MultiLins GeneralElectric

MAPA DE REGISTROS PARA RED MODBUS PARA RELES GE MULTILINSISTEMA EFICIENCIA ENERGÉTICA P937212CODELCO DIVISION CHUQUICAMATA

Jan-13

REV F.S.A.

MAPA DE REGISTROS PARA RED MODBUS PARA RELES GE MULTILIN

SALA ELECTRICA N° 1

CABINA TAG NOMBRE TIPO MULTILIN SR NODO MODBUS1A A220_SG01_CM01 INTERRUPTOR ALIMENTADOR TR 220-XO-011B 745# 12A A220_SG01_CM02 CELDA DE MEDIDA2B3A A220_SG01_CM03 INTERRUPTOR ALIMENTADOR BARRA MOTORES3B 469* 24A A220_SG01_CM04 INTERRUPTOR ALIMENTACION MOTOR DE COLA #4, CORREA M24B 469* 35A A220_SG01_CM05 INTERRUPTOR ALIMENTACION MOTOR DE COLA #5, CORREA M25B 469+ 46A A220_SG01_CM06 INTERRUPTOR ALIMENTACION MOTOR CHANCADOR #16B 469* 57A7B8A CCM240_SG01_MC088B 269 6

#GE Multilin 745 part number: 1601-0162-A6* GE Multilin SR469 part number: 1601-0152-A8+SR469 Version: 30D200A4.000

1A

1B

2A

2B

3A

3B

4A

4B

5A

5B

6A

6B

7A

7B

8A

8B


CABINA TAG NOMBRE TIPO MULTILIN SR NODO MODBUS1A1B2A2B3A3B A220_SG02_CM03 INT. ALIMENTACION PARA MOTORES 760 74A4B A220_SG02_CM04 INT. ALIMENTACION MOTOR DE COLA #4 CORREA M1 469+ 85A5B A220_SG02_CM05 INT. ALIMENTACION MOTOR DE COLA #5 CORREA M1 469+ 96A6B A220_SG02_CM06 INT. ALIMENTACION MOTOR CHANCADOR #2 NO PRESENTE (10)7A7B8A8B CCM240_SG02_MC08 CHANCADO TRASLADO MINA DE BANCO E4 AL BANCO 2445 269 11

+SR469 Version: 30D200A4.000

1A

1B

2A

2B

3A

3B

4A

4B

5A

5B

6A

6B

7A

7B

8A

8B

0A

0B


SWITCHGEAR 245-SG-01

CABINA TAG NOMBRE1A A270_MTS_C3_MT MOTOR CORREA BYPASS 1B A220_SG08_CM01 ALIMENTADOR PLANTA CHANCADO E42B A220_SG08_CM02 INCOMING 13B A220_SG08_CM03 ALIM. N°1 CAVERNA TRANSFERENCIA

4BA245_CVK1_MT1

MOTORES; CONDENSADOR 430 KvarA245_CVK1_MT2

5BA245_CVK1_MT3


7BA245_CVK2_MT1

MOTORES CONDENSADOR 430 KvarA245_CVK2_MT2

8A A220_SG08_CM08A ALIMENTADOR N°2 CAVERNA TRNSF.8B A220_SG08_CM08B TRANSFORMADOR 21XF23 4130/480 V 750KVA

9BA245_CVK2_MT3


10B A220_SG08_CM10 INCOMING 2

&SR-745: 1601-0070-B1-S(GEK-106592)

SWITCHGEAR SIEMENS

CABINA TAG NOMBREM4 A220_SG08_CM04 BANDA TRANSPORTADORA MTS 400W 10-1 M1 MTS C1M5 A220_SG08_CM05 BANDA TRANSPORTADORA MTS 400W 10-1 M1 MTS C2

1A

1B

2A

2B

3A

3B

4A

4B

5A

5B

6A

6B

7A

7B

M1 M2 M3 M4 M5

NOMBRE TIPO MULTILIN SR NODO MODBUSMOTOR CORREA BYPASS 469 12ALIMENTADOR PLANTA CHANCADO E4 737 13INCOMING 1 745& 14ALIM. N°1 CAVERNA TRANSFERENCIA 737 15

MOTORES; CONDENSADOR 430 Kvar 469 16469 17


MOTORES CONDENSADOR 430 Kvar 469 20469 21

ALIMENTADOR N°2 CAVERNA TRNSF. 737 22TRANSFORMADOR 21XF23 4130/480 V 750KVA 737 23


INCOMING 2 745& 26

NOMBRE TIPO MULTILIN SR NODO MODBUSBANDA TRANSPORTADORA MTS 400W 10-1 M1 MTS C1 469 27BANDA TRANSPORTADORA MTS 400W 10-1 M1 MTS C2 469 28

7A

7B

8A

8B

9A

9B

10A

10B

SALA ELECTRICA N° 10Switchgear 03-A

CABINA TAG NOMBRE1A A250_CV03A_M1_0104 SWITCH GEAR CORREA 03-A

+SR469 Version: 30D200A4.000

1A

1B

NOMBRE TIPO MULTILIN SR NODO MODBUSSWITCH GEAR CORREA 03-A 469+ 29

SR-269 PLUS SR-469 SR-737GE Multilin SR-469 part number: 1601-0152-A8

SR469 Version: 30D200A4.000

SR-745 SR-750GE Multilin part number: 1601-0162-A6

SR-745: 1601-0070-B1-S(GEK-106592)

RELE MULITIN GE SR-269 PLUS

1 Corriente

Dir.Modbus HEX DEC Descripcion HMI40529 0010 16 phase 1 current X40530 0011 17 phase 2 current X40531 0012 18 phase 3 current X40532 0013 19 average current X

2 Temperatura

Dir.Modbus HEX DEC Descripcion HMI40541 001C 28 hottest stator RTD #40542 001D 29 hottest stator temperature40543 001E 30 RTD 1 temperature X40544 001F 31 RTD 2 temperature X40545 0020 32 RTD 3 temperature X40546 0021 33 RTD 4 temperature X40547 0022 34 RTD 5 temperature X40548 0023 35 RTD 6 temperature X40549 0024 36 RTD 7 temperature X

· Corriente por cada fase

· Promedio de las corrientes

· Carga motor porcentaje FLA

· Temperatura de cada bobinado

· Temperatura de cada descanso

· Temperatura de reductor

40550 0025 37 RTD 8 temperature X40551 0026 38 RTD 9 temperature X40552 0027 39 RTD 10 temperature X

3 Voltaje

Dir.Modbus HEX DEC Descripcion HMI40633 Average Volts X40634 Voltage AB X40635 Voltage BC X40636 Voltage CA X

40641 Frequency X

4 Potencia

Dir.Modbus HEX DEC Descripcion HMI40637 007C 124 Actual Watts X40638 007D 125 Actual VARS X40639 007E 126 Power Factor X40640 007F 127 Power Factor sign X

40642 kWatt Sign X40643 kVAR Sign X

5 Demanda

sin registrosin registrosin registrosin registrosin registrosin registro

· Voltaje entre fases

· Voltaje entre fase-neutro

· Promedio voltaje fases

· Frecuencia

· Factor potencia

· Potencia real en HP y KW

· Potencia reactiva

· Potencia aparente

· Consumo Potencia en KW/h

· Demanda corriente

· Demanda potencia real

· Demanda potencia reactiva

· Demanda potencia aparente

6 Fasores

sin registrosin registrosin registrosin registrosin registro

7 Estado

Dir.Modbus HEX DEC Descripcion HMI40534 unbalance ratio

40564 estimated-time-to-trip40565 motor load (% Full load)40566 thermal capacity used

40586 Motor Alarm Status 2 X40587 Motor Trip Status 2 X

40590 Motor Current Status X40591 Motor Alarm Status 1 X40592 Motor Trip Status 1 X

40614 Cause of Last Trip Message

40627 Cause of Last Event

Codigos de Formato

F19 16 bits0000 0000 0000 00010000 0000 0000 00100000 0000 0000 01000000 0000 0000 10000000 0000 0001 00000000 0000 0010 00000000 0000 0100 0000

· Fasores de corriente y voltaje

· Estado equipo (funcionando – detenido)

· Capacidad termica usada

· Tiempo estimado de bloqueo de trip

· Causa de trip por evento

· Causa de alarma por evento

0000 0000 1000 00000000 0001 0000 00000000 0010 0000 00000000 0100 0000 00000000 1000 0000 00000001 0000 0000 00000010 0000 0000 00000100 0000 0000 00001000 0000 0000 0000

F20 16 bits0000 0000 0000 00010000 0000 0000 00100000 0000 0000 01000000 0000 0000 10000000 0000 0001 00000000 0000 0010 00000000 0000 0100 00000000 0000 1000 00000000 0001 0000 00000000 0010 0000 00000000 0100 0000 00000000 1000 0000 00000001 0000 0000 00000010 0000 0000 00000100 0000 0000 00001000 0000 0000 0000

F21 16 bits0000 0000 0000 00010000 0000 0000 00100000 0000 0000 01000000 0000 0000 10000000 0000 0001 00000000 0000 0010 00000000 0000 0100 00000000 0000 1000 0000

F22 16 bits0000 0000 0000 00010000 0000 0000 00100000 0000 0000 01000000 0000 0000 10000000 0000 0001 00000000 0000 0010 0000

0000 0000 0100 00000000 0000 1000 0000

F23 16 bits 0000 0000 0000 00000000 0000 0000 00010000 0000 0000 00100000 0000 0000 0011

F26 16 bits0000 0000 0000 00010000 0000 0000 00100000 0000 0000 01000000 0000 0000 10000000 0000 0001 00000000 0000 0010 00000000 0000 0100 00000000 0000 1000 0000

F27 16 bits0000 0000 0011 01010000 0000 0011 01100000 0000 0100 1110

F28 16 bits0000 0000 0100 01010000 0000 0100 01100000 0000 0100 01110000 0000 0100 10000000 0000 0100 10010000 0000 0100 10100000 0000 0100 10110000 0000 0100 11000000 0000 0100 11010000 0000 0100 11100000 0000 0100 11110000 0000 0101 00000000 0000 0101 00010000 0000 0101 00100000 0000 0101 00110000 0000 0101 01000000 0000 0101 01010000 0000 0101 01100000 0000 0101 01110000 0000 0101 1000

0000 0000 0101 10010000 0000 0101 10100000 0000 0101 1111

F29 16 bits0000 0000 0100 11100000 0000 0101 11010000 0000 0101 1110

Rango Unidad Codigo Formato0 to 18000 A0 to 18000 A0 to 18000 A0 to 18000 A

Rango Unidad Codigo Formato 1 to 60 to 200 °C0 to 201 (201 = no RTD) °C0 to 201 (201 = no RTD) °C0 to 201 (201 = no RTD) °C0 to 201 (201 = no RTD) °C0 to 201 (201 = no RTD) °C0 to 201 (201 = no RTD) °C0 to 201 (201 = no RTD) °C

0 to 201 (201 = no RTD) °C0 to 201 (201 = no RTD) °C0 to 201 (201 = no RTD) °C

Rango Unidad Codigo Formato0 to 65535 V0 to 65535 V0 to 65535 V0 to 65535 V

0, 400 to 720 (0 = out of range) ¥0.1

Rango Unidad Codigo Formato0 to 65535 kW0 to 65535 kvars0 to 100 (100 = OFF) ¥ 0.014E H, 5D H, 5E H F29

35H to 36H F2735H to 36H F27

Rango Unidad Codigo Formato0 to 31 %

0 to 65535 (65535 = no reading) sec.0 to 1200 %0 to 100 %

0 to 255 F210 to 255 F22

0 to 3 F230 to 65535 F190 to 65535 F20

45H to 56H F28

45H to 56H and 5FH F28

Motor Alarm Status 1Immediate O/L WarningGround Fault AlarmUnbalance AlarmUndercurrent AlarmStator RTD AlarmBearing RTD AlarmBroken Sensor Alarm

Self-Test FailureSpare Input AlarmundefinedPower Factor AlarmUndervoltage Alarmkvar Limit AlarmMeter Communication Failure AlarmThermal Capacity AlarmRTD Lotemp Alarm

Motor Trip Status 1Overload TripUnbalance TripShort Circuit TripRapid TripStator RTD TripRTD TripGround Fault TripAcceleration Time TripPhase Reversal TripInhibitsSpeed Switch TripDifferential Input TripSingle Phase TripSpare Input TripPower Factor TripUndervoltage Trip

Motor Alarm Status 2Overvoltage AlarmMechanical Jam AlarmUndefinedUndefinedUndefinedUndefinedStator RTD High AlarmRTD High Alarm

Motor Trip Status 2Overvoltage TripUndercurrent TripUndefinedUndefinedUndefinedUndefined

UndefinedUndefined

Motor Current StatusMotor Stopped (Iavg < 5% FLC)Motor Running Normal (Iavg < Iflc)Motor in Overload (Iavg > Iflc)Motor Starting

Illuminated LEDsAUX. 2 relay activeAUX. 1 relay activeALARM relay activeTRIP relay activeundefinedundefinedundefinedundefined

Power Sign+- BLANK

Cause of Last TripOverload TripUnbalance TripShort Circuit TripRapid Trip TripStator RTD TripRTD TripGround Fault TripAcceleration TripPhase Reversal TripBLANK - No Cause oSpeed Switch TripDifferential TripSingle Phase TripSpare Input TripPower Factor TripUndervoltage TripOvervoltage TripUndercurrent TripUndefined Undefined

UndefinedUndefinedInhibit Lockout

Power Factor Sign‘ ‘ BlankLeadLag

RELE MULITIN GE part number: 1601-0152-A8SR-469 PLUS

1Corriente

Dir.Modbus HEX DEC Descripcion0300 phase 1 current0302 phase 2 current0304 phase 3 current0306 average current0308 Motor load0309 Current unbalance030A Equivalent motor load030B Ground current030D Phase A differential current030E Phase B differential current030F Phase C differential current

