Ethernet interfaces

Ethernet interface Protocol Cable Data transfer rate

Front TCP/IP protocol Standard Ethernet CAT 5 cable with RJ-45 connector 10 MBits/s

Table 17. Station communication link, fibre-optic

Connector Fibre type1) Wave length Max. distance Permitted path attenuation2)

LC MM 62.5/125 or 50/125 μmglass fibre core

1300 nm 2 km <8 dB

ST MM 62.5/125 or 50/125 μmglass fibre core

820-900 nm 1 km <11 dB

1) (MM) multi-mode fibre, (SM) single-mode fibre2) Maximum allowed attenuation caused by connectors and cable together

Table 18. IRIG-B

Description Value

IRIG time code format B004, B0051)

Isolation 500V 1 min

Modulation Unmodulated

Logic level 5 V TTL

Current consumption <4 mA

Power consumption <20 mW

1) According to the 200-04 IRIG standard

Table 19. Lens sensor and optical fibre for arc protection

Description Value

Fibre-optic cable including lens 1.5 m, 3.0 m or 5.0 m

Normal service temperature range of the lens -40...+100°C

Maximum service temperature range of the lens, max 1 h +140°C

Minimum permissible bending radius of the connection fibre 100 mm


24 ABB

Table 20. Degree of protection of flush-mounted IED

Description Value

Front side IP 54

Rear side, connection terminals IP 20

Table 21. Environmental conditions

Description Value

Operating temperature range -25...+55ºC (continuous)

Short-time service temperature range -40...+85ºC (<16h)1)2)

Relative humidity <93%, non-condensing

Atmospheric pressure 86...106 kPa

Altitude Up to 2000 m

Transport and storage temperature range -40...+85ºC

1) Degradation in MTBF and HMI performance outside the temperature range of -25...+55 ºC2) For IEDs with an LC communication interface the maximum operating temperature is +70 ºC


ABB 25

Table 22. Electromagnetic compatibility tests

Description Type test value Reference

1 MHz/100 kHz burst disturbance test IEC 61000-4-18IEC 60255-22-1, class IIIIEEE C37.90.1-2002

• Common mode 2.5 kV

• Differential mode 2.5 kV

3 MHz, 10 MHz and 30 MHz burst disturbancetest

IEC 61000-4-18IEC 60255-22-1, class III

• Common mode 2.5 kV

Electrostatic discharge test IEC 61000-4-2IEC 60255-22-2IEEE C37.90.3-2001

• Contact discharge 8 kV

• Air discharge 15 kV

Radio frequency interference test

10 V (rms)f = 150 kHz...80 MHz

IEC 61000-4-6IEC 60255-22-6, class III

10 V/m (rms)f = 80...2700 MHz

IEC 61000-4-3IEC 60255-22-3, class III

10 V/mf = 900 MHz

ENV 50204IEC 60255-22-3, class III

20 V/m (rms)f = 80...1000 MHz

IEEE C37.90.2-2004

Fast transient disturbance test IEC 61000-4-4IEC 60255-22-4IEEE C37.90.1-2002

• All ports 4 kV

Surge immunity test IEC 61000-4-5IEC 60255-22-5

• Communication 1 kV, line-to-earth

• Other ports 4 kV, line-to-earth2 kV, line-to-line

Power frequency (50 Hz) magnetic fieldimmunity test

IEC 61000-4-8

• Continuous• 1...3 s

300 A/m1000 A/m

Pulse magnetic field immunity test 1000 A/m6.4/16 µs

IEC 61000-4-9

Damped oscillatory magnetic field immunity test IEC 61000-4-10

• 2 s 100 A/m

• 1 MHz 400 transients/s

Voltage dips and short interruptions 30%/10 ms60%/100 ms60%/1000 ms>95%/5000 ms

IEC 61000-4-11


26 ABB

Table 22. Electromagnetic compatibility tests, continued


Power frequency immunity test Binary inputs only IEC 61000-4-16IEC 60255-22-7, class A

• Common mode 300 V rms

• Differential mode 150 V rms

Conducted common mode disturbances 15 Hz...150 kHzTest level 3 (10/1/10 V rms)

IEC 61000-4-16

Emission tests EN 55011, class AIEC 60255-25

• Conducted

0.15...0.50 MHz <79 dB (µV) quasi peak<66 dB (µV) average

0.5...30 MHz <73 dB (µV) quasi peak<60 dB (µV) average

• Radiated

30...230 MHz <40 dB (µV/m) quasi peak, measured at 10 mdistance

230...1000 MHz <47 dB (µV/m) quasi peak, measured at 10 mdistance

Table 23. Insulation tests


Dielectric tests 2 kV, 50 Hz, 1 min500 V, 50 Hz, 1 min, communication

IEC 60255-5 andIEC 60255-27

Impulse voltage test 5 kV, 1.2/50 μs, 0.5 J1 kV, 1.2/50 μs, 0.5 J, communication

IEC 60255-5 andIEC 60255-27

Insulation resistance measurements >100 MΩ, 500 V DC IEC 60255-5 andIEC 60255-27

Protective bonding resistance <0.1 Ω, 4 A, 60 s IEC 60255-27

Table 24. Mechanical tests

Description Reference Requirement

Vibration tests (sinusoidal) IEC 60068-2-6 (test Fc)IEC 60255-21-1

Class 2

Shock and bump test IEC 60068-2-27 (test Ea shock)IEC 60068-2-29 (test Eb bump)IEC 60255-21-2

