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Toshiba GRL150-100 Series, Instruction Manual

The Toshiba GRL150-100 Series is a cutting-edge product that revolutionizes user experience. To fully explore its features and unleash its true potential, an Instruction Manual is vital. Download our comprehensive manual for free from manualshive.com to ensure seamless understanding and optimize your product experience.

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6  F  2  S  0  8  2  

DIFI1 setting and Full-scale 

GRL150 transmits current data to the remote terminal after the CT matching. The current data is 
normalized by the DIFI1 setting value. Therfore, the full-scale of the current data is expressed by 
the following equation depending on the DIFI1 setting. 

I

FS

 = DIFI1 

×

 32 (A) 

where, I

FS

: Full-scale of current data 

When setting DIFI1, it must be ensured that I

FS

 is greater than the maximum fault current. 

Setting of DIFI1 

The setting of DIFI1 is determined considering the minimum internal fault current for which the 
relay should operate and the maximum erroneous differential current (mainly the internal charging 
current) during normal service conditions for which the relay should not operate. 

DIFI1 should therefore be set to satisfy the following equation: 

 

K

Ic 

<

 DIFI1 

<

 If / K 

where, 

 

K: 

Setting margin (K = 1.2 to 1.5) 

 

Ic: 

Internal charging current 

 

If: 

Minimum internal fault current 

Setting of DIFI2 

The setting of DIFI2 is determined from the following three criteria: 

  Maximum erroneous current generated by CT saturation in case of an external fault  

  Maximum load current 

  Maximum outflow current in case of an internal fault 

In the case of the first criterion, DIFI2 should be set as small as possible so that unwanted 
operation is not caused by the maximum erroneous current generated by CT saturation during 
heavy through current for an external fault. It is recommended normally to set DIFI2 to 2

×

In (In: 

secondary rated current) for this criterion. 

For the second criterion, DIFI2 should be set large enough such that it does not encroach on load 
current. 

For the third criterion, the maximum outflow current must be considered. DIFI2 should be set 
larger than the largest possible value of outflow current in the case of an internal fault. 

In two terminal network, the maximum outflow current is the maximum load current. 

Setting of DIFSV 

When using the differential current monitoring function, the setting of DIFSV is determined from 
the maximum erroneous differential current during normal service conditions. 

 

K

Ierr 

<

 DIFSV 

<

 DIFI1 / (1.5 to 2) 

Ierr: maximum erroneous differential current 

Setting of [SP.SYN] 

One terminal must be set to "Master" and the other terminal to "Slave". 

Summary of Contents for GRL150-100 Series

Page 1: ...6 F 2 S 0 8 2 8 INSTRUCTION MANUAL LINE DIFFERENTIAL RELAY GRL150 TOSHIBA Corporation 2005 All Rights Reserved Ver 0 9 ...

Page 2: ... be followed by important safety information that must be carefully reviewed Indicates an imminently hazardous situation which will result in death or serious injury if you do not follow the instructions Indicates a potentially hazardous situation which could result in death or serious injury if you do not follow the instructions CAUTION Indicates a potentially hazardous situation which if not avo...

Page 3: ... of ambient temperature humidity and dust detailed in the specification and in an environment free of abnormal vibration Ratings Before applying AC current or the DC power supply to the equipment check that they conform to the equipment ratings Printed circuit board Do not attach and remove printed circuit boards when the DC power to the equipment is on as this may cause the equipment to malfuncti...

Page 4: ...anner according to local regulations 环保使用期限标识是根据 电子信息产品污染控制管理办法 以及 电子信息产品污染控制标识要求 SJ T11364 2006 电子信息产品环保使用期限通则 制定的 适用于中国境内销售的电子信息产品的标识 只要按照安全及使用说明内容在正常使用电子信息产品情况下 从生产日期算起 在此期限内产品中含有的有毒 有害物质不致发生外泄或突变 不致对环境造成严重污染或对其人身 财产造成严重损害 产品正常使用后 要废弃在环保使用年限内或者刚到年限的产品 请根据国家标准采取适当的方法进行处置 另外 此期限不同于质量 功能的保证期限 The Mark and Information are applicable for People s Republic of China only ...