2Temperatura

Dir.Modbus HEX DEC Descripcion0320 hottest stator RTD0321 RTD 1 temperature0322 RTD 2 temperature0323 RTD 3 temperature0324 RTD 4 temperature0325 RTD 5 temperature







0326 RTD 6 temperature0327 RTD 7 temperature0328 RTD 8 temperature0329 RTD 9 temperature032A RTD 10 temperature032B RTD 11 temperature032C RTD 12 temperature

3Voltaje

Dir.Modbus HEX DEC Descripcion0340 Voltage AB0341 Voltage BC0342 Voltage CA0343 Average Volts0344 Van0345 Vbn0346 Vcn0347 Average phase voltage0348 System frequency

4Potencia

Dir.Modbus HEX DEC Descripcion0370 Power factor

0371 Real power0373 Real power (HP)0374 Reactive power0376 Apparent power0377 MWh consumption0379 Mvarh consumption037B Mvarh generation037D Torque

5Demanda




· Frecuencia

· Factor potencia







Dir.Modbus HEX DEC Descripcion0390 Current demand0392 Real power demand0394 Reactive power demand0396 Apparent power demand0397 Peak current demand0399 Peak real power demand039B Peak reactive power demand039D Peak apparent power demand

6Fasores

Dir.Modbus HEX DEC Descripcion 0500 Va angle0501 Vb angle0502 Vc angle0503 Ia angle0504 Ib angle0505 Ic angle

7Estado

Dir.Modbus HEX DEC Descripcion0360 Tachometer RPM

0210 General status0211 Output relay status

0220 Cause of last trip0221 Time of last trip (2 words)0222 Date of last trip (2 words)

Codigos de Formato









F116 bits

F1 Example: 1234 stored as 1234F3 F3

16 bitsF4 Example: 12.34 stored as 1234F9 F4

16 bitsF10 Example: –1234 stored as –1234 (i.e. 64302)F11

F9

32 bitsF12 1st 16 bitsF17 2nd 16 bits

F18F19

F10

32 bitsF21 F134 1st 16 bitsF140 2nd 16 bitsF141 Example: 12345.6 stored as 123456 (i.e. 1st word: 0001 hex, 2nd word: E240 hex)

F11

32 bits

1st 16 bits2nd 16 bits

Example: 1234.56 stored as 123456 (i.e. 1st word: 0001 hex, 2nd word: E240 hex)

F12

32 bits


Example: -123456 stored as -123456 (i.e. 1st word: FFFE hex, 2nd word: 1DC0 hex)

F17

32 bits


F18

32 bits1st byte 2nd byte3rd & 4th byte

F19

32 bits1st byte 2nd byte

Example: 123456 stored as 123456(i.e. 1st word: 0001 hex, 2nd word: E240 hex)

Example: 123.456 stored as 123456(i.e. 1st word: 0001 hex, 2nd word: E240 hex)

Example: Feb. 20, 1995 stored as 34867142 (i.e. 1st word: 0214, 2nd word 07C6)

F19 3rd byte4th byte

F21

16 bits

< 0> 0

Example: Power Factor of 0.87lag is used as 87 (i.e. 0057)

F134

01234567891011121314151617181920212223242526272829303132

Example: 2:05pm stored as 235208704 (i.e. 1st word: 0E05, 2nd word 0000)

Unsigned16 bit integer

F134

333435363738394041424344454647484950515253545556575859606162636465666768697071727374757980

F134

81828384858687888990919293949596979899100101102103104105106107108109110111112↓118119120121122123124125126127128129

F134

130131132136137138139140141142143

F140

bit 0bit 1bit 2bit 3bit 4bit 5bit 6bit 7bit 8bit 9bit 10 bit 11 bit 12 bit 13 bit 14 bit 15

F141

bit 0bit 1bit 2bit 3bit 4bit 5bit 6 to 15

Unsigned 16 bit integer

Unsigned 16 bit integer

SR469 Version: 30D200A4.000

HMI Min Max Unidad Codigo FormatoX 0 100000 A F9X 0 100000 A F9X 0 100000 A F9X 0 100000 A F9X 0 2000 FLA F3X 0 100 % F1X 0 2000 FLA F3X 0 5000 A F11

0 5000 A F10 5000 A F10 5000 A F1

HMI Min Max Unidad Codigo FormatoX -50 250 °C F4X -50 250 °C F4X -50 250 °C F4X -50 250 °C F4X -50 250 °C F4X -50 250 °C F4

X -50 250 °C F4X -50 250 °C F4X -50 250 °C F4X -50 250 °C F4X -50 250 °C F4X -50 250 °C F4X -50 250 °C F4

HMI Min Max Unidad Codigo FormatoX 0 20000 V F1X 0 20000 V F1X 0 20000 V F1X 0 20000 V F1X 0 20000 V F1X 0 20000 V F1X 0 20000 V F1X 0 20000 V F1X 0 12000 Hz F3

HMI Min Max Unidad Codigo FormatoX –99 100 - F21 X –99999 99999 kW F12 X 0 65535 hp F1 X –99999 99999 kvar F12 X 0 65535 kVA F1 X 0 999999999 MWh F17X 0 999999999 Mvarh F17X 0 999999999 Mvarh F17X 0 999999999 Nm/ftlb F10

HMI Min Max Unidad Codigo FormatoX 0 100000 A F9 X 0 99999 kW F12 X 0 99999 kvar F12 X 0 65535 kVA F1 X 0 100000 A F9 X 0 99999 kW F12 X 0 99999 kvar F12 X 0 65535 kVA F1

HMI Min Max Unidad Codigo Formato0 359 ° F10 359 ° F10 359 ° F10 359 ° F10 359 ° F10 359 ° F1

HMI Min Max Unidad Codigo FormatoX 0 7200 RPM F1

X 0 65535 F140X 0 63 F141

X 0 49 F134- - F19- - F18

16 bitsUNSIGNED VALUE

Example: 1234 stored as 123416 bits

UNSIGNED VALUE,2 DECIMAL PLACESExample: 12.34 stored as 123416 bits

2’s COMPLEMENT SIGNED VALUEExample: –1234 stored as –1234 (i.e. 64302)32 bits UNSIGNED LONG VALUE1st 16 bits High Order Word of Long Value2nd 16 bits Low Order Word of Long Value

32 bits UNSIGNED LONG VALUE, 1 DECIMAL PLACE

1st 16 bits High Order Word of Long Value2nd 16 bits Low Order Word of Long Value


32 bits UNSIGNED LONG VALUE, 2 DECIMAL PLACES



32 bits 2’s COMPLEMENT SIGNED LONG VALUE


Example: -123456 stored as -123456 (i.e. 1st word: FFFE hex, 2nd word: 1DC0 hex)

32 bits UNSIGNED LONG VALUE, 3 DECIMAL PLACES


32 bits DATE (MM/DD/YYYY)1st byte Month (1 to 12)2nd byte Day (1 to 31)3rd & 4th byte Year (1995 to 2094)

32 bits TIME (HH:MM:SS:hh)1st byte Hours (0 to 23)2nd byte Minutes (0 to 59)

Example: 123456 stored as 123456(i.e. 1st word: 0001 hex, 2nd word: E240 hex)

Example: 123.456 stored as 123456(i.e. 1st word: 0001 hex, 2nd word: E240 hex)

Example: Feb. 20, 1995 stored as 34867142 (i.e. 1st

3rd byte Seconds (0 to 59)4th byte Hundredths of seconds (0 to 99)

16 bits

< 0 Leading Power Factor - Negative> 0 Lagging Power Factor - Positive

Example: Power Factor of 0.87lag is used as 87 (i.e. 0057)

0 NoEvent/TripToDate1 Incomplete Seq Trip2 Remote Trip3 Speed Switch Trip4 Load Shed Trip5 PressureSw.Trip6 Vibration Sw. Trip7 TachometerTrip8 General Sw. A Trip9 General Sw. B Trip10 General Sw. C Trip11 General Sw. D Trip12 Overload Trip13 Short Circuit Trip14 Short Circuit Backup15 Mechanical Jam Trip16 Undercurrent Trip17 Current U/B Trip18 Ground Fault Trip19 Ground Fault Backup20 Differential Trip21 Acceleration Trip22 RTD 1 Trip23 RTD 2 Trip24 RTD 3 Trip25 RTD 4 Trip26 RTD 5 Trip27 RTD 6 Trip28 RTD 7 Trip29 RTD 8 Trip30 RTD 9 Trip31 RTD 10 Trip32 RTD 11 Trip

Example: 2:05pm stored as 235208704 (i.e. 1st word:

2’s COMPLEMENT SIGNED VALUE2 DECIMAL PLACES (Power Factor)

CAUSE OF EVENT / CAUSE OF LAST TRIP (UP TO 49)

33 RTD 12 Trip34 Undervoltage Trip35 Overvoltage Trip36 Phase Reversal Trip37 Volt. Frequency Trip38 Power Factor Trip39 Reactive Power Trip40 Underpower Trip41 Analog I/P 1 Trip42 Analog I/P 2 Trip43 Analog I/P 3 Trip44 Analog I/P 4 Trip45 Single Phasing Trip46 Reverse Power Trip47 Field Circuit Open Trip (Valid only for Mod 001)48 Analog Diff 1-2 Trip49 Analog Diff 3-4 Trip50 ----51 Remote Alarm52 Pressure Sw. Alarm53 Vibration Sw. Alarm54 Counter Alarm55 Tachometer Alarm56 General Sw. A Alarm57 General Sw. B Alarm58 General Sw. C Alarm59 General Sw. D Alarm60 Thermal Model Alarm61 Overload Alarm62 Undercurrent Alarm63 Current U/B Alarm64 Ground Fault Alarm65 RTD 1 Alarm66 RTD 2 Alarm67 RTD 3 Alarm68 RTD 4 Alarm69 RTD 5 Alarm70 RTD 6 Alarm71 RTD 7 Alarm72 RTD 8 Alarm73 RTD 9 Alarm74 RTD 10 Alarm75 RTD 11 Alarm79 Undervoltage Alarm80 Overvoltage Alarm

81 Volt. Frequency Alarm82 Power Factor Alarm83 Reactive Power Alarm84 Underpower Alarm85 Trip Counter Alarm86 Starter Failed Alarm87 Current Demand Alarm88 kW Demand Alarm89 kvar Demand Alarm90 kVA Demand Alarm9192 Analog I/P 1 Alarm93 Analog I/P 2 Alarm94 Analog I/P 3 Alarm95 Analog I/P 4 Alarm96 Reverse Power Alarm97 Incomplete Seq Alarm (Valid only for Mod 001)98 Analog Diff 1-2 Alarm99 Analog Diff 3-4 Alarm100 Self-test Warning 9101 Service Alarm102 Control Power Lost103 Cont . Power Applied104 Emergency Rst. Close105 Emergency Rst. Open106 Start While Blocked107 Relay Not Inserted108 Trip Coil Super.109 Breaker Failure110 Welded Contactor111 Simulation Started112 Simulation Stopped

↓118 Digital Trace Trigger119 Serial Trace Trigger120 RTD 1 High Alarm121 RTD 2 High Alarm122 RTD 3 High Alarm123 RTD 4 High Alarm124 RTD 5 High Alarm125 RTD 6 High Alarm126 RTD 7 High Alarm127 RTD 8 High Alarm128 RTD 9 High Alarm129 RTD 10 High Alarm

130 RTD 11 High Alarm131 RTD 12 High Alarm132 Overtorque Alarm136 4 ALARM Relay Forced137 5 BLOCK Relay Forced138 Force 1 TRIP Disabled139 Force 2 AUX Disabled140 Force 3 AUX Disabled141 Force 4 ALARM Disabled142 Force 5 BLOCK Disabled143 Motor Started

GENERAL STATUS

bit 0 Relay in Servicebit 1 Active Trip Conditionbit 2 Active Alarm Conditionbit 3 Reservedbit 4 Reservedbit 5 Reservedbit 6 Reservedbit 7 Reservedbit 8 Motor Stoppedbit 9 Motor Startingbit 10 Motor Runningbit 11 Overload Pickupbit 12 Unbalance Pickupbit 13 Ground Pickupbit 14 Hot RTDbit 15 Loss of Load

GENERAL STATUS

bit 0 1 TRIPbit 1 2 AUXILIARYbit 2 3 AUXILIARYbit 3 4 ALARMbit 4 5 BLOCK STARTbit 5 6 SERVICEbit 6 to 15 Not Used

RELE MULITIN GE SR-737

1Corriente

Dir.Modbus HEX DEC0010 0011 0012 0013

2Temperatura

Dir.Modbus HEX DEC







3Voltaje

Dir.Modbus HEX DEC

4Potencia

Dir.Modbus HEX DEC

5Demanda




· Frecuencia

· Factor potencia







Dir.Modbus HEX DEC

6Fasores

Dir.Modbus HEX DEC

7Estado

Dir.Modbus HEX DEC00140015

00170018

0024 0025









Codigos de Formato

FORMAT TYPEF1 UNSIGNED INTEGER

F101 STATUS BYTE

F102 DIP Switches

F103

MAIN OUTPUT RELAYS

737 OUTPUT RELAYS

F105 LEDs

F105 LEDs

F106 BARGRAPH

Descripcion HMIPhase A current XPhase B current XPhase C current XGround current X