Class 2

Seismic test IEC 60255-21-3 Class 2


ABB 27

Table 25. Environmental tests


Dry heat test • 96 h at +55ºC• 16 h at +85ºC1)

IEC 60068-2-2

Dry cold test • 96 h at -25ºC• 16 h at -40ºC

IEC 60068-2-1

Damp heat test • 6 cycles (12 h + 12 h) at +25°C…+55°C,humidity >93%

IEC 60068-2-30

Change of temperature test • 5 cycles (3 h + 3 h)at -25°C...+55°C

IEC60068-2-14

Storage test • 96 h at -40ºC• 96 h at +85ºC

IEC 60068-2-1IEC 60068-2-2

1) For IEDs with an LC communication interface the maximum operating temperature is +70oC

Table 26. Product safety

Description Reference

LV directive 2006/95/EC

Standard EN 60255-27 (2005)EN 60255-1 (2009)

Table 27. EMC compliance

Description Reference

EMC directive 2004/108/EC

Standard EN 50263 (2000)EN 60255-26 (2007)

Table 28. RoHS compliance

Description

Complies with RoHS directive 2002/95/EC


28 ABB

Protection functions

Table 29. Three-phase non-directional overcurrent protection (PHxPTOC)

Characteristic Value

Operation accuracy Depending on the frequency of the measured current: fn ±2 Hz

PHLPTOC ±1.5% of the set value or ±0.002 × In

PHHPTOC1)

andPHIPTOC

±1.5% of set value or ±0.002 × In(at currents in the range of 0.1…10 × In)±5.0% of the set value(at currents in the range of 10…40 × In)

Start time 2)3) Minimum Typical Maximum

PHIPTOC:IFault = 2 × set Start valueIFault = 10 × set Start value

16 ms 11 ms

19 ms 12 ms

23 ms 14 ms

PHHPTOC1) and PHLPTOC:IFault = 2 x set Start value

23 ms

26 ms

29 ms

Reset time Typically 40 ms

Reset ratio Typically 0.96

Retardation time <30 ms

Operate time accuracy in definite time mode ±1.0% of the set value or ±20 ms

Operate time accuracy in inverse time mode ±5.0% of the theoretical value or ±20 ms 4)

±5.0% of the theoretical value or ±40 ms 4)5)

Suppression of harmonics RMS: No suppressionDFT: -50 dB at f = n × fn, where n = 2, 3, 4, 5,…Peak-to-Peak: No suppressionP-to-P+backup: No suppression

1) Not included in REM6152) Set Operate delay time = 0,02 s, Operate curve type = IEC definite time, Measurement mode = default (depends on stage), current before fault = 0.0 × In, fn = 50 Hz, fault current in one

phase with nominal frequency injected from random phase angle, results based on statistical distribution of 1000 measurements3) Includes the delay of the signal output contact4) Includes the delay of the heavy-duty output contact5) Valid for FPHLPTOC


ABB 29

Table 30. Three-phase non-directional overcurrent protection (PHxPTOC) main settings

Parameter Function Value (Range) Step

Start Value PHLPTOC 0.05...5.00 × In 0.01

PHHPTOC1) 0.10...40.00 × In 0.01

PHIPTOC 1.00...40.00 × In 0.01

Time multiplier PHLPTOC 0.05...15.00 0.01

PHHPTOC1) 0.05...15.00 0.01

Operate delay time PHLPTOC 40...200000 ms 10

PHHPTOC1) 40...200000 ms 10

PHIPTOC 20...200000 ms 10

Operating curve type2) PHLPTOC Definite or inverse timeCurve type: 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 17, 18, 19

PHHPTOC1) Definite or inverse timeCurve type: 1, 3, 5, 9, 10, 12, 15, 17

PHIPTOC Definite time

1) Not included in REM6152) For further reference, see Operation characteristics table

Table 31. Non-directional earth-fault protection (EFxPTOC)



EFLPTOC ±1.5% of the set value or ±0.002 × In

EFHPTOCandEFIPTOC1)

±1.5% of set value or ±0.002 × In(at currents in the range of 0.1…10 × In)±5.0% of the set value(at currents in the range of 10…40 × In)


EFIPTOC1):IFault = 2 × set Start valueIFault = 10 × set Start value

16 ms11 ms

19 ms12 ms

23 ms14 ms

EFHPTOC and EFLPTOC:IFault = 2 × set Start value

23 ms

26 ms

29 ms






Suppression of harmonics RMS: No suppressionDFT: -50 dB at f = n × fn, where n = 2, 3, 4, 5,…Peak-to-Peak: No suppression

1) Not included in REM6152) Measurement mode = default (depends on stage), current before fault = 0.0 × In, fn = 50 Hz, earth-fault current with nominal frequency injected from random phase angle, results based

on statistical distribution of 1000 measurements3) Includes the delay of the signal output contact4) Maximum Start value = 2.5 × In, Start value multiples in range of 1.5...20


30 ABB

Table 32. Non-directional earth-fault protection (EFxPTOC) main settings


Start value EFLPTOC 0.010...5.000 × In 0.005

EFHPTOC 0.10...40.00 × In 0.01

EFIPTOC 1) 1.00...40.00 × In 0.01

Time multiplier EFLPTOC 0.05...15.00 0.01

EFHPTOC 0.05...15.00 0.01

Operate delay time EFLPTOC 40...200000 ms 10

EFHPTOC 40...200000 ms 10

EFIPTOC1) 20...200000 ms 10

Operating curve type2) EFLPTOC Definite or inverse timeCurve type: 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 17, 18, 19

EFHPTOC Definite or inverse timeCurve type: 1, 3, 5, 9, 10, 12, 15, 17

EFIPTOC1) Definite time

1) Not included in REM6152) For further reference, see Operation characteristics table


ABB 31

Table 33. Directional earth-fault protection (DEFxPDEF)



DEFLPDEF Current:±1.5% of the set value or ±0.002 × InVoltage±1.5% of the set value or ±0.002 × Un

Phase angle:±2°

DEFHPDEF1) Current:±1.5% of the set value or ±0.002 × In(at currents in the range of 0.1…10 × In)±5.0% of the set value(at currents in the range of 10…40 × In)Voltage:±1.5% of the set value or ±0.002 × Un

Phase angle:±2°


DEFHPDEF1)

IFault = 2 × set Start value 42 ms

46 ms

49 ms

DEFLPDEFIFault = 2 × set Start value

58 ms 62 ms 66 ms






Suppression of harmonics RMS: No suppressionDFT: -50 dB at f = n × fn, where n = 2, 3, 4, 5,…Peak-to-Peak: No suppression

1) Not included in REM6152) Set Operate delay time = 0.06 s,Operate curve type = IEC definite time, Measurement mode = default (depends on stage), current before fault = 0.0 × In, fn = 50 Hz, earth-fault current

with nominal frequency injected from random phase angle, results based on statistical distribution of 1000 measurements3) Includes the delay of the signal output contact4) Maximum Start value = 2.5 × In, Start value multiples in range of 1.5...20


32 ABB

Table 34. Directional earth-fault protection (DEFxPDEF) main settings


Start Value DEFLPDEF 0.010...5.000 × In 0.005

DEFHPDEF1) 0.10...40.00 × In 0.01

Directional mode DEFLPDEF and DEFHPDEF 1 = Non-directional2 = Forward3 = Reverse

Time multiplier DEFLPDEF 0.05...15.00 0.01

DEFHPDEF1) 0.05...15.00 0.01

Operate delay time DEFLPDEF 60...200000 ms 10

DEFHPDEF1) 40...200000 ms 10

Operating curve type2) DEFLPDEF Definite or inverse timeCurve type: 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 17, 18, 19

DEFHPDEF1) Definite or inverse timeCurve type: 1, 3, 5, 15, 17

Operation mode DEFLPDEF and DEFHPDEF1) 1 = Phase angle2 = IoSin3 = IoCos4 = Phase angle 805 = Phase angle 88

1) Not included in REM6152) For further reference, refer to the Operating characteristics table

Table 35. Three phase undervoltage protection (PHPTUV)


Operation accuracy Depending on the frequency of the voltage measured: fn ±2 Hz

±1.5% of the set value or ±0.002 × Un

Start time1)2) Minimum Typical Maximum

UFault = 0.9 × set Start value 62 ms 66 ms 70 ms


Reset ratio Depends on the set Relative hysteresis



Operate time accuracy in inverse time mode ±5.0% of the theoretical value or ±20 ms3)

Suppression of harmonics DFT: -50 dB at f = n × fn, where n = 2, 3, 4, 5,…

1) Start value = 1.0 × Un, Voltage before fault = 1.1 × Un, fn = 50 Hz, undervoltage in one phase-to-phase with nominal frequency injected from random phase angle, results based on

statistical distribution of 1000 measurements2) Includes the delay of the signal output contact3) Minimum Start value = 0.50, Start value multiples in range of 0.90...0.20


ABB 33

Table 36. Three-phase undervoltage protection (PHPTUV) main settings


Start value PHPTUV 0.05...1.20 × Un 0.01

Time multiplier PHPTUV 0.05...15.00 0.01

Operate delay time PHPTUV 60...300000 ms 10

Operating curve type1) PHPTUV Definite or inverse timeCurve type: 5, 15, 21, 22, 23

1) For further reference, see Operation characteristics table

Table 37. Positive-sequence undervoltage protection (PSPTUV)





UFault = 0.99 × set Start valueUFault = 0.9 × set Start value

52 ms44 ms

55 ms47 ms

58 ms50 ms


Reset ratio Depends of the set Relative hysteresis




1) Start value = 1.0 × Un, Positive sequence voltage before fault = 1.1 × Un, fn = 50 Hz, positive sequence undervoltage with nominal frequency injected from random phase angle, results

based on statistical distribution of 1000 measurements2) Includes the delay of the signal output contact

Table 38. Positive-sequence undervoltage protection (PSPTUV) main settings


Start value PSPTUV 0.010...1.200 × Un 0.001

Operate delay time PSPTUV 40...120000 ms 10

Voltage block value PSPTUV 0.01...1.0 × Un 0.01


34 ABB

Table 39. Negative-sequence overvoltage protection (NSPTOV)





UFault = 1.1 × set Start valueUFault = 2.0 × set Start value

33 ms24 ms

35 ms26 ms

37 ms28 ms






1) Negative-sequence voltage before fault = 0.0 × Un, fn = 50 Hz, negative-sequence overvoltage with nominal frequency injected from random phase angle, results based on statistical

distribution of 1000 measurements2) Includes the delay of the signal output contact

Table 40. Negative-sequence overvoltage protection (NSPTOV) main settings


Start value NSPTOV 0.010...1.000 × Un 0.001

Operate delay time NSPTOV 40...120000 ms 1

Table 41. Frequency protection (FRPFRQ)