Descripcion HMI

Descripcion HMI

Descripcion HMI

Descripcion HMI

Descripcion HMI

Descripcion HMIRelay Status Register XOutput relays X

LEDs XBargraph X

Cause of last trip XLast OC trip time X

DESCRIPTION0 to 65535XXXX XXXX XXXX XXX1 = Phase A pickup xXXXX XXXX XXXX XX1X = Phase B pickup xXXXX XXXX XXXX X1XX = Phase C pickup xXXXX XXXX XXXX 1XXX = Ground pickup xXXXX XXXX XXX1 XXXX = Relay in service xXXXX XXXX XX1X XXXX = Service required xXXXX XXXX X1XX XXXX = Test mode xXXXX XXXX 1XXX XXXX = Relay tripped xXXXX XXX1 XXXX XXXX = not usedXXXX XX1X XXXX XXXX = not usedXXXX X1XX XXXX XXXX = not usedXXXX 1XXX XXXX XXXX = not usedXXX1 XXXX XXXX XXXX = not usedXX1X XXXX XXXX XXXX = trip relays disabled = 1 xX1XX XXXX XXXX XXXX = simulated dials = 1 x1XXX XXXX XXXX XXXX = simulated current = 1 xXXXX XXXX XXXX XXX1 = Switch 1 on=1XXXX XXXX XXXX XX1X = Switch 2 on = 1XXXX XXXX XXXX X1XX = Switch 3 on = 1XXXX XXXX XXXX 1XXX = Switch 4 on = 1XXXX XXXX XXX1 XXXX = Switch 5 on = 1XXXX XXXX XX1X XXXX = Switch 6 on = 1XXXX XXXX X1XX XXXX = Switch 7 on = 1XXXX XXXX 1XXX XXXX = Switch 8 on = 1XXXX XXXX XXXX XXX1 = Trip relay on = 1 xXXXX XXXX XXXX XX1X = Aux trip relay on =1 xXXXX XXXX XXXX X1XX = Service relay on = 1 xXXXX XXXX XXXX 1XXX = not usedXXXX XXXX XXX1 XXXX = not usedXXXX XXXX XX1X XXXX = not usedXXXX XXXX X1XX XXXX = not usedXXXX XXXX 1XXX XXXX = not usedXXXX XXX1 XXXX XXXX = Phase A time OC pickup/trip (51P-A)XXXX XX1X XXXX XXXX = Phase B time OC pickup/trip (51P-B)XXXX X1XX XXXX XXXX = Phase C time OC pickup/trip (51P-C)XXXX 1XXX XXXX XXXX = Ground time OC pickup/trip (51G)XXX1 XXXX XXXX XXXX = Phase A nest pickup/trip (50P-A)XX1X XXXX XXXX XXXX = Phase B nest pickup/trip (50P-B)X1XX XXXX XXXX XXXX = Phase C nest pickup/trip (50P-C)1XXX XXXX XXXX XXXX = Ground nest pickup/trip (50G)XXXX XXXX XXXX XXX1 = Phase A overcurrent LED on = 1 x

XXXX XXXX XXXX XX1X = Phase B overcurrent LED on = 1 xXXXX XXXX XXXX X1XX = Phase C overcurrent LED on = 1 xXXXX XXXX XXXX 1XXX = Ground overcurrent LED on = 1 xXXXX XXXX XXX1 XXXX = Phase A instantaneous LED on = 1 xXXXX XXXX XX1X XXXX = Phase B instantaneous LED on = 1 xXXXX XXXX X1XX XXXX = Phase C instantaneous LED on = 1 xXXXX XXXX 1XXX XXXX = Ground instantaneous LED on = 1 xXXXX XXX1 XXXX XXXX = Phase pickup LED on = 1 xXXXX XX1X XXXX XXXX = Ground pickup LED on = 1 xXXXX X1XX XXXX XXXX = Relay in service LED on = 1 xXXXX 1XXX XXXX XXXX = Service required LED on = 1 xXXXX XXXX XXXX XXX1 = 100% indicator on = 1XXXX XXXX XXXX XX1X = 90% indicator on = 1XXXX XXXX XXXX X1XX = 80% indicator on = 1XXXX XXXX XXXX 1XXX = 70% indicator on = 1XXXX XXXX XXX1 XXXX = 60% indicator on = 1XXXX XXXX XX1X XXXX = 50% indicator on = 1XXXX XXXX X1XX XXXX = 40% indicator on = 1XXXX XXXX 1XXX XXXX = 30% indicator on = 1XXXX XXX1 XXXX XXXX = 20% indicator on = 1XXXX XX1X XXXX XXXX = 10% indicator on = 1

Min Max Unidad Codigo Formato0 2000 % CT F10 2000 % CT F10 2000 % CT F10 2000 % CT F1

Min Max Unidad Codigo Formato



Min Max Unidad Codigo Formato- - - F101

--- --- --- F103

--- --- --- F105--- --- --- F106

Bits --- --- F1130 65000 --- F115


1Corriente

Dir.Modbus HEXWinding 1 current 0280

028102820283028402850286028702880289028A028B

Winding 2 current 029002910292029302940295029602970298




0299029A029B

Winding 3 current 02A002A102A202A302A402A502A602A702A802A902AA02AB

Sequence currents 02B0 02B1 02B2 02B3 02B4 02B5 02B6 02B7 02B8 02B902BA02BB02BC02BD02BE02BF02C002C1

Differential current 02D002D102D202D302D402D5

Restraint current 02D602D7

02D8

Ground differential current 02D902DA02DB

Total harmonic distortion042004210422042304240425042604270428

Harmonic derating043004310432

2Temperatura

Dir.Modbus HEXAmbient temperature 0478

Loss-of-life 048004810483

3Voltaje

Dir.Modbus HEX0440







· Frecuencia

0441

0449044A044B044C

4Potencia

Dir.Modbus HEXPower 0490

0491 0492 0493 0494 0495 0496 0497 0498 0499 049A 049B

Winding 1 04A004A204A4

Winding 2 04A804AA04AC

Winding3 04B0 04B2 04B4

Energy 0500 0502 0504 0506

· Factor potencia





0508 050A 050C 050E 0510 0512 0514 0516 0518 051A

5Demanda

Dir.Modbus HEXCurrent demand 0450

0452 0454 0455 0456 0457 0458 0459 045B 045D 045E 045F 0460 0461 0462 0464 0466 0467 0468 0469 046A 046B 046D

6Fasores (Incluidos en 1 Corrientes)





Dir.Modbus HEXver Seccion Corrientesver Seccion Corrientesver Seccion Corrientesver Seccion Corrientesver Seccion Corrientesver Seccion Corrientes

7Estado

Dir.Modbus HEX020002010202020302040205

0445

Event recorder 0800 0802 0804 0805

Event recorder data 0830 0832 0834 0835 0836 0837 0838 0839 083A 083B 083C 083D083E 083F







0840 0841 0842 0843 0844 0845 0846 0847 0848 0849 084A 084B 084C 084D084E 084F 0850 0851 0852 0853 0854 0855 0856 085708580859085A085B085C085D085E085F0860086108620863086408650866086708680869086A

Commands 0080

Codigo Formato

F1 F18 F2 F19 F3 F4 F6 F7

F1: Unsigned value (16 bits)Example: 1234 stored as 1234F2: Unsigned value, 1 decimal place (16 bits)Example: 123.4 stored as 1234F3: Unsigned value, 2 decimal places (16 bits)Example: 12.34 stored as 1234F4: Two’s-complement signed value (16 bits)Example: –1234 stored as –1234F5: Two’s-complement signed value, 1 decimal place (16 bits)Example: –123.4 stored as –1234F6: Two’s-complement signed value, 2 decimal places (16 bits)Example: –12.34 stored as –1234F7: Unsigned long value (32 bits)First block of 16 bits: high-order word of long valueSecond block of 16 bits: low-order word of long valueExample: 123456 stored as 123456

F18: Maximum demand phase (16-bit enumeration)Value Maximum demand

0 in phase A1 in phase B2 in phase C

F20: Relay status (16-bit bitmask)Bitmask

–––– –––– –––– –––1 –––– –––– –––– ––1– –––– –––– –––– –1–– –––– –––– –––– 1––– –––– –––– –––1 –––– –––– –––– ––1– –––– –––– –––– –1–– ––––

–––– –––– 1––– ––––

F21: System status (16-bit bitmask)Bitmask

–––– –––– –––– –––1 –––– –––– –––– ––1– –––– –––– –––– –1–– –––– –––– –––– 1––– –––– –––– –––1 –––– –––– –––– ––1– –––– –––– –––– –1–– –––– –––– –––– 1––– ––––

F22: Time (32 bits)First block of eight bits (0000 0000 ---- ---- ---- ---- ----- ----): hours, 0 to 23 in steps of 1Second block of eight bits (---- ---- 0000 0000 ---- ---- ---- ----): minutes, 0 to 59 in steps of

1Third and fourth block of four bits(---- ---- ---- ---- 0000 0000 0000 0000): seconds in format SS.SSSS (0 to 59999 in steps of 1). For example, 2.220 seconds stored as 2220.Note: if the time has never been set, then all bits will be set to 1.F23: Date (32 bits)First block of eight bits (0000 0000 ---- ---- ---- ---- ----- ----): month, 0 to 12 in steps of 1Second block of eight bits (---- ---- 0000 0000 ---- ---- ---- ----): day, 0 to 31 in steps of 1Third and fourth block of four bits(---- ---- ---- ---- 0000 0000 0000 0000): year, 1990 to 2089 in steps of 1.Note: if the date has never been set, then all bits will be set to 1.

F24: Event type and cause (16-bit enumeration)First block of four bits (0000 ---- ---- ----): type of event, enumerated as follows:

Value Bit arrangement 0 0000 –––– –––– –––– 1 0001 –––– –––– –––– 2 0010 –––– –––– –––– 3 0011 –––– –––– –––– 4 0100 –––– –––– –––– 5 0101 –––– –––– –––– 6 0110 –––– –––– ––––

Second block of twelve bits (---- 0000 0000 0000): cause of event, enumerated as follows:

Value Bit arrangement 0 –––– 0000 0000 0000 1 –––– 0000 0000 0001 2 –––– 0000 0000 0010

3 –––– 0000 0000 0011 4 –––– 0000 0000 0100 5 –––– 0000 0000 0101 6 –––– 0000 0000 0110 7 –––– 0000 0000 0111 8 –––– 0000 0000 1000 9 –––– 0000 0000 1001

10 –––– 0000 0000 1010 11 –––– 0000 0000 1011 12 –––– 0000 0000 1100 13 –––– 0000 0000 1101 14 –––– 0000 0000 1110 15 –––– 0000 0000 1111 16 –––– 0000 0001 0000 17 –––– 0000 0001 0001 18 –––– 0000 0001 0010 19 –––– 0000 0001 0011 20 –––– 0000 0001 0100 21 –––– 0000 0001 0101 22 –––– 0000 0001 0110 23 –––– 0000 0001 0111 24 –––– 0000 0001 1000 25 –––– 0000 0001 1001 26 –––– 0000 0001 1010 27 –––– 0000 0001 1011 28 –––– 0000 0001 1100 29 –––– 0000 0001 1101 30 –––– 0000 0001 1110 31 –––– 0000 0001 1111 32 –––– 0000 0010 0000 33 –––– 0000 0010 0001 34 –––– 0000 0010 0010 35 –––– 0000 0010 0011 36 –––– 0000 0010 0100 37 –––– 0000 0010 0101 38 –––– 0000 0010 0110 39 –––– 0000 0010 0111 40 –––– 0000 0010 1000 41 –––– 0000 0010 1001 42 –––– 0000 0010 1010 43 –––– 0000 0010 1011 44 –––– 0000 0010 1100 45 –––– 0000 0010 1101 46 –––– 0000 0010 1110 47 –––– 0000 0010 1111

48 –––– 0000 0011 0000 49 –––– 0000 0011 0001 50 –––– 0000 0011 0010 51 –––– 0000 0011 0011 52 –––– 0000 0011 0100 53 –––– 0000 0011 0101 54 –––– 0000 0011 0110 55 –––– 0000 0011 0111 56 –––– 0000 0011 1000 57 –––– 0000 0011 1001 58 –––– 0000 0011 1010 59 –––– 0000 0011 1011 60 –––– 0000 0011 1100 61 –––– 0000 0011 1101 62 –––– 0000 0011 1110 63 –––– 0000 0011 1111 64 –––– 0000 0100 0000 65 –––– 0000 0100 0001 66 –––– 0000 0100 0010 67 –––– 0000 0100 0011 68 –––– 0000 0100 0100 69 –––– 0000 0100 0101 70 –––– 0000 0100 0110 71 –––– 0000 0100 0111 72 –––– 0000 0100 1000 73 –––– 0000 0100 1001 74 –––– 0000 0100 1010 75 –––– 0000 0100 1011 76 –––– 0000 0100 1100 77 –––– 0000 0100 1101 78 –––– 0000 0100 1110 79 –––– 0000 0100 1111 80 –––– 0000 0101 0000 81 –––– 0000 0101 0001 82 –––– 0000 0101 0010 83 –––– 0000 0101 0011 84 –––– 0000 0101 0100 85 –––– 0000 0101 0101 86 –––– 0000 0101 0110 87 –––– 0000 0101 0111 88 –––– 0000 0101 1000 89 –––– 0000 0101 1001 90 –––– 0000 0101 1010 91 –––– 0000 0101 1011 92 –––– 0000 0101 1100

93 –––– 0000 0101 1101 94 –––– 0000 0101 1110 95 –––– 0000 0101 1111 96 –––– 0000 0110 0000 97 –––– 0000 0110 0001 98 –––– 0000 0110 0010 99 –––– 0000 0110 0011

100 –––– 0000 0110 0100 101 –––– 0000 0110 0101 102 –––– 0000 0110 0110 103 –––– 0000 0110 0111 104 –––– 0000 0110 1000 105 –––– 0000 0110 1001 106 –––– 0000 0110 1010 107 –––– 0000 0110 1011 108 –––– 0000 0110 1100 109 –––– 0000 0110 1101 110 –––– 0000 0110 1110 111 –––– 0000 0110 1111 112 –––– 0000 0111 0000 113 –––– 0000 0111 0001 114 –––– 0000 0111 0010 115 –––– 0000 0111 0011 116 –––– 0000 0111 0100 117 –––– 0000 0111 0101 118 –––– 0000 0111 0110 119 –––– 0000 0111 0111 120 –––– 0000 0111 1000 121 –––– 0000 0111 1001 122 –––– 0000 0111 1010 123 –––– 0000 0111 1011 124 –––– 0000 0111 1100 125 –––– 0000 0111 1101 126 –––– 0000 0111 1110 127 –––– 0000 0111 1111 128 –––– 0000 1000 0000 129 –––– 0000 1000 0001 130 –––– 0000 1000 0010 131 –––– 0000 1000 0011 132 –––– 0000 1000 0100 133 –––– 0000 1000 0101 134 –––– 0000 1000 0110 135 –––– 0000 1000 0111 136 –––– 0000 1000 1000 137 –––– 0000 1000 1001

138 –––– 0000 1000 1010 139 –––– 0000 1000 1011 140 –––– 0000 1000 1100 141 –––– 0000 1000 1101 142 –––– 0000 1000 1110

Example: 302Ah = 12230 decimal = 0011 0000 0010 1010 = Underfrequency 1 pickup, since 0011 (first four bits) indicates a pickup event and 0000 0010 1010 (next 12 bits) indicate an underfrequency 1 cause of event .