Operation accuracy f>/f< ±10 mHz

df/dt ±100 mHz/s (in range |df/dt| < 5 Hz/s)± 2.0% of the set value (in range 5 Hz/s < |df/dt| < 15 Hz/s)

Start time f>/f< <80 ms

df/dt <120 ms

Reset time <150 ms

Operate time accuracy ±1.0% of the set value or ±30 ms


ABB 35

Table 42. Frequency protection (FRPFRQ) main settings


Operation mode FRPFRQ 1 = Freq<2 = Freq>3 = df/dt4 = Freq< + df/dt5 = Freq> + df/dt6 = Freq< OR df/dt7 = Freq> OR df/dt

Start value Freq> FRPFRQ 0.9000...1.2000 × fn 0.0001

Start value Freq< FRPFRQ 0.8000...1.1000 × fn 0.0001

Start value df/dt FRPFRQ -0.200...0.200 × fn/s 0.005

Operate Tm Freq FRPFRQ 80...200000 ms 10

Operate Tm df/dt FRPFRQ 120...200000 ms 10

Table 43. Negative phase-sequence overcurrent protection for motors (MNSPTOC)



±1.5% of the set value or ±0.002 x In


IFault = 2.0 × set Start value 23 ms 25 ms 28 ms





Operate time accuracy in inverse time mode ±5.0% of the theoretical value or ±20 ms3)


1) Negative-sequence current before = 0.0, fn = 50 Hz, results based on statistical distribution of 1000 measurements

2) Includes the delay of the signal output contact3) Start value multiples in range of 1.10...5.00

Table 44. Negative phase-sequence overcurrent protection for motors (MNSPTOC) main settings


Start value MNSPTOC 0.01...0.50 x In 0.01

Operating curve type MNSPTOC ANSI Def. TimeIEC Def. TimeInv. Curve AInv. Curve B

-

Operate delay time MNSPTOC 100...120000 ms 10

Cooling time MNSPTOC 5...7200 s 1

Operation MNSPTOC OffOn

-


36 ABB

Table 45. Loss of load supervision (LOFLPTUC)



±1.5% of the set value or ±0.002 × In

Start time Typically 300 ms





Table 46. Loss of load supervision (LOFLPTUC) main settings


Start value high LOFLPTUC 0.01...1.00 x In 0.01

Start value low LOFLPTUC 0.01...0.50 x In 0.01

Operate delay time LOFLPTUC 400...600000 ms 10

Operation LOFLPTUC OffOn

-

Table 47. Motor load jam protection (JAMPTOC)








Table 48. Motor load jam protection (JAMPTOC) main settings


Operation JAMPTOC OffOn

-

Start value JAMPTOC 0.10...10.00 x In 0.01

Operate delay time JAMPTOC 100...120000 ms 10


ABB 37

Table 49. Motor startup supervision (STTPMSU)





IFault = 1.1 × set Start detection A 27 ms 30 ms 34 ms


Reset ratio Typical 0.90

1) Current before = 0.0 × In, fn = 50 Hz, overcurrent in one phase, results based on statistical distribution of 1000 measurements

2) Includes the delay of the signal output contact

Table 50. Motor start-up supervision (STTPMSU) main settings


Motor start-up A STTPMSU 1.0...10.0 x In 0.1

Motor start-up time STTPMSU 1...80.0 s 1

Lock rotor time STTPMSU 2...120 s 1

Operation STTPMSU OffOn

-

Operation mode STTPMSU IItIIt, CBIIt & stallIIt & stall, CB

-

Restart inhibit time STTPMSU 0...250 min 1

Table 51. Phase reversal protection (PREVPTOC)





IFault = 2.0 × set Start value 23 ms 25 ms 28 ms






1) Negative-sequence current before = 0.0, fn = 50 Hz, results based on statistical distribution of 1000 measurements

2) Includes the delay of the signal output contact


38 ABB

Table 52. Phase reversal protection (PREVPTOC) main settings


Start value PREVPTOC 0.05...1.00 x In 0.01

Operate delay time PREVPTOC 100...60000 ms 10

Operation PREVPTOC OffOn

-

Table 53. Three-phase thermal overload protection for motors (MPTTR)



Current measurement: ±1.5% of the set value or ±0.002 x In (atcurrents in the range of 0.01...4.00 x In)

Operate time accuracy1) ±2.0% of the theoretical value or ±0.50 s

1) Overload current > 1.2 x Operate level temperature

Table 54. Thermal overload protection for motors (MPTTR) main settings


Env temperature mode MPTTR FLC OnlyUse RTDSet Amb Temp

-

Env temperature set MPTTR -20.0...70.0 °C 0.1

Alarm thermal value MPTTR 50.0...100.0 % 0.1

Restart thermal value MPTTR 20.0...80.0 % 0.1

Overload factor MPTTR 1.00...1.20 0.01

Weighting factor p MPTTR 20.0...100.0 0.1

Time constant normal MPTTR 80...4000 s 1

Time constant start MPTTR 80...4000 s 1

Operation MPTTR OffOn

-

Table 55. Circuit breaker failure protection (CCBRBRF)







ABB 39

Table 56. Circuit breaker failure protection (CCBRBRF) main settings


Current value (Operating phasecurrent)

CCBRBRF 0.05...1.00 × In 0.05

Current value Res (Operatingresidual current)

CCBRBRF 0.05...1.00 × In 0.05

CB failure mode (Operating modeof function)

CCBRBRF 1 = Current2 = Breaker status3 = Both

-

CB fail trip mode CCBRBRF 1 = Off2 = Without check3 = Current check

-

Retrip time CCBRBRF 0...60000 ms 10

CB failure delay CCBRBRF 0...60000 ms 10

CB fault delay CCBRBRF 0...60000 ms 10

Table 57. Arc protection (ARCSARC)


Operation accuracy ±3% of the set value or ±0.01 × In

Operate time Minimum Typical Maximum

Operation mode = "Light+current"1)2)

9 ms 12 ms 15 ms

Operation mode = "Light only"2) 9 ms 10 ms 12 ms



1) Phase start value = 1.0 × In, current before fault = 2.0 × set Phase start value, fn = 50 Hz, fault with nominal frequency, results based on statistical distribution of 200 measurements

2) Includes the delay of the heavy-duty output contact

Table 58. Arc protection (ARCSARC) main settings


Phase start value (Operatingphase current)

ARCSARC 0.50...40.00 x In 0.01

Ground start value (Operatingresidual current)

ARCSARC 0.05...8.00 x In 0.01

Operation mode ARCSARC 1=Light+current2=Light only3=BI controlled

Table 59. Multipurpose protection (MAPGAPC)


Operation accuracy ±1.0% of the set value or ±20 ms


40 ABB

Table 60. Multipurpose analog protection (MAPGAPC) main settings


Start value MAPGAPC -10000.0...10000.0 0.1

Operate delay time MAPGAPC 0...200000 ms 100

Operation mode MAPGAPC OverUnder

-


ABB 41

Control functions

Table 61. Emergency start function (ESMGAPC) main settings


Operation ESMGAPC OffOn

-

Motor stand still A ESMGAPC 0.05...0.20 x In 0.01


42 ABB

Supervision functions

Table 62. Current circuit supervision (CCRDIF)


Operate time1) <30 ms

1) Including the delay of the output contact

Table 63. Current circuit supervision (CCRDIF) main settings


Start value CCRDIF 0.05...0.20 x In 0.01

Maximum operate current CCRDIF 1.00...5.00 x In 0.01

Table 64. Fuse failure supervision (SEQRFUF)


Operate time1) NPS function UFault = 1.1 × set Neg Seq voltageLev

<33 ms

UFault = 5.0 × set Neg Seq voltageLev

<18 ms

Delta function ΔU = 1.1 × set Voltage change rate <30 ms

ΔU = 2.0 × set Voltage change rate <24 ms

1) Includes the delay of the signal output contact, fn = 50 Hz, fault voltage with nominal frequency injected from random phase angle, results based on statistical distribution of 1000

measurements

Table 65. Motor run time counter (MDSOPT)

Description Value

Motor run-time measurement accuracy1) ±0.5%

1) Of the reading, for a stand-alone IED, without time synchronization.


ABB 43

Measurement functions

Table 66. Three-phase current measurement (CMMXU)



±0.5% or ±0.002 × In(at currents in the range of 0.01...4.00 × In)

Suppression of harmonics DFT: -50 dB at f = n × fn, where n = 2, 3, 4, 5,…RMS: No suppression

Table 67. Current sequence components (CSMSQI)


Operation accuracy Depending on the frequency of the measured current: f/fn = ±2 Hz

±1.0% or ±0.002 × Inat currents in the range of 0.01...4.00 × In


Table 68. Residual current measurement (RESCMMXU)


Operation accuracy Depending on the frequency of the current measured: f/fn = ±2 Hz

±0.5% or ±0.002 × Inat currents in the range of 0.01...4.00 × In


Table 69. Three-phase voltage measurement (VMMXU)


Operation accuracy Depending on the frequency of the voltage measured: fn ±2 HzAt voltages in range 0.01…1.15 × Un

±0.5% or ±0.002 × Un


Table 70. Residual voltage measurement (RESVMMXU)


Operation accuracy Depending on the frequency of the measured current: f/fn = ±2 Hz

±0.5% or ±0.002 × Un



44 ABB

Table 71. Voltage sequence components (VSMSQI)


Operation accuracy Depending on the frequency of the voltage measured: fn ±2 HzAt voltages in range 0.01…1.15 × Un

±1.0% or ±0.002 × Un


Table 72. Three-phase power and energy (PEMMXU)


Operation accuracy At all three currents in range 0.10…1.20 × InAt all three voltages in range 0.50…1.15 × Un

At the frequency fn ±1 HzActive power and energy in range |PF| > 0.71Reactive power and energy in range |PF| < 0.71

±1.5% for power (S, P and Q)±0.015 for power factor±1.5% for energy


Table 73. RTD/mA measurement (XRGGIO130)

Description Value

RTD inputs Supported RTD sensors 100 Ω platinum250 Ω platinum100 Ω nickel120 Ω nickel250 Ω nickel10 Ω copper

TCR 0.00385 (DIN 43760)TCR 0.00385TCR 0.00618 (DIN 43760)TCR 0.00618TCR 0.00618TCR 0.00427

Supported resistance range 0...2 kΩ

Maximum lead resistance (three-wire measurement) 25 Ω per lead

Isolation 2 kV (inputs to protective earth)

Response time <4 s

RTD/resistance sensing current Maximum 0.33 mA rms

Operation accuracy Resistance Temperature

± 2.0% or ±1 Ω ±1°C10 Ω copper: ±2°C

mA inputs Supported current range 0…20 mA

Current input impedance 44 Ω ± 0.1%

Operation accuracy ±0.5% or ±0.01 mA

Table 74. Frequency measurement (FMMXU)


Operation accuracy ±10 mHz(in measurement range 35...75 Hz)


ABB 45

20. Local HMIThe IED is available with two optional displays, a large oneand a small one. The large display is suited for IEDinstallations where the front panel user interface is frequentlyused and a single line diagram is required. The small displayis suited for remotely controlled substations where the IED isonly occasionally accessed locally via the front panel userinterface.