F25: Two’s-complement signed value, 3 decimal places (16 bits)Example: –1.234 stored as –1234

F35: Relay conditions (16-bit bitmask)Bitmask –––– –––– –––– –––1 –––– –––– –––– ––1– –––– –––– –––– –1–– –––– –––– –––1 –––– –––– –––– ––1– –––– –––– –––– –1–– –––– –––– –––– 1––– ––––

F44: Operation status (16-bit bitmask)Bitmask

F45: Analog output value (16-bit enumeration)Value Analog output

0 Winding 1 phase A current 1 Winding 1 phase B current 2 Winding 1 phase C current 3 Winding 2 phase A current 4 Winding 2 phase B current 5 Winding 2 phase C current 6 Winding 3 phase A current 7 Winding 3 phase B current 8 Winding 3 phase C current

–––– –––– –––– –––0–––– –––– –––– –––1

–––– –––– –––– ––0––––– –––– –––– ––1–

–––– –––– –––– –0–––––– –––– –––– –1––

–––– –––– –––– 0––––––– –––– –––– 1–––

9 Winding 1 loading 10 Winding 2 loading 11 Winding 3 loading 12 Winding 1 phase A THD 13 Winding 1 phase B THD 14 Winding 1 phase C THD 15 Winding 2 phase A THD 16 Winding 2 phase B THD 17 Winding 2 phase C THD 18 Winding 3 phase A THD 19 Winding 3 phase B THD 20 Winding 3 phase C THD 21 Winding 1 derating 22 Winding 2 derating 23 Winding 3 derating 24 Frequency25 Tap position26 Voltage27 Winding 1 phase A demand28 Winding 1 phase B demand29 Winding 1 phase C demand30 Winding 2 phase A demand31 Winding 2 phase B demand32 Winding 2 phase C demand33 Winding 3 phase A demand34 Winding 3 phase B demand35 Winding 3 phase C demand36 Analog input37 Maximum event winding 1 Ia38 Maximum event winding 1 Ib39 Maximum event winding 1 Ic40 Maximum event winding 1 Ig41 Maximum event winding 2 Ia42 Maximum event winding 2 Ib43 Maximum event winding 2 Ic44 Maximum event winding 2 Ig45 Maximum event winding 3 Ia46 Maximum event winding 3 Ib47 Maximum event winding 3 Ic48 Maximum event winding 3 Ig

F50: Output relay states (16-bit bitmask)Bitmask –––– –––– –––– –––x

–––– –––– –––– ––x– –––– –––– –––– –x–– –––– –––– –––– x––– –––– –––– –––x –––– –––– –––– ––x– –––– –––– –––– –x–– –––– –––– –––– x––– –––– –––– –––x –––– ––––

F53: Unsigned value, 3 decimal places (16 bits)Example: 1.234 stored as 1234F54: Force LED state (16-bit bitmask)

Bitmask –––– –––– –––– –––1 –––– –––– –––– ––1– –––– –––– –––– –1–– –––– –––– –––– 1––– –––– –––– –––1 –––– –––– –––– ––1– –––– –––– –––– –1–– –––– –––– –––– 1––– ––––

F78: Unsigned value, auto-ranging based onwinding 1 phase CT primary value (16 bits)For winding 1 phase CT primary ≤2 A, F78 is an unsigned value with three decimal places. For example, 1.234 is stored as 1234.For 2 A <winding 1 phase CT primary ≤20 A, F78 is an unsigned value with two decimal places. For example, 12.34 is stored as 1234.For 20 A <winding 1 phase CT primary ≤200 A, F78 is an unsigned value with one decimal place. For example, 123.4 is stored as 1234.For 200 A < winding 1 phase CT primary ≤2000 A, F78 is a standard unsigned value. For example, 1234 is stored as 1234.For winding 1 phase CT primary >2000 A, F78 is a standard unsigned value scaled by 10. For example, 12340 is stored as 1234.

F79: Unsigned value, auto-ranging based onwinding 2 phase CT primary value (16 bits)For winding 2 phase CT primary ≤2 A, F79 is an unsigned value with three decimal places. For example, 1.234 is stored as 1234.For 2 A <winding 2 phase CT primary ≤20 A, F79 is an unsigned value with two decimal places. For example, 12.34 is stored as 1234.For 20 A <winding 2 phase CT primary ≤200 A, F79 is an unsigned value with one decimal place. For example, 123.4 is stored as 1234.For 200 A < winding 2 phase CT primary ≤2000 A, F78 is a standard unsigned value. For example, 1234 is stored as 1234.

For winding 2 phase CT primary >2000 A, F78 is a standard unsigned value scaled by 10. For example, 12340 is stored as 1234.

F80: Unsigned value, auto-ranging based onwinding 3 phase CT primary value (16 bits)For winding 3 phase CT primary ≤2 A, F80 is an unsigned value with three decimal places. For example, 1.234 is stored as 1234.For 2 A <winding 3 phase CT primary ≤20 A, F80 is an unsigned value with two decimal places. For example, 12.34 is stored as 1234.For 20 A <winding 3 phase CT primary ≤200 A, F80 is an unsigned value with one decimal place. For example, 123.4 is stored as 1234.For 200 A < winding 3 phase CT primary ≤2000 A, F78 is a standard unsigned value. For example, 1234 is stored as 1234.For winding 3 phase CT primary >2000 A, F78 is a standard unsigned value scaled by 10. For example, 12340 is stored as 1234.

F81: Unsigned value, auto-ranging based on winding 1 ground CT primary (16 bits)For winding 1 ground CT primary ≤2 A, F81 is an unsigned value with three decimal places. For example, 1.234 is stored as 1234.For 2 A <winding 1 ground CT primary ≤20 A, F81 is an unsigned value with two decimal places. For example, 12.34 is stored as 1234.For 20 A <winding 1 ground CT primary ≤200 A, F81 is an unsigned value with one decimal place. For example, 123.4 is stored as 1234.For winding 1 ground CT primary >200 A, F81 is a standard unsigned value. For example, 1234 is stored as 1234.



F93: Two’s-complement, signed value, auto-ranging based on winding 1 phase CT primary (16 bits)

W1≤2A No 2A<W1≤20A No 20A<W1≤200A No W1>200A No W1≤2A Yes 2A<W1≤20A Yes 20A<W1≤200A Yes W1>200A Yes


W2≤2A No2A<W2≤20A No20A<W2≤200A NoW2>200A NoW2≤2A Yes2A<W2≤20A Yes20A<W2≤200A YesW2>200A Yes


W3≤2A No 2A<W3≤20A No 20A<W3≤200A No W3>200A No W3≤2A Yes 2A<W3≤20A Yes 20A<W3≤200A Yes W3>200A Yes

Winding 1 phase CTprimary ["W1"]

Is W1 Rated Loada Low MVA Transformer?





F96: Unsigned value, auto-ranging based on winding 1 phase CT primary (32 bits)For winding 1 phase CT primary ≤2 A, format F96 is an unsigned value with three decimal places. For example, 1.234 is stored as 1234.For 2 A <winding 1 phase CT primary ≤20 A, format F96 is an unsigned value with two decimal places. For example,12.34 is stored as 1234.For 20 A <winding 1 phase CT primary ≤200 A, format F96 is an unsigned value with one decimal place. For example, 123.4 is stored as 1234.For 200 A <winding 1 phase CT primary ≤2000 A, format F96 is a standard unsigned value. For example, 1234 is stored as 1234.For winding 1 phase CT primary >2000 A, format F96 is an unsigned value scaled by 10. For example, 12340 is stored as 1234.



F156: floating point (32 bits)IEEE 754 single precision binary floating-point format: binary32.The first modbus address contains the sign bit, exponent, and 7 most significant bits of the fraction. The second modbus address contains the 16 least significant bits of the fraction.Reference: http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=4610935

F49 16 bits ESTADOS DE ENTRADA xxxx xxxx xxxx xxx1 Entrada 1 (0 = Abierto, 1 = cerrado)

xxxx xxxx xxxx xx1x Entrada 2(0 = Abierto, 1 = cerrado) xxxx xxxx xxxx x1xx Entrada 3(0 = Abierto, 1 = cerrado) xxxx xxxx xxxx 1xxx Entrada 4(0 = Abierto, 1 = cerrado) xxxx xxxx xxx1 xxxx Entrada 5(0 = Abierto, 1 = cerrado) xxxx xxxx xx1x xxxx Entrada 6(0 = Abierto, 1 = cerrado) xxxx xxxx x1xx xxxx Entrada 7(0 = Abierto, 1 = cerrado) xxxx xxxx 1xxx xxxx Entrada 8(0 = Abierto, 1 = cerrado) xxxx xxx1 xxxx xxxx Entrada 9(0 = Abierto, 1 = cerrado) xxxx xx1x xxxx xxxx Entrada 10(0 = Abierto, 1 = cerrado) xxxx x1xx xxxx xxxx Entrada 11 (0 = Abierto, 1 = cerrado) xxxx 1xxx xxxx xxxx Entrada 12 (0 = Abierto, 1 = cerrado) xxx1 xxxx xxxx xxxx Entrada 13 (0 = Abierto, 1 = cerrado) xx1x xxxx xxxx xxxx Entrada 14 (0 = Abierto, 1 = cerrado) x1xx xxxx xxxx xxxx Entrada 15 (0 = Abierto, 1 = cerrado) 1xxx xxxx xxxx xxxx Entrada 16 (0 = Abierto, 1 = cerrado)

GE Multilin part number: 1601-0162-A6

DEC Descripcion HMIWinding 1 phase A current magnitude XWinding 1 phase A current angle Winding 1 phase B current magnitude XWinding 1 phase B current angle Winding 1 phase C current magnitude XWinding 1 phase C current angle Winding 1 neutral current magnitude XWinding 1 neutral current angle Winding 1 ground current magnitude XWinding 1 ground current angle Winding 1 loading Winding 1 average phase current X

Winding 2 phase A current magnitude XWinding 2 phase A current angle Winding 2 phase B current magnitude XWinding 2 phase B current angle Winding 2 phase C current magnitude XWinding 2 phase C current angle Winding 2 neutral current magnitude XWinding 2 neutral current angle Winding 2 ground current magnitude X

Winding 2 ground current angle Winding 2 loading Winding 2 average phase current X

Winding 3 phase A current magnitude Winding 3 phase A current angle Winding 3 phase B current magnitude Winding 3 phase B current angle Winding 3 phase C current magnitude Winding 3 phase C current angle Winding 3 neutral current magnitude Winding 3 neutral current angle Winding 3 ground current magnitude Winding 3 ground current angle Winding 3 loading Winding 3 average phase current

Winding 1 positive-sequence current magnitude Winding 1 positive-sequence current angle Winding 2 positive-sequence current magnitude Winding 2 positive-sequence current angle Winding 3 positive-sequence current magnitude Winding 3 positive-sequence current angle Winding 1 negative-sequence current magnitude Winding 1 negative-sequence current angle Winding 2 negative-sequence current magnitude Winding 2 negative-sequence current angle Winding 3 negative-sequence current magnitude Winding 3 negative-sequence current angle Winding 1 zero-sequence current magnitude Winding 1 zero-sequence current angle Winding 2 zero-sequence current magnitude Winding 2 zero-sequence current angle Winding 3 zero-sequence current magnitude Winding 3 zero-sequence current angle

Phase A differential current magnitude Phase A differential current angle Phase B differential current magnitude Phase B differential current angle Phase C differential current magnitude Phase C differential current angle

Phase A restraint current Phase B restraint current

Phase C restraint current

Winding 1 ground differential current Winding 2 ground differential current Winding 3 ground differential current

Winding 1 phase A total harmonic distortion Winding 1 phase B total harmonic distortion Winding 1 phase C total harmonic distortion Winding 2 phase A total harmonic distortion Winding 2 phase B total harmonic distortion Winding 2 phase C total harmonic distortion Winding 3 phase A total harmonic distortion Winding 3 phase B total harmonic distortion Winding 3 phase C total harmonic distortion

Winding 1 harmonic derating factor Winding 2 harmonic derating factor Winding 3 harmonic derating factor