Both LCD displays offer front-panel user interfacefunctionality with menu navigation and menu views. However,the large display offers increased front-panel usability withless menu scrolling and improved information overview. Inaddition, the large display includes a user-configurable singleline diagram (SLD) with position indication for the associatedprimary equipment. Depending on the chosen standardconfiguration, the IED displays the related measuring values,

apart from the default single line diagram. The SLD view canalso be accessed using the Web browser-based userinterface. The default SLD can be modified according to userrequirements by using the Graphical Display Editor inPCM600. The user can create up to 10 SLD pages.

The local HMI includes a push button (L/R) for local/remoteoperation of the IED. When the IED is in the local mode, theIED can be operated only by using the local front panel userinterface. When the IED is in the remote mode, the IED canexecute commands sent from a remote location. The IEDsupports the remote selection of local/remote mode via abinary input. This feature facilitates, for example, the use ofan external switch at the substation to ensure that all IEDs arein the local mode during maintenance work and that thecircuit breakers cannot be operated remotely from thenetwork control center.

IECA070904 V3 EN

Figure 11. Small display

IECA070901 V3 EN

Figure 12. Large display

Table 75. Small display

Character size1) Rows in the view Characters per row

Small, mono-spaced (6x12 pixels) 5 20

Large, variable width (13x14 pixels) 4 8 or more

1) Depending on the selected language

Table 76. Large display

Character size1) Rows in the view Characters per row

Small, mono-spaced (6x12 pixels) 10 20

Large, variable width (13x14 pixels) 8 8 or more

1) Depending on the selected language


46 ABB

21. Mounting methodsBy means of appropriate mounting accessories the standardIED case for the 615 series IED can be flush mounted, semi-flush mounted or wall mounted. The flush mounted and wallmounted IED cases can also be mounted in a tilted position(25°) using special accessories.

Further, the IEDs can be mounted in any standard 19”instrument cabinet by means of 19” mounting panels availablewith cut-outs for one or two IEDs.Alternatively, the IED can bemounted in 19” instrument cabinets by means of 4UCombiflex equipment frames.

For the routine testing purposes, the IED cases can beequipped with test switches, type RTXP 18, which can bemounted side by side with the IED cases.

Mounting methods:

• Flush mounting• Semi-flush mounting• Semi-flush mounting in a 25° tilt• Rack mounting• Wall mounting• Mounting to a 19" equipment frame• Mounting with a RTXP 18 test switch to a 19" rack

Panel cut-out for flush mounting:• Height: 161.5 ±1 mm• Width: 165.5 ±1 mm

48

177

160

177

153

164

IECA070900 V4 EN

Figure 13. Flush mounting

98

177

160

186

103

IECA070903 V4 EN

Figure 14. Semi-flush mounting

230

107

25°

133

190

IECA070902 V4 EN

Figure 15. Semi-flush with a 25º tilt

22. IED case and IED plug-in unitFor safety reasons, the IED cases for current measuring IEDsare provided with automatically operating contacts for short-circuiting the CT secondary circuits when a IED unit iswithdrawn from its case. The IED case is further provided witha mechanical coding system preventing current measuringIED units from being inserted into a IED case for a voltage

measuring IED unit and vice versa, i.e. the IED cases areassigned to a certain type of IED plug-in unit.

23. Selection and ordering dataUse the ABB Library to access the selection and orderinginformation and to generate the order number.


ABB 47

http://search.abb.com/library/Download.aspx?DocumentID=1MRS758059&LanguageCode=en&Action=Launch

24. Accessories and ordering data

Table 77. Cables

Item Order number

Cable for optical sensors for arc protection 1.5 m 1MRS120534-1.5



Table 78. Mounting accessories

Item Order number

Semi-flush mounting kit 1MRS050696

Wall mounting kit 1MRS050697

Inclined semi-flush mounting kit 1MRS050831

19” rack mounting kit with cut-out for one IED 1MRS050694

19” rack mounting kit with cut-out for two IEDs 1MRS050695

Mounting bracket for one IED with test switch RTXP in 4U Combiflex (RHGT 19” variant C) 2RCA022642P0001

Mounting bracket for one IED in 4U Combiflex (RHGT 19” variant C) 2RCA022643P0001

19” rack mounting kit for one IED and one RTXP18 test switch (the test switch is not included in the delivery) 2RCA021952A0003

19” rack mounting kit for one IED and one RTXP24 test switch (the test switch is not included in the delivery) 2RCA022561A0003

Replacement kit for a Strömberg SP_J40 series relay (cut-out in the center of the installation plate) 2RCA027871A0001

Replacement kit for a Strömberg SP_J40 series relay (cut-out on the left or the right of the installation plate) 2RCA027874A0001

Replacement kit for two Strömberg SP_J3 series relays 2RCA027880A0001

19” rack replacement kit for Strömberg SP_J3/J6 series relays (one cut-out) 2RCA027894A0001

19” rack replacement kit for Strömberg SP_J3/J6 series relays (two cut-outs) 2RCA027897A0001

Replacement kit for a Strömberg SP_J6 series relay 2RCA027881A0001

Replacement kit for three BBC S_ series relays 2RCA027882A0001

Replacement kit for a SPA 300 series relay 2RCA027885A0001


48 ABB

25. ToolsThe IED is delivered as a pre-configured unit. The defaultparameter setting values can be changed from the front-paneluser interface, the Web browser-based user interface (WebHMI) or the PCM600 tool in combination with the IED-specificconnectivity package.