DEC Descripcion HMIAmbient temperature

Hottest-spot winding temperature Total accumulated loss-of-life (2 registers) Aging factor

DEC Descripcion HMISystem Frequency X

Frequency Decay Rate

System line-to-line voltage XVolts-per-hertz Line-to-neutral voltage magnitude XLine-to-neutral voltage angle

DEC Descripcion HMIWinding 1 real power XWinding 1 reactive power Winding 1 apparent power Winding 1 power factor Winding 2 real power XWinding 2 reactive power Winding 2 apparent power Winding 2 power factor Winding 3 real power Winding 3 reactive power Winding 3 apparent power Winding 3 power factor

Winding 1 real powerWinding 1 reactive power Winding 1 apparent power

Winding 2 real power Winding 2 reactive power Winding 2 apparent power

Winding 3 real power Winding 3 reactive power Winding 3 apparent power

Energy clear date Energy clear time Winding 1 source watthours Winding 1 load watthours

Winding 1 source varhours Winding 1 load varhours Winding 2 source watthours Winding 2 load watthours Winding 2 source varhours Winding 2 load varhours Winding 3 source watthours Winding 3 load watthours Winding 3 source varhours Winding 3 load varhours

DEC Descripcion HMIDemand data last clear date (2 registers) Demand data last clear time (2 registers) Winding 1 phase A current demand XWinding 1 phase B current demand XWinding 1 phase C current demand XWinding 1 maximum current demand XWinding 1 maximum current demand phase XWinding 1 maximum current demand date (2 registers) XWinding 1 maximum current demand time (2 registers) XWinding 2 phase A current demand XWinding 2 phase B current demand XWinding 2 phase C current demand XWinding 2 maximum current demand XWinding 2 maximum current demand phase XWinding 2 maximum current demand date (2 registers) XWinding 2 maximum current demand time (2 registers) XWinding 3 phase A current demand Winding 3 phase B current demand Winding 3 phase C current demand Winding 3 maximum current demand Winding 3 maximum current demand phase Winding 3 maximum current demand date (2 registers) Winding 3 maximum current demand time (2 registers)

DEC Descripcion HMI

DEC Descripcion HMIEstatus del Relé XEstatus de Sistema XCondiciones XEstatus de la Operación XEstatus de la Entrada Lógica XEstatus del Relé de Salida X

Tap changer position

Last clear date (2 registers) Last clear time (2 registers) Total number of events since last clear Event selector index (XX) [read/write]

Event XX date of event (2 registers) Event XX time of event (2 registers) Event XX cause of event Event XX winding 1 phase A current magnitude Event XX winding 1 phase A current angle Event XX winding 1 phase B current magnitude Event XX winding 1 phase B current angle Event XX winding 1 phase C current magnitude Event XX winding 1 phase C current angle Event XX winding 1 ground current magnitude Event XX winding 1 ground current angle Event XX winding 1 phase A 2nd harmonic Event XX winding 1 phase B 2nd harmonic Event XX winding 1 phase C 2nd harmonic

Event XX winding 1 phase A 5th harmonic Event XX winding 1 phase B 5th harmonic Event XX winding 1 phase C 5th harmonic Event XX winding 2 phase A current magnitude Event XX winding 2 phase A current angle Event XX winding 2 phase B current magnitude Event XX winding 2 phase B current angle Event XX winding 2 phase C current magnitude Event XX winding 2 phase C current angle Event XX winding 2 ground current magnitude Event XX winding 2 ground current angle Event XX winding 2 phase A 2nd harmonic Event XX winding 2 phase B 2nd harmonic Event XX winding 2 phase C 2nd harmonic Event XX winding 2 phase A 5th harmonic Event XX winding 2 phase B 5th harmonic Event XX winding 2 phase C 5th harmonic Event XX winding 3 phase A current magnitude Event XX winding 3 phase A current angle Event XX winding 3 phase B current magnitude Event XX winding 3 phase B current angle Event XX winding 3 phase C current magnitude Event XX winding 3 phase C current angle Event XX winding 3 ground current magnitude Event XX winding 3 ground current angle Event XX winding 3 phase A 2nd harmonic Event XX winding 3 phase B 2nd harmonic Event XX winding 3 phase C 2nd harmonic Event XX winding 3 phase A 5th harmonic Event XX winding 3 phase B 5th harmonic Event XX winding 3 phase C 5th harmonic Event XX phase A differential current Event XX phase B differential current Event XX phase C differential current Event XX phase A restraint current Event XX phase B restraint current Event XX phase C restraint current Event XX system frequency Event XX frequency decay rate Event XX tap changer position Event XX volts-per-hertz Event XX ambient temperature Event XX analog input

Command operation code

F20 F35 F21 F22 F23 F24

F6: Two’s-complement signed value, 2 decimal places (16 bits)

DescriptionRelay in serviceOne or more self-test errorsTest mode enabledDifferential blockedNot usedNot usedLocal mode on

One or more active diagnostic messages

DescriptionTransformer de-energizedTransformer overloadLoad limit reducedNot usedSetpoint group 1 activeSetpoint group 2 activeSetpoint group 3 activeSetpoint group 4 active

First block of eight bits (0000 0000 ---- ---- ---- ---- ----- ----): hours, 0 to 23 in steps of 1Second block of eight bits (---- ---- 0000 0000 ---- ---- ---- ----): minutes, 0 to 59 in steps of

Third and fourth block of four bits(---- ---- ---- ---- 0000 0000 0000 0000): seconds in format SS.SSSS (0 to 59999 in steps of 1). For example, 2.220 seconds stored as 2220.Note: if the time has never been set, then all bits will be set to 1.

First block of eight bits (0000 0000 ---- ---- ---- ---- ----- ----): month, 0 to 12 in steps of 1Second block of eight bits (---- ---- 0000 0000 ---- ---- ---- ----): day, 0 to 31 in steps of 1Third and fourth block of four bits(---- ---- ---- ---- 0000 0000 0000 0000): year, 1990 to

Note: if the date has never been set, then all bits will be set to 1.

First block of four bits (0000 ---- ---- ----): type of event, enumerated as follows:

Event typeNoneOffOnPickupOperateDropoutError

Second block of twelve bits (---- 0000 0000 0000): cause of event, enumerated as follows:

Cause of eventNo eventPercent differentialnstantaneous differential

Winding 1 phase time overcurrentWinding 2 phase time overcurrentWinding 3 phase time overcurrentWinding 1 phase instantaneous overcurrent 1Winding 2 phase instantaneous overcurrent 1Winding 3 phase instantaneous overcurrent 1Winding 1 phase instantaneous overcurrent 2Winding 2 phase instantaneous overcurrent 2Winding 3 phase instantaneous overcurrent 2Winding 1 neutral time overcurrentWinding 2 neutral time overcurrentWinding 3 neutral time overcurrentWinding 1 neutral instantaneous overcurrent 1Winding 2 neutral instantaneous overcurrent 1Winding 3 neutral instantaneous overcurrent 1Winding 1 neutral instantaneous overcurrent 2Winding 2 neutral instantaneous overcurrent 2Winding 3 neutral instantaneous overcurrent 2Winding 1 ground time overcurrentWinding 2 ground time overcurrentWinding 3 ground time overcurrentWinding 1 ground instantaneous overcurrent 1Winding 2 ground instantaneous overcurrent 1Winding 3 ground instantaneous overcurrent 1Winding 1 ground instantaneous overcurrent 2Winding 2 ground instantaneous overcurrent 2Winding 3 ground instantaneous overcurrent 2Winding 1 restricted ground faultWinding 2 restricted ground faultWinding 3 restricted ground faultWinding 1 restricted ground trendWinding 2 restricted ground trendWinding 3 restricted ground trendWinding 1 negative-sequence time overcurrentWinding 2 negative-sequence time overcurrentWinding 3 negative-sequence time overcurrentWinding 1 negative-sequence instantaneous overcurrentWinding 2 negative-sequence instantaneous overcurrentWinding 3 negative-sequence instantaneous overcurrentUnderfrequency 1Underfrequency 2Frequency decay 1Frequency decay 2Frequency decay 3Frequency decay 4

OverfrequencyFifth harmonic levelVolts per hertz 1Volts per hertz 2Winding 1 THD levelWinding 2 THD levelWinding 3 THD levelWinding 1 harmonic deratingWinding 2 harmonic deratingWinding 3 harmonic deratingHottest-spot limitLoss-of-life limitAnalog input level 1Analog input level 2Winding 1 current demandWinding 2 current demandWinding 3 current demandTransformer overloadLogic input 1Logic input 2Logic input 3Logic input 4Logic input 5Logic input 6Logic input 7Logic input 8Logic input 9Logic input 10Logic input 11Logic input 12Logic input 13Logic input 14Logic input 15Logic input 16 Virtual input 1 Virtual input 2 Virtual input 3 Virtual input 4 Virtual input 5 Virtual input 6 Virtual input 7 Virtual input 8 Virtual input 9 Virtual input 10 Virtual input 11

Virtual input 12 Virtual input 13 Virtual input 14 Virtual input 15 Virtual input 16 Output relay 1 Output relay 2 Output relay 3 Output relay 4 Output relay 5 Output relay 6 Output relay 7 Output relay 8 Self-test relay Virtual output 1 Virtual output 2 Virtual output 3 Virtual output 4 Virtual output 5 Setpoint group 1 Setpoint group 2 Setpoint group 3 Setpoint group 4 Test mode Simulation disabled Simulation prefault Simulation fault Simulation playback Logic input reset Front panel reset Communications port reset Manual trace trigger Automatic trace trigger Control power Logic input power Analog output powerUnit not calibratedEEPROM memoryReal time clockNot usedEmulation softwareInternal temperatureFlexLogic™ equationDSP processorBad transformer settings

IRIG-B signalSetpoint access deniedAging factor limitAmbient temperatureTap changer failure

Example: 302Ah = 12230 decimal = 0011 0000 0010 1010 = Underfrequency 1 pickup, since 0011 (first four bits) indicates a pickup event and 0000 0010 1010 (next 12 bits)

F25: Two’s-complement signed value, 3 decimal places (16 bits)

DescriptionActive trip condition xActive alarm condition(s) xPickup condition xPhase A fault xPhase B fault xPhase C fault xGround fault x

Statusxxxxxxxx

Code programming mode disabledCode programming mode enabled

Setpoint access jumper disabledSetpoint access jumper enabled

Factory service mode disabledFactory service mode enabled

Communication port passcode access is read and writeCommunication port passcode access is read only

Output stateOutput relay 1 (0 = de-energized, 1 = energized) x

Output relay 2 (0 = de-energized, 1 = energized) xOutput relay 3 (0 = de-energized, 1 = energized) xOutput relay 4 (0 = de-energized, 1 = energized) xOutput relay 5 (0 = de-energized, 1 = energized) xOutput relay 6 (0 = de-energized, 1 = energized) xOutput relay 7 (0 = de-energized, 1 = energized) xOutput relay 8 (0 = de-energized, 1 = energized) xSelf-test relay (0 = de-energized, 1 = energized) x

LED stateLED #1 on (top)LED #2 onLED #3 onLED #4 onLED #5 onLED #6 onLED #7 onLED #8 on (bottom)

F78: Unsigned value, auto-ranging based onwinding 1 phase CT primary value (16 bits)For winding 1 phase CT primary ≤2 A, F78 is an unsigned value with three decimal places.

For 2 A <winding 1 phase CT primary ≤20 A, F78 is an unsigned value with two decimal

For 20 A <winding 1 phase CT primary ≤200 A, F78 is an unsigned value with one decimal

For 200 A < winding 1 phase CT primary ≤2000 A, F78 is a standard unsigned value. For

For winding 1 phase CT primary >2000 A, F78 is a standard unsigned value scaled by 10.











F81: Unsigned value, auto-ranging based on winding 1 ground CT primary (16 bits)For winding 1 ground CT primary ≤2 A, F81 is an unsigned value with three decimal places.

For 2 A <winding 1 ground CT primary ≤20 A, F81 is an unsigned value with two decimal

For 20 A <winding 1 ground CT primary ≤200 A, F81 is an unsigned value with one decimal

For winding 1 ground CT primary >200 A, F81 is a standard unsigned value. For example,









F93: Two’s-complement, signed value, auto-ranging based on winding 1 phase CT

Example

3 decimal places 1.234 stored as 12342 decimal places 12.34 stored as 12341 decimal place 123.4 stored as 1234Standard signed value 1234 stored as 12345 decimal places 0.01234 stored as 12344 decimal places 0.1234 stored as 12343 decimal place 1.234 stored as 12342 decimal place 12.34 stored as 1234


Example

3 decimal places 1.234 stored as 1234 2 decimal places 12.34 stored as 1234 1 decimal place 123.4 stored as 1234 Standard signed value 1234 stored as 1234 5 decimal places 0.01234 stored as 1234 4 decimal places 0.1234 stored as 1234 3 decimal place 1.234 stored as 1234 2 decimal place 12.34 stored as 1234


Example

3 decimal places 1.234 stored as 12342 decimal places 12.34 stored as 12341 decimal place 123.4 stored as 1234Standard signed value 1234 stored as 12345 decimal places 0.01234 stored as 12344 decimal places 0.1234 stored as 12343 decimal place 1.234 stored as 12342 decimal place 12.34 stored as 1234

Signed Value stored with:



F96: Unsigned value, auto-ranging based on winding 1 phase CT primary (32 bits)For winding 1 phase CT primary ≤2 A, format F96 is an unsigned value with three decimal

For 2 A <winding 1 phase CT primary ≤20 A, format F96 is an unsigned value with two

For 20 A <winding 1 phase CT primary ≤200 A, format F96 is an unsigned value with one

For 200 A <winding 1 phase CT primary ≤2000 A, format F96 is a standard unsigned value.

For winding 1 phase CT primary >2000 A, format F96 is an unsigned value scaled by 10.











IEEE 754 single precision binary floating-point format: binary32.The first modbus address contains the sign bit, exponent, and 7 most significant bits of the fraction. The second modbus address contains the 16 least significant bits of the fraction.Reference: http://ieeexplore.ieee.org/xpl/freeabs_all.jsp?arnumber=4610935

x

xxxxxxxxxxxxxxx

SR-745: 1601-0070-B1-S(GEK-106592)

Min Max Paso Unidad Codigo Formato--- --- --- A F78 0 359 --- ° Lag F1 --- --- --- A F78 0 359 1 ° Lag F1 --- --- A F78 0 359 1 ° Lag F1 --- --- --- A F78 0 359 1 ° Lag F1 --- --- --- A F81 0 359 1 ° Lag F1 0 999 1 % rated F1 --- --- --- A F78

--- --- --- A F79 0 359 --- ° Lag F1 --- --- --- A F79 0 359 1 ° Lag F1 --- --- A F79 0 359 1 ° Lag F1 --- --- --- A F79 0 359 1 ° Lag F1 --- --- --- A F82

0 359 1 ° Lag F1 0 999 1 % rated F1 --- --- --- A F79

--- --- --- A F80 0 359 --- ° Lag F1 --- --- --- A F80 0 359 1 ° Lag F1 --- --- A F80 0 359 1 ° Lag F1 --- --- --- A F80 0 359 1 ° Lag F1 --- --- --- A F83 0 359 1 ° Lag F1 0 999 1 % rated F1 --- --- --- A F80

--- --- --- A F780 359 --- ° Lag F1 --- --- --- A F790 359 --- ° Lag F1 --- --- --- A F800 359 --- ° Lag F1 --- --- --- A F780 359 --- ° Lag F1 --- --- --- A F790 359 --- ° Lag F1 --- --- --- A F80 0 359 --- ° Lag F1 --- --- --- A F78 0 359 --- ° Lag F1 --- --- --- A F79 0 359 --- ° Lag F1 --- --- --- A F80 0 359 --- ° Lag F1

0.00 655.35 0.01 x CT F3 0 359 1 ° Lag F1

0.00 655.35 0.01 x CT F3 0 359 1 ° Lag F1

0.00 655.35 0.01 x CT F3 0 359 1 ° Lag F1

0.00 655.35 0.01 x CT F30.00 655.35 0.01 x CT F3

0.00 655.35 0.01 x CT F3

0.000 65,535 0.001 x CT F530.000 65,535 0.001 x CT F530.000 65,535 0.001 x CT F53

0.0 99.9 0.1 % ƒo F20.0 99.9 0.1 % ƒo F20.0 99.9 0.1 % ƒo F20.0 99.9 0.1 % ƒo F20.0 99.9 0.1 % ƒo F20.0 99.9 0.1 % ƒo F20.0 99.9 0.1 % ƒo F20.0 99.9 0.1 % ƒo F20.0 99.9 0.1 % ƒo F2

Min Max Paso Unidad Codigo Formato-51 251 1 °C F4

–50 300 1 °C F4 0 200000 1 hours F7

0.0 2000.0 0.1 - F2

Min Max Paso Unidad Codigo Formato0.00 99.99 0.01 Hz F3

-9,99 9.99 0.01 Hz/s F6

0.00 600.00 0.01 kV F3 0.00 4.00 0.01 V/Hz F3 0.00 600.00 0.01 kV F3

0 359 1 ° Lag F1

Min Max Paso Unidad Codigo Formato–32000 32000 --- MW F93 –32000 32000 --- Mvar F93

0 32000 --- MVA F93 –1.00 1.00 0.01 --- F6

–32000 32000 --- MW F94 –32000 32000 --- Mvar F94

0 32000 --- MVA F94 –1.00 1.00 0.01 --- F6

–32000 32000 --- MW F95 –32000 32000 --- Mvar F95

0 32000 --- MVA F95 –1.00 1.00 0.01 --- F6

.00001 32000 --- MW F156

.00001 32000 --- Mvar F156

.00001 32000 --- MVA F156

.00001 32000 --- MW F156

.00001 32000 --- Mvar F156

.00001 32000 --- MVA F156

.00001 32000 --- MW F156

.00001 32000 --- Mvar F156

.00001 32000 --- MVA F156

--- --- --- --- F23 --- --- --- --- F22 --- --- --- MWh F96 --- --- --- MWh F96

--- --- --- Mvarh F96 --- --- --- Mvarh F96 --- --- --- MWh F97 --- --- --- MWh F97 --- --- --- Mvarh F97 --- --- --- Mvarh F97 --- --- --- MWh F98 --- --- --- MWh F98 --- --- --- Mvarh F98 --- --- --- Mvarh F98

Min Max Paso Unidad Codigo Formato--- --- --- F23 --- --- --- F22 --- --- A F78 --- --- A F78 --- --- A F78 --- --- A F78 --- --- --- F18 --- --- --- F23 --- --- --- F22 --- --- A F79 --- --- A F79 --- --- A F79 --- --- A F79 --- --- --- F18 --- --- --- F23 --- --- --- F22 --- --- A F80 --- --- A F80 --- --- A F80 --- --- A F80 --- --- --- F18 --- --- --- F23 --- --- --- F22

Min Max Paso Unidad Codigo Formato

Min Max Paso Unidad Codigo Formato--- --- --- F20 --- --- --- F21 --- --- --- F35 --- --- --- F44 --- --- --- F49 --- --- --- F50

1 50 1 --- F1

--- --- --- --- F23 --- --- --- --- F22 0 65535 1 --- F1 1 65535 1 --- F1

--- --- --- --- F23 --- --- --- --- F22 --- --- --- --- F24 --- --- --- A F78 0 359 --- ° Lag F1

--- --- --- A F78 0 359 1 ° Lag F1

--- --- --- A F78 0 359 1 ° Lag F1

--- --- --- A F81 0 359 1 ° Lag F1

0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2

0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 --- --- --- A F79 0 359 1 ° Lag F1

--- --- --- A F79 0 359 1 ° Lag F1

--- --- --- A F79 0 359 1 ° Lag F1

--- --- --- A F82 0 359 1 ° Lag F1

0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 --- --- --- A F80 0 359 1 ° Lag F1

--- --- --- A F80 0 359 1 ° Lag F1

--- --- --- A F80 0 359 1 ° Lag F1

--- --- --- A F83 0.0 99.9 1 ° Lag F1 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2 0.0 99.9 0.1 % ƒo F2

0.00 655.35 0.01 ×CT F3 0.00 655.35 0.01 ×CT F3 0.00 655.35 0.01 ×CT F3 0.00 655.35 0.01 ×CT F3 0.00 655.35 0.01 ×CT F3 0.00 655.35 0.01 ×CT F3 0.0 99.9 0.01 Hz F3

-9.99 9.99 0.01 Hz/s F6 1 50 1 --- F1

0.00 4.00 0.01 V/Hz F3 -51 251 1 °C F4 0 65000 1 Units> F1

--- --- --- --- F19

F44 F50 F78 F80 F93 F156F49 F53 F79 F81 F94

F82 F95 F83 F96

F97 F98


1Corriente

Dir.Modbus HEX DEC3 02FF

0300 0301 0302 0303 0304

030C

030F

2Temperatura

Dir.Modbus HEX DEC







3Voltaje

Dir.Modbus HEX DEC5 02FE

0305 0306 0307 0308 0309 030A

3 030B

030D 030E

FREQUENCY AND THREE-PHASE POWER2 03102 03112 0312

03130314

1 03151 0316

SYNCHRONIZING VOLTAGE0318 0319 031A 031B 031C 031D




· Frecuencia

4Potencia

ENERGY USE Dir.Modbus HEX DEC2 0320

03222 0324

03262 03282 032A

032CSINGLE-PHASE POWER

1 03601 03611 03621 03631 03641 03651 03661 03671 03681 03691 036A1 036B

5Demanda

Dir.Modbus HEX DECLAST DEMAND 0330

03310332

2 03332 03342 0335

03400341

· Factor potencia









0343034503460348034A034B034D

2 034F03500352

2 035403550357

2 0359035A035C035E

6Fasores

Dir.Modbus HEX DECCURRENT PHASE ANGLE

040004010402040304040405

3 0406

VOLTAGE PHASE ANGLES 041004110412041304140415

5 0416

SYMMETRICAL COMPONENTS0420042104220423


042404250426042704280429042A042B

7Estado

Dir.Modbus HEX DECSYSTEM STATUS 0200

02010202020302040205020602070209020B020C020D020E020F

LAST TRIP DATA02E0 02E2 02E4 02E5 02E6 02E7 02E8 02E9 02EA 02EB






02EC 02ED 02EE

3 02EF5 02F0

ANALOG INPUT037003710372

Codigos de Formato

F1 F21 F30 F3 F22 F5 F23 F6 F24 F7

F1 Unsigned Value (16 bits)Example: 1234 stored as 1234

F3 Unsigned Value, 2 Decimal Places (16 bits)Example: 12.34 stored as 1234

F5 2's Complement Signed, 1 Decimal Place (16 bits)Example: -123.4 stored as -1234

F6 2's Complement Signed, 2 Decimal Places (16 bits)Example: -12.34 stored as -1234

F7

Unsigned Long Value (32 bits)

High order word of long value stored in 1st 16 bits; low order word of long value stored in 2nd 16 bitsExample: 123456 stored as 123456

F21

General Status0001h Relay In Service (0 = Not In Svc, 1 = In Svc)0002h Trip (0 = No Active Trips, 1 = Active Trip)0004h Alarm (0 = No Active Alarms, 1 = Active Alrm)0008h Pickup (0 = No Protection, 1 = Protection)0010h Setpoint Group 1 (0 = Disabled, 1 = Enabled)0020h Setpoint Group 2 (0 = Disabled, 1 = Enabled)0040h Setpoint Group 3 (0 = Disabled, 1 = Enabled)0080h Setpoint Group 4 (0 = Disabled, 1 = Enabled)0100h Breaker Open (0 = Closed, 1 = Open)0200h Breaker Closed (0 = Open, 1 = Closed)0400h Reclosure (0=Disabled, 1=Enabled), 760 only0800h Reclosure (0=Enabled, 1=Disabled), 760 only1000h Reclosure In Progress (0 = Not In Progress, 1 = In Progress) – 760 only!

F21

2000h Reclosure Lockout (0 = Not In Lockout , 1 = In Lockout) – 760 only!4000h Local Mode (0 = Enabled, 1 = Disabled)8000h Message (0 = No Diagnostic Message,1 = Diagnostic Messages)

F22

Time (32 bits)Hours / Minutes (HH:MM:xx.xxx) 1st 16 bits

FF00h Hours (0= 12am, 1=1am,..., 23=11pm)00FFh Minutes (0 to 59 in steps of 1)

Seconds (xx:xx:SS.SSS) (2nd 16 bits)FFFFh (0 = 00.000 s, 1=00.001 s, 59999=59.999 s)

NOTE: If the time has never been set then all 32 bits will be 1.

F23

Date (32 bits)Month / Day (MM/DD/xxxx) (2nd 16 bits)

FF00h Month (1 = January,..., 12 = December)00FFh Day (1 to 31 in steps of 1)

Year (xx/xx/YYYY) (2nd 16 bits)FFFFh 2000 to 2097 in steps of 1

NOTE: If the date has never been set then all 32 bits will be 1.

F24

Event TypeF000h Event Type (first 4 bits)

1 General2 Pickup3 Trip4 Alarm5 Control6 Logic Input7 Self-Test Warning8 Dropout

10 Maintenance AlertThe format for the rest of the register depends on Event TypeGeneral Event Type00FFh Event Cause (last 8 bits)

1 Control Power Off2 Control Power On3 Breaker Opened4 Breaker Closed5 Breaker Not Connected6 Reset7 Open Breaker8 Close Breaker9 Set Time

10 Set Date11 Trigger Trace Memory12 Clear Energy Use13 Clear Max Demand14 Clear Event Recorder

F24

15 Reset Trip Counter16 Reset Arcing Current17 Reserved18 Trigger Data Logger20 Transfer Initiated21 Transfer Not Ready22 Close From Transfer23 Trip From Transfer24 Transfer Ready30 Reclosure 1 760 only!31 Reclosure 2 760 only!32 Reclosure 3 760 only!33 Reclosure 4 760 only!34 Reclosure Lockout 760 only!35 Shots Reduced to 3 760 only!36 Shots Reduced to 2 760 only!37 Shots Reduced to 1 760 only!38 Shots Reduced to L/O 760 only!39 Autoreclose Reset 760 only!40 Setpoint Group 1 Active41 Setpoint Group 2 Active42 Setpoint Group 3 Active43 Setpoint Group 4 Active44 Reset AR Count 760 only!45 Reset AR Shot Rate 760 only!