The Protection and Control IED Manager PCM600 offersextensive IED configuration functions such as IED signalconfiguration, application configuration, graphical displayconfiguration including single line diagram configuration, andIEC 61850 communication configuration including horizontalGOOSE communication.

When the Web browser-based user interface is used, the IEDcan be accessed either locally or remotely, using a Webbrowser (Internet Explorer). For security reasons, the Web

browser-based user interface is disabled by default. Theinterface can be enabled with PCM600 or via the front paneluser interface. The functionality of the interface can be limitedto read-only access through PCM600.

The IED connectivity package is a collection of software andspecific IED information, which enable system products andtools to connect and interact with the IED. The connectivitypackages reduce the risk of errors in system integration,minimizing device configuration and set-up times. Further, theconnectivity packages for this product series IEDs include aflexible update tool for adding one additional local HMIlanguage to the IED. The update tool is activated usingPCM600, and it enables multiple updates of the additionalHMI language, thus offering flexible means for possible futurelanguage updates.

Table 79. Tools

Configuration and setting tools Version

PCM600 2.6 or later

Web-browser based user interface IE 8.0, IE 9.0 or IE 10.0

RE_615 Connectivity Package 5.0


ABB 49

Table 80. Supported functions

Function Web HMI PCM600

IED parameter setting

Saving of IED parameter settings in the IED

Signal monitoring

Disturbance recorder handling

Alarm LED viewing

Access control management

IED signal configuration (signal matrix) -

Modbus® communication configuration (communicationmanagement) -

DNP3 communication configuration (communicationmanagement) -

IEC 60870-5-103 communication configuration(communication management) -

Saving of IED parameter settings in the tool -

Disturbance record analysis -

XRIO parameter export/import -

Graphical display configuration -

Application configuration -

IEC 61850 communication configuration, GOOSE(communication configuration) -

Phasor diagram viewing -

Event viewing

Saving of event data on the user's PC -

Online monitoring - = Supported

26. Cyber securityIED supports role based user authentication andauthorization. It can store 2048 audit trail events to non-volatile memory. FTP used for, for example, configuration

download and Web HMI uses TLS encryption with 128 bitkey length protecting data in transit according FTPS andHTTPS standards.


50 ABB

27. Terminal diagrams

GUID-B2057B3C-DDFD-4A85-98AF-9E14D947439D V1 EN

Figure 16. Terminal diagram of standard configuration A


ABB 51

GUID-FB8CC4CD-F5ED-4FE5-837D-B39CB06ED67C V1 EN

Figure 17. Terminal diagram of standard configuration B


52 ABB

GUID-1589F909-AB4D-44A7-9445-057B7385AFD7 V2 EN

Figure 18. Terminal diagram of standard configuration C


ABB 53

REM615

X13Light sensor input 1 1)



16

17

1918

X100

67

89

10

111213

15

14

2

1

3

45

22

212324

SO2

TCS2

PO4

SO1

TCS1

PO3

PO2

PO1

IRF

+

-Uaux

20

X110

34

56

7

89

10BI 6

BI 5

BI 4

BI 3

BI 2

BI 8

BI 712

13

11

BI 112

X110

16

14

15

19

17

18

22

20

21

SO3

SO2

SO1

23SO4

24

1) Optional2) The IED features an automatic short-circuit mechanism in the CT connector when plug-in unit is detached

X130

12

X131

45

IL1

78

U1

X132

45

IL2

78

U2

X133

45

IL3

78

U3

Io0,2/1A

N

GUID-6C78FB07-4F88-4810-B265-F78B98C9F584 V1 EN

Figure 19. Terminal diagram of standard configuration D

28. CertificatesKEMA has issued an IEC 61850 Certificate Level A1 for

Relion® 615 series. Certificate number: 74102147-MOC/INC13-4263.

Det Norske Veritas (DNV) has issued a Type ApprovalCertificate for REM615. Certificate number: E-11189.

29. ReferencesThe www.abb.com/substationautomation portal providesinformation on the entire range of distribution automationproducts and services.

You will find the latest relevant information on the REM615protection IED on the product page.

The download area to the right contains the latest productdocumentation, such as the technical manual, installationmanual and operation manual.

The Features and Application tabs contain product-relatedinformation in a compact format.