Pickup / Trip / Alarm Latched Alarm / Control / Dropout Event TypesFF00h Phases (first 8 bits)0100h Phase A (0 = No Fault , 1 = Fault)0200h Phase B (0 = No Fault , 1 = Fault)0400h Phase C (0 = No Fault , 1 = Fault)00FFh CAUSE OF EVENT (last 8 bits)

2 1 Phase Time Overcurrent 12 2 Phase Instantaneous Overcurrent 12 3 Phase Instantaneous Overcurrent 22 4 Ground Time Overcurrent2 5 Ground Instantaneous Overcurrent2 6 Neutral Time OC 12 7 Neutral Time OC 22 8 Neutral Instantaneous Overcurrent 12 9 Neutral Instantaneous Overcurrent 22 10 Phase Directional is Reverse2 11 Neutral Directional is Reverse2 12 Manual Close Feature Blocking

13 Cold Load Pickup Feature Blocking14 Bus Undervoltage 1

F24

15 Bus Undervoltage 217 Line Undervoltage 418 Overvoltage 119 Overvoltage 220 Underfrequency 121 Underfrequency 222 Phase Current Level

1 23 Neutral Current Level24 Power Factor 1 25 Power Factor 2 26 Out Of Synchronization27 Current Demand28 Real Power Demand 29 Reactive Power Demand 30 Apparent Power Demand31 Analog Input Threshold 132 Analog Input Threshold 2 33 Analog Input Rate of Change 134 Analog Input Rate of Change 235 Overfrequency36 Trip Counter 37 Arcing Current38 VT Failure39 Breaker Failure40 Breaker Operation41 Trip Coil Monitor42 Close Coil Monitor43 User Input A44 User Input B45 User Input C46 User Input D47 User Input E48 User Input F49 User Input G50 User Input H51 Negative Sequence Instantaneous Overcurrent52 Negative Sequence Time Overcurrent53 Negative Sequence Overvoltage54 Undervoltage Restoration55 Underfrequency Restoration56 Phase Time Overcurrent 2

1 57 Frequency Decay1 58 Negative Sequence is Reverse3 59 Sensitive Ground Instantaneous OC3 60 Sensitive Ground Time Overcurrent

3

F24

61 Sensitive Ground Direction is Reverse4 62 Reverse Power (requires Mod 008)4 63 Neutral Displacement4 64 Positive Watthours Pulse Output 4 65 Negative Watthours Pulse Output 4 66 Positive Varhours Pulse Output 4 67 Negative Varhours Pulse Output 5 68 Ground Directional is Reverse 6 69 Reserved for Mod 0107 70 User Input I 7 71 User Input J 7 72 User Input K 7 73 User Input L 7 74 User Input M 7 75 User Input N 7 76 User Input O 7 77 User Input P 7 78 User Input Q 7 79 User Input R 7 80 User Input S 7 81 User Input T 7 82 Autoreclose Rate 760 ONLY!7 83 Restricted Earth Fault

Logic Input Event TypeFF00h States (first 8 bits)0100h Contact State (0 = Open, 1 = Closed)0200h Virtual State (0 = Off, 1 = On)0400h Logic Input (0 = Not Asserted, 1 = Asserted)00FFh Input Function (last 8 bits)

1 52a Contact2 52b Contac3 Breaker Connected

10 Local Mode11 Remote Reset12 Remote Open13 Remote Close14 Cold Load Pickup15 Setpoint Group 216 Setpoint Group 317 Setpoint Group 420 User Input A21 User Input B22 User Input C23 User Input D24 User Input E

F24

25 User Input F26 User Input G27 User Input H30 Block 1 TRIP31 Block 2 CLOSE32 Block Reset33 Block Undervolt 134 Block Undervolt 235 Block Undervolt 336 Block Undervolt 437 Block Underfreq 138 Block Underfreq 239 Bypass Synchrocheck40 Block Trip Count41 Block Negative Sequence Overvoltage42 Block Restoration

1 43 Block Freq Decay50 Block All Overcurrent51 Block Phase Overcurrent52 Block Ground Overcurrent53 Block Neutral Overcurrent

2 54 Block Phase Time Overcurrent 12 55 Block Phase Instantaneous Overcurrent 12 56 Block Phase Instantaneous Overcurrent 22 57 Block Ground Time Overcurrent2 58 Block Ground Instantaneous Overcurrent2 59 Block Neutral Time Overcurrent 22 60 Block Neutral Time Overcurrent 12 61 Block Neutral Instantaneous Overcurrent 12 62 Block Neutral Instantaneous Overcurrent 2

63 Block Negative Sequence Instantaneous Overcurrent64 Block Negative Sequence Time Overcurrent

1 65 Block Phase Time Overcurrent 270 Selected To Trip71 Undervoltage On Other Source72 ncomer 1 Closed73 ncomer 2 Closed74 BusTie Connected75 Bus Tie Closed76 Block Transfer77 Transformer Lockout78 Source Trip79 Close From Incomer 1 80 Close From Incomer 290 nitiate Reclosure

F24

91 Cancel Reclosure92 Block Reclosure

100 Trigger Trace Memory101 Simulate Fault102 Trigger Data Log

3 103 Block All Sensitive Ground Overcurrent3 104 Block Sensitive Ground Instantaneous OC3 105 Block Sensitive Ground Time Overcurrent4 106 Block Reverse Power (requires Mod 008)4 107 Block Neutral Displacement7 108 User Input I7 109 User Input J7 110 User Input K7 111 User Input L7 112 User Input M7 113 User Input N7 114 User Input O7 115 User Input P7 116 User Input Q7 117 User Input R7 120 Start Demand Interval

Self-Test Warning Event Type00FFh Event Cause (last 8 bits)

1 Relay Not Ready2 Analog Output +32V3 FLASH Corrupt4 EEPROM Corrupt5 Dry Contact +32V6 A/D Virtual Ground7 Internal RS4858 Internal Temperature9 Clock Not Set

10 Prototype Software11 Not Calibrated12 Force Relays13 Force Analog Out14 Simulation Mode15 Pickup Test16 Factory Service Mode17 IRIG-B Failure18 Not Used19 Not Used20 RTC Crystal

Maintenance Alert Event Type00FFh Event Cause (last 8 bits)

F24

1 Event Rate High2 EEPROM Usage High

F30Enabled/Disabled

0 0 = Disabled1 1 = Enabled

F40

Output Relay Status0001h Relay 1 Trip (0 = not operated, 1 = operated)0002h Relay 2 Close (0 = not operated, 1 = operated)0004h Relay 3 Alarm (0 = not operated, 1 = operated)0008h Relay 4 Aux (0 = not operated, 1 = operated)0010h Relay 5 Aux (0 = not operated, 1 = operated)0020h Relay 6 Aux (0 = not operated, 1 = operated)0040h Relay 7 Aux (0 = not operated, 1 = operated)0080h Relay 8 Self-test (0 = not operated, 1 = operated)

F44

Out Of Service States0001h Major Internal Failure (0=disabled, 1=enabled)0002h Minor Internal Failure (0=disabled, 1=enabled)0004h Testing Mode (0=Disabled, 1=Enabled)0020h Code Programming Mode (0=Disabled, 1=Enabled)

F46

Contact Input Status0001h Contact Input 1 State (0=Open, 1=Closed)0002h Contact Input 2 State (0=Open, 1=Closed)0004h Contact Input 3 State (0=Open, 1=Closed)0008h Contact Input 4 State (0=Open, 1=Closed)0010h Contact Input 5 State (0=Open, 1=Closed)0020h Contact Input 6 State (0=Open, 1=Closed)0040h Contact Input 7 State (0=Open, 1=Closed)0080h Contact Input 8 State (0=Open, 1=Closed)0100h Contact Input 9 State (0=Open, 1=Closed)0200h Contact Input 10 State (0=Open, 1=Closed)0400h Contact Input 11 State (0=Open, 1=Closed)0800h Contact Input 12 State (0=Open, 1=Closed)1000h Contact Input 13 State (0=Open, 1=Closed)2000h Contact Input 14 State (0=Open, 1=Closed)4000h Setpoint Access (0=Restricted, 1=Allowed)

F47Trip/Close Coil Status

0001h Coil Monitor 1 Circuit (0=Open, 1=Closed)0002h Coil Monitor 2 Circuit (0=Open, 1=Closed)

F79

Setpoint Group0 Group 11 Group 22 Group 33 Group 4

F86

Auto-Ranging Power / EnergyAll power quantities auto-range to display units relative to the nominal power of the system as defined

F86

below. Multiply the power quantity in question by the multiplier in register 0316h to yield the correct reading. The SI prefix for all power and energy quantities before scaling by the multiplier is ‘k’. All power quantities are signed, single word registers (F4).All energy quantities are unsigned, double word registers (F7).The multiplier is determined from the nominal power which is defined as the product of three setpoints: PN= Phase CT Primary x Bus VT Secondary Voltage x Bus VT Ratio

NOMINAL POWER PN MULTIPLIERPN< 1 MVA 11 MVA ≤PN< 10 MVA 1010 MVA ≤PN 100

Example: If the 3φReal Power register (0310) has a value of ‘123’ and the Multiplier register (0316) has a value of ‘10’ then the value to display is 1230 kW.

Descripcion HMI MinSensitive Ground Current X 0.00 Phase A RMS Current X 0Phase B RMS Current X 0Phase C RMS Current X 0Percent of Load-to-Trip 0Ground Current X 0

Average Current X 0

Neutral Current X 0

Descripcion HMI Min

Descripcion HMI MinNeutral Voltage X 0.00

A-N RMS Voltage X 0.00 B-N RMS Voltage X 0.00 C-N RMS Voltage X 0.00 A-B RMS Voltage X 0.00 B-C RMS Voltage X 0.00 C-A RMS Voltage X 0.00 Reserved for Polarizing Current ---

Average Line Voltage X 0.00 Average Phase Voltage X 0.00

Three-Phase Real Power X –30000Three-Phase Reactive Power –30000Three-Phase Apparent Power 0Three-Phase Power Factor X –0.99System Frequency X 0.00 System Frequency Decay Rate –10.00 Auto Ranging Power / Energy Multiplier 1

Synchronizing RMS Voltage 0.00 Synchronizing RMS Voltage Frequency 0.00 Synchronizing Voltage Difference 0.00 Synchronizing Phase Difference 0Synchronizing Frequency Difference 0.00 Synchronizing Voltage Angle 0

Descripcion HMI MinPositive Watthours (2 words) 0Positive Watthour Cost (2 words) 0Negative Watthours (2 words) 0Negative Watthour Cost (2 words) 0Positive Varhours (2 words) 0Negative Varhours (2 words) 0Energy Use Data Last Reset (2 words) 0

Phase A Real Power X –30000 Phase A Reactive Power –30000 Phase A Apparent Power 0Phase A Power Factor –0.99Phase B Real Power X –30000 Phase B Reactive Power –30000 Phase B Apparent Power 0Phase B Power Factor –0.99Phase C Real Power X –30000 Phase C Reactive Power –30000 Phase C Apparent Power 0Phase C Power Factor –0.99

Descripcion HMI MinLast Phase A Current Demand 0Last Phase B Current Demand 0Last Phase C Current Demand 0Last Real Power Demand –30000Last Reactive Power Demand –30000Last Apparent Power Demand 0

Maximum Phase A Current Demand X 0Maximum Phase A Current Date (2 words) ---

Maximum Phase A Current Time (2 words) --- Maximum Phase B Current Demand X 0Maximum Phase B Current Date (2 words) --- Maximum Phase B Current Time (2 words) --- Maximum Phase C Current Demand X 0Maximum Phase C Current Date (2 words) --- Maximum Phase C Current Time (2 words) --- Maximum Real Power Demand X 0Maximum Real Power Date (2 words) --- Maximum Real Power Time (2 words) --- Maximum Reactive Power Demand 0Maximum Reactive Power Date (2 words) --- Maximum Reactive Power Time (2 words) --- Maximum Apparent Power Demand 0Maximum Apparent Power Date (2 words) --- Maximum Apparent Power Time (2 words) --- Demand Data Last Reset (2 words) ---

Descripcion HMI Min

Phase A Current Angle 0Phase B Current Angle 0Phase C Current Angle 0Neutral Current Angle 0Ground Current Angle 0ReservedSensitive Ground Current Angle 0

Phase A-N Voltage Angle 0Phase B-N Voltage Angle 0Phase C-N Voltage Angle 0Phase A-B Voltage Angle 0Phase B-C Voltage Angle 0Phase C-A Voltage Angle 0Neutral Voltage Angle 0

Positive Sequence Current Magnitude 0Positive Sequence Current Angle 0Negative Sequence Current Magnitude 0Negative Sequence Current Angle 0

Zero Sequence Current Magnitude 0Zero Sequence Current Angle 0Positive Sequence Voltage Magnitude 0.00Positive Sequence Voltage Angle 0Negative Sequence Voltage Magnitude 0.00Negative Sequence Voltage Angle 0Zero Sequence Voltage Magnitude 0.00Zero Sequence Voltage Angle 0

Descripcion HMI MinGeneral Status X ---760 Operation Status X ---Communications Port Setpoint Access Status X ---Reserved ---Contact Input Status X ---Coil Monitor Status X ---Output Relay Status X ---Date (2 words) ---Time (2 words) ---Active Setpoint Group ---Edit Setpoint Group ---Major Failure Code ---Diagnostic Code ---Diagnostic Code ---

Date of Last Trip (2 words) --- Time of Last Trip (2 words) --- Cause of Last Trip X --- Last Trip Phase A Current 0Last Trip Phase B Current 0Last Trip Phase C Current 0Last Trip Ground Current 0Last Trip A-N (A-B) Voltage 0.00 Last Trip B-N (B-C) Voltage 0.00 Last Trip C-N (C-A) Voltage 0.00

Last Trip System Frequency 0.00Last Trip Analog Input 0Last Trip Neutral Current 0Last Trip Sensitive Ground Current 0.00 Last Trip Neutral Voltage 0.00

Analog Input X 0Analog Input Fast Rate of Change --- Analog Input Slow Rate of Change ---

F40 F79 F44 F46 F47

Unsigned Value (16 bits)Example: 1234 stored as 1234Unsigned Value, 2 Decimal Places (16 bits)Example: 12.34 stored as 12342's Complement Signed, 1 Decimal Place (16 bits)Example: -123.4 stored as -12342's Complement Signed, 2 Decimal Places (16 bits)Example: -12.34 stored as -1234Unsigned Long Value (32 bits)

High order word of long value stored in 1st 16 bits; low order word of long value stored in 2nd 16 bitsExample: 123456 stored as 123456General Status

Relay In Service (0 = Not In Svc, 1 = In Svc) xTrip (0 = No Active Trips, 1 = Active Trip) xAlarm (0 = No Active Alarms, 1 = Active Alrm) xPickup (0 = No Protection, 1 = Protection) xSetpoint Group 1 (0 = Disabled, 1 = Enabled) xSetpoint Group 2 (0 = Disabled, 1 = Enabled) xSetpoint Group 3 (0 = Disabled, 1 = Enabled) xSetpoint Group 4 (0 = Disabled, 1 = Enabled) xBreaker Open (0 = Closed, 1 = Open) xBreaker Closed (0 = Open, 1 = Closed) xReclosure (0=Disabled, 1=Enabled), 760 only xReclosure (0=Enabled, 1=Disabled), 760 only xReclosure In Progress (0 = Not In Progress, 1 = In Progress) – 760 only! x

Reclosure Lockout (0 = Not In Lockout , 1 = In Lockout) – 760 only! xLocal Mode (0 = Enabled, 1 = Disabled) xMessage (0 = No Diagnostic Message,1 = Diagnostic Messages) x

Time (32 bits)Hours / Minutes (HH:MM:xx.xxx) 1st 16 bits

Hours (0= 12am, 1=1am,..., 23=11pm)Minutes (0 to 59 in steps of 1)

Seconds (xx:xx:SS.SSS) (2nd 16 bits) (0 = 00.000 s, 1=00.001 s, 59999=59.999 s)

NOTE: If the time has never been set then all 32 bits will be 1.Date (32 bits)Month / Day (MM/DD/xxxx) (2nd 16 bits)

Month (1 = January,..., 12 = December)Day (1 to 31 in steps of 1)

Year (xx/xx/YYYY) (2nd 16 bits)2000 to 2097 in steps of 1

NOTE: If the date has never been set then all 32 bits will be 1.Event Type

Event Type (first 4 bits)GeneralPickupTripAlarmControlLogic InputSelf-Test WarningDropoutMaintenance Alert

The format for the rest of the register depends on Event TypeGeneral Event Type

Event Cause (last 8 bits)Control Power OffControl Power OnBreaker OpenedBreaker ClosedBreaker Not ConnectedResetOpen BreakerClose BreakerSet TimeSet DateTrigger Trace MemoryClear Energy UseClear Max DemandClear Event Recorder

Reset Trip CounterReset Arcing CurrentReservedTrigger Data LoggerTransfer InitiatedTransfer Not ReadyClose From TransferTrip From TransferTransfer ReadyReclosure 1 760 only!Reclosure 2 760 only!Reclosure 3 760 only!Reclosure 4 760 only!Reclosure Lockout 760 only!Shots Reduced to 3 760 only!Shots Reduced to 2 760 only!Shots Reduced to 1 760 only!Shots Reduced to L/O 760 only!Autoreclose Reset 760 only!Setpoint Group 1 ActiveSetpoint Group 2 ActiveSetpoint Group 3 ActiveSetpoint Group 4 ActiveReset AR Count 760 only!Reset AR Shot Rate 760 only!

Pickup / Trip / Alarm Latched Alarm / Control / Dropout Event TypesPhases (first 8 bits)Phase A (0 = No Fault , 1 = Fault)Phase B (0 = No Fault , 1 = Fault)Phase C (0 = No Fault , 1 = Fault)CAUSE OF EVENT (last 8 bits)Phase Time Overcurrent 1Phase Instantaneous Overcurrent 1Phase Instantaneous Overcurrent 2Ground Time OvercurrentGround Instantaneous OvercurrentNeutral Time OC 1Neutral Time OC 2Neutral Instantaneous Overcurrent 1Neutral Instantaneous Overcurrent 2Phase Directional is ReverseNeutral Directional is ReverseManual Close Feature BlockingCold Load Pickup Feature BlockingBus Undervoltage 1

Bus Undervoltage 2Line Undervoltage 4Overvoltage 1Overvoltage 2Underfrequency 1Underfrequency 2Phase Current LevelNeutral Current LevelPower Factor 1 Power Factor 2 Out Of SynchronizationCurrent DemandReal Power Demand Reactive Power Demand Apparent Power DemandAnalog Input Threshold 1Analog Input Threshold 2 Analog Input Rate of Change 1Analog Input Rate of Change 2OverfrequencyTrip Counter Arcing CurrentVT FailureBreaker FailureBreaker OperationTrip Coil MonitorClose Coil MonitorUser Input AUser Input BUser Input CUser Input DUser Input EUser Input FUser Input GUser Input HNegative Sequence Instantaneous OvercurrentNegative Sequence Time OvercurrentNegative Sequence OvervoltageUndervoltage RestorationUnderfrequency RestorationPhase Time Overcurrent 2Frequency DecayNegative Sequence is ReverseSensitive Ground Instantaneous OCSensitive Ground Time Overcurrent

Sensitive Ground Direction is ReverseReverse Power (requires Mod 008)Neutral DisplacementPositive Watthours Pulse Output Negative Watthours Pulse Output Positive Varhours Pulse Output Negative Varhours Pulse Output Ground Directional is Reverse Reserved for Mod 010User Input I User Input J User Input K User Input L User Input M User Input N User Input O User Input P User Input Q User Input R User Input S User Input T Autoreclose Rate 760 ONLY!Restricted Earth Fault

Logic Input Event TypeStates (first 8 bits)Contact State (0 = Open, 1 = Closed)Virtual State (0 = Off, 1 = On)Logic Input (0 = Not Asserted, 1 = Asserted)Input Function (last 8 bits)52a Contact52b ContacBreaker ConnectedLocal ModeRemote ResetRemote OpenRemote CloseCold Load PickupSetpoint Group 2Setpoint Group 3Setpoint Group 4User Input AUser Input BUser Input CUser Input DUser Input E

User Input FUser Input GUser Input HBlock 1 TRIPBlock 2 CLOSEBlock ResetBlock Undervolt 1Block Undervolt 2Block Undervolt 3Block Undervolt 4Block Underfreq 1Block Underfreq 2Bypass SynchrocheckBlock Trip CountBlock Negative Sequence OvervoltageBlock RestorationBlock Freq DecayBlock All OvercurrentBlock Phase OvercurrentBlock Ground OvercurrentBlock Neutral OvercurrentBlock Phase Time Overcurrent 1Block Phase Instantaneous Overcurrent 1Block Phase Instantaneous Overcurrent 2Block Ground Time OvercurrentBlock Ground Instantaneous OvercurrentBlock Neutral Time Overcurrent 2Block Neutral Time Overcurrent 1Block Neutral Instantaneous Overcurrent 1Block Neutral Instantaneous Overcurrent 2Block Negative Sequence Instantaneous OvercurrentBlock Negative Sequence Time OvercurrentBlock Phase Time Overcurrent 2Selected To TripUndervoltage On Other Sourcencomer 1 Closedncomer 2 ClosedBusTie ConnectedBus Tie ClosedBlock TransferTransformer LockoutSource TripClose From Incomer 1 Close From Incomer 2nitiate Reclosure

Cancel ReclosureBlock ReclosureTrigger Trace MemorySimulate FaultTrigger Data LogBlock All Sensitive Ground OvercurrentBlock Sensitive Ground Instantaneous OCBlock Sensitive Ground Time OvercurrentBlock Reverse Power (requires Mod 008)Block Neutral DisplacementUser Input IUser Input JUser Input KUser Input LUser Input MUser Input NUser Input OUser Input PUser Input QUser Input RStart Demand Interval

Self-Test Warning Event TypeEvent Cause (last 8 bits)Relay Not ReadyAnalog Output +32VFLASH CorruptEEPROM CorruptDry Contact +32VA/D Virtual GroundInternal RS485Internal TemperatureClock Not SetPrototype SoftwareNot CalibratedForce RelaysForce Analog OutSimulation ModePickup TestFactory Service ModeIRIG-B FailureNot UsedNot UsedRTC Crystal

Maintenance Alert Event TypeEvent Cause (last 8 bits)

Event Rate HighEEPROM Usage High

Enabled/Disabled

Output Relay StatusRelay 1 Trip (0 = not operated, 1 = operated) xRelay 2 Close (0 = not operated, 1 = operated) xRelay 3 Alarm (0 = not operated, 1 = operated) xRelay 4 Aux (0 = not operated, 1 = operated) xRelay 5 Aux (0 = not operated, 1 = operated) xRelay 6 Aux (0 = not operated, 1 = operated) xRelay 7 Aux (0 = not operated, 1 = operated) xRelay 8 Self-test (0 = not operated, 1 = operated) x

Out Of Service StatesMajor Internal Failure (0=disabled, 1=enabled) xMinor Internal Failure (0=disabled, 1=enabled) xTesting Mode (0=Disabled, 1=Enabled) xCode Programming Mode (0=Disabled, 1=Enabled) x

Contact Input StatusContact Input 1 State (0=Open, 1=Closed) xContact Input 2 State (0=Open, 1=Closed) xContact Input 3 State (0=Open, 1=Closed) xContact Input 4 State (0=Open, 1=Closed) xContact Input 5 State (0=Open, 1=Closed) xContact Input 6 State (0=Open, 1=Closed) xContact Input 7 State (0=Open, 1=Closed) xContact Input 8 State (0=Open, 1=Closed) xContact Input 9 State (0=Open, 1=Closed) xContact Input 10 State (0=Open, 1=Closed) xContact Input 11 State (0=Open, 1=Closed) xContact Input 12 State (0=Open, 1=Closed) xContact Input 13 State (0=Open, 1=Closed) xContact Input 14 State (0=Open, 1=Closed) xSetpoint Access (0=Restricted, 1=Allowed) x

Trip/Close Coil StatusCoil Monitor 1 Circuit (0=Open, 1=Closed)Coil Monitor 2 Circuit (0=Open, 1=Closed)

Setpoint GroupGroup 1Group 2Group 3Group 4

All power quantities auto-range to display units relative to the nominal power of the system as defined

below. Multiply the power quantity in question by the multiplier in register 0316h to yield the correct reading. The SI prefix for all power and energy quantities before scaling by the multiplier is ‘k’. All power quantities are signed, single word registers (F4).All energy quantities are unsigned, double word registers (F7).The multiplier is determined from the nominal power which is defined as the product of three setpoints: PN= Phase CT Primary x Bus VT Secondary Voltage x Bus VT Ratio

Example: If the 3φReal Power register (0310) has a value of ‘123’ and the Multiplier register (0316) has a value of ‘10’ then the value to display is 1230 kW.

Max Unidad Codigo Formato655.35 A F3 65535 A F1 65535 A F1 65535 A F12000 % F1

65535 A F1

65535 A F1

65535 A F1

Max Unidad Codigo Formato

Max Unidad Codigo Formato655.35 kV F3

655.35 kV F3 655.35 kV F3 655.35 kV F3 655.35 kV F3 655.35 kV F3 655.35 kV F3

--- --- ---

655.35 kV F3 655.35 kV F3

30000 kW F86 30000 kvar F86 30000 kVA F86 +1.00 --- F6 65.00 Hz F3 10.00 Hz/s F6 100 --- F1

655.35 kV F3 65.00 Hz F3 655.35 kV F3

359 ° F1 65.00 Hz F3

359 ° Lag F1

Max Unidad Codigo Formato4.00E+09 kWh F86 4.00E+09 $ F7 4.00E+09 kWh F86 4.00E+09 $ F7 4.00E+09 kvarh F86 4.00E+09 kvarh F86 4.00E+09 --- F23

30000 kW F86 30000 kvar F86 30000 kVA F86 +1.00 --- F6 30000 kW F86 30000 kvar F86 30000 kVA F86 +1.00 --- F6 30000 kW F86 30000 kvar F86 30000 kVA F86 +1.00 --- F6

Max Unidad Codigo Formato65535 A F1 65535 A F1 65535 A F1 30000 kW F86 30000 kvar F86 30000 kVA F86

65535 A F1 --- --- F23

--- --- F22 65535 A F1

--- --- F23 --- --- F22

65535 A F1 --- --- F23 --- --- F22

30000 kW F86 --- --- F23 --- --- F22

30000 kvar F86 --- --- F23 --- --- F22

30000 kVA F86 --- --- F23 --- --- F22 --- --- F23

Max Unidad Codigo Formato

359 ° Lag F1 359 ° Lag F1 359 ° Lag F1 359 ° Lag F1 359 ° Lag F1

--- --- 359 ° Lag F1

359 ° Lag F1 359 ° Lag F1 359 ° Lag F1 359 ° Lag F1 359 ° Lag F1 359 ° Lag F1 359 ° Lag F1

65535 A F1 359 ° Lag F1

65535 A F1 359 ° Lag F1

65535 A F1 359 ° Lag F1

600.00 kV F3 359 ° Lag F1

600.00 kV F3 359 ° Lag F1

600.00 kV F3 359 ° Lag F1

Max Unidad Codigo Formato--- --- F21 --- --- F44 --- --- F30 --- ------ --- F46 --- --- F47 --- --- F40 --- --- F23 --- --- F22 --- --- F79 --- --- F79 --- --- F24 --- --- F1 --- --- F1

--- --- F23 --- --- F22 --- --- F24

65535 A F1 65535 A F1 65535 A F1 65535 A F1

655.35 kV F3 655.35 kV F3 655.35 kV F3

65.00 Hz F3 65535 units F1 65535 A F1

655.35 A F3 655.35 kV F3

65535 Units F1 Units / min. F5 Units / hr. F5

F86

MultiLins GeneralElectric

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