54 ABB

HTTP://WWW.ABB.COM/SUBSTATIONAUTOMATION

HTTP://WWW.ABB.COM/PRODUCT/DB0003DB004281/349227215B8B8FF9C12575DF0028D8EC.ASPX

30. Functions, codes and symbols

Table 81. Functions included in the IED

Function IEC 61850 IEC 60617 IEC-ANSI

Protection

Three-phase non-directional overcurrent protection, low stage PHLPTOC1 3I> (1) 51P-1 (1)

Three-phase non-directional overcurrent protection, instantaneousstage PHIPTOC1 3I>>> (1) 50P/51P (1)

Non-directional earth-fault protection, low stage EFLPTOC1 Io> (1) 51N-1 (1)

Non-directional earth-fault protection, high stage EFHPTOC1 Io>> (1) 51N-2 (1)

Directional earth-fault protection, low stage DEFLPDEF1 Io> -> (1) 67N-1 (1)

Three-phase undervoltage protection PHPTUV1 3U< (1) 27 (1)

Positive-sequence undervoltage protection PSPTUV1 U1< (1) 47U+ (1)

Negative-sequence overvoltage protection NSPTOV1 U2> (1) 47O- (1)

Frequency protection FRPFRQ1 f>/f<,df/dt (1) 81 (1)

FRPFRQ2 f>/f<,df/dt (2) 81 (2)

Negative-sequence overcurrent protection for motors MNSPTOC1 I2>M (1) 46M (1)

MNSPTOC2 I2>M (2) 46M (2)

Loss of load supervision LOFLPTUC1 3I< (1) 37 (1)

Motor load jam protection JAMPTOC1 Ist> (1) 51LR (1)

Motor start-up supervision STTPMSU1 Is2t n< (1) 49,66,48,51LR (1)

Phase reversal protection PREVPTOC1 I2>> (1) 46R (1)

Thermal overload protection for motors MPTTR1 3Ith>M (1) 49M (1)

Circuit breaker failure protection CCBRBRF1 3I>/Io>BF (1) 51BF/51NBF (1)

Master trip TRPPTRC1 Master Trip (1) 94/86 (1)

TRPPTRC2 Master Trip (2) 94/86 (2)




Arc protection ARCSARC1 ARC (1) 50L/50NL (1)

ARCSARC2 ARC (2) 50L/50NL (2)

ARCSARC3 ARC (3) 50L/50NL (3)


ABB 55

Table 81. Functions included in the IED, continued


Multi-purpose protection1) MAPGAPC1 MAP (1) MAP (1)

MAPGAPC2 MAP (2) MAP (2)

















Control

Circuit-breaker control CBXCBR1 I <-> O CB (1) I <-> O CB (1)

Disconnector control DCXSWI1 I <-> O DCC (1) I <-> O DCC (1)

DCXSWI2 I <-> O DCC (2) I <-> O DCC (2)

Earthing switch control ESXSWI1 I <-> O ESC (1) I <-> O ESC (1)

Disconnector position indication DCSXSWI1 I <-> O DC (1) I <-> O DC (1)

DCSXSWI2 I <-> O DC (2) I <-> O DC (2)

DCSXSWI3 I <-> O DC (3) I <-> O DC (3)

Earthing switch indication ESSXSWI1 I <-> O ES (1) I <-> O ES (1)

ESSXSWI2 I <-> O ES (2) I <-> O ES (2)

Emergergency startup ESMGAPC1 ESTART (1) ESTART (1)

Condition monitoring

Circuit-breaker condition monitoring SSCBR1 CBCM (1) CBCM (1)

Trip circuit supervision TCSSCBR1 TCS (1) TCM (1)

TCSSCBR2 TCS (2) TCM (2)

Current circuit supervision CCRDIF1 MCS 3I (1) MCS 3I (1)

Fuse failure supervision SEQRFUF1 FUSEF (1) 60 (1)

Runtime counter for machines and devices MDSOPT1 OPTS (1) OPTM (1)

Measurement

Disturbance recorder RDRE1 DR (1) DFR (1)


56 ABB

Table 81. Functions included in the IED, continued


Load profile record LDPMSTA1 LOADPROF (1) LOADPROF (1)

Three-phase current measurement CMMXU1 3I (1) 3I (1)

Sequence current measurement CSMSQI1 I1, I2, I0 (1) I1, I2, I0 (1)

Residual current measurement RESCMMXU1 Io (1) In (1)

Three-phase voltage measurement VMMXU1 3U (1) 3V (1)

Residual voltage measurement RESVMMXU1 Uo (1) Vn (1)

Sequence voltage measurement VSMSQI1 U1, U2, U0 (1) V1, V2, V0 (1)

Three-phase power and energy measurement PEMMXU1 P, E (1) P, E (1)

RTD/mA measurement XRGGIO130 X130 (RTD) (1) X130 (RTD) (1)

Frequency measurement FMMXU1 f (1) f (1)

IEC 61850-9-2 LE (Voltage sharing)2) SMVSENDER SMVSENDER SMVSENDER

1) For example, used for RTD/mA based protection or analog GOOSE2) Only available with redundant Ethernet communication modules

31. Document revision history

Document revision/date Product version History

A/2009-07-03 2.0 First release

B/2009-10-01 2.0 Content updated

C/2010-06-11 3.0 Content updated to correspond to the product version

D/2010-06-29 3.0 Terminology updated

E/2010-09-07 3.0 Content updated

F/2012-05-11 4.0 Content updated to correspond to the product version

G/2013-02-21 4.0 FP1 Content updated to correspond to the product version

H/2014-01-24 5.0 Content updated to correspond to the product version


ABB 57

58

Contact us

ABB OyMedium Voltage Products,Distribution AutomationP.O. Box 699FI-65101 VAASA, FinlandPhone +358 10 22 11Fax +358 10 22 41094

ABB LimitedDistribution AutomationManejaVadodara 390013, IndiaPhone +91 265 2604032Fax +91 265 2638922

www.abb.com/substationautomation

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REM615 - Motor