Page 5: ...ault Overcurrent Protection 20 2 3 1 Inverse Time IDMT Operation 20 2 3 2 Scheme Logic 23 2 3 3 Setting 25 2 4 Earth Fault Protection 28 2 4 1 Scheme Logic 28 2 4 2 Setting 29 2 5 Sensitive Earth Fault Protection 31 2 5 1 Scheme Logic 31 2 5 2 Setting 33 2 6 Phase Undercurrent Protection 34 2 6 1 Scheme Logic 34 2 6 2 Setting 35 2 7 Thermal Overload Protection 36 2 7 1 Scheme Logic 37 2 7 2 Settin...

Page 6: ...62 3 3 8 Failure Alarms 62 3 3 9 Trip Blocking 65 3 3 10 Setting 65 3 4 Recording Function 66 3 4 1 Fault Recording 66 3 4 2 Event Recording 67 3 4 3 Disturbance Recording 67 3 5 Metering Function 69 4 User Interface 70 4 1 Outline of User Interface 70 4 1 1 Front Panel 70 4 1 2 Communication Ports 72 4 2 Operation of the User Interface 74 4 2 1 LCD and LED Displays 74 4 2 2 Relay Menu 78 4 2 3 Di...

Page 7: ...Input Circuit 129 6 4 3 Binary Output Circuit 130 6 4 4 AC Input Circuits 131 6 5 Function Test 132 6 5 1 Measuring Element 132 6 5 2 Protection Scheme 140 6 5 3 Metering and Recording 140 6 6 Conjunctive Tests 141 6 6 1 On Load Test 141 6 6 2 Communication Circuit Test 141 6 6 3 Tripping Circuit Test 142 6 7 Maintenance 144 6 7 1 Regular Testing 144 6 7 2 Failure Tracing and Repair 144 6 7 3 Repl...

Page 8: ...95 Appendix F Typical External Connection 199 Appendix G Relay Setting Sheet 203 Appendix H Commissioning Test Sheet sample 223 Appendix I Return Repair Form 227 Appendix J Technical Data 231 Appendix K Symbols Used in Scheme Logic 237 Appendix L Inverse Time Characteristics 241 Appendix M IEC60870 5 103 Interoperability 247 Appendix N Resistor Box Option 259 Appendix N Ordering 263 The data given...

Page 9: ...continuous monitoring of internal circuits and of software External circuits are also monitored by trip circuit supervision CT supervision and CB condition monitoring features A user friendly HMI is provided through a backlit LCD programmable LEDs keypad and menu based operating system PC access is also provided either for local connection via a front mounted RS232 port or for remote connection vi...

Page 10: ... 9 Thermal Overload THM 49 9 9 9 9 9 9 Phase Undercurrent UC 37P 9 9 9 9 9 9 Broken Conductor BCD BC 9 9 9 9 9 9 Circuit Breaker Fail CBF 50BF 9 9 9 9 9 9 Cold Load Protection 9 9 9 9 9 9 Trip circuit supervision 9 9 9 9 9 9 Self supervision 9 9 9 9 9 9 CB State Monitoring 9 9 9 9 9 9 Trip Counter Alarm 9 9 9 9 9 9 Iy Alarm 9 9 9 9 9 9 CB Operate Time Alarm 9 9 9 9 9 9 Metering 9 9 9 9 9 9 Fault r...

Page 11: ...fferential Protection GRL150 is applied as a segregated phase current differential protection for use with pilot wire or direct fibre optic communication as shown in Figure 2 2 1 For pilot wire communication GRL150 can be applied to circuits up to 8 km in length for 0 91mmφ and provides built in 5kV and optional 20kV isolation For direct fibre optic communication GRL150 can be applied to circuits ...

Page 12: ...cheme logic of the segregated phase current differential protection Output signals of differential elements DIF A B and C perform instantaneous three phase tripping See Figure 2 12 1 The output signals of DIF A B and C are blocked when a communication circuit failure is detected by the data error check sampling synchronism check or interruption of the received signals For DIF A_FS B_FS and C_FS si...

Page 13: ...nt This characteristic has weaker restraint and ensures sensitivity to low level faults Characteristic B is expressed by the following equation Id Ir 2 DIFI2 where DIFI2 is a setting and its physical meaning is described later This characteristic has stronger restraint and prevents the element from operating falsely in response to the erroneous differential current which is caused by saturation or...

Page 14: ...can be set OCD is a phase current change detection element and its sensitivity is fixed The scheme logic is shown in Figure 2 2 3 1 The output of DIFFS_OP is connected to DIF A_FS DIF B_FS DIF C_FS respectively by PLC function The fail safe function is disabled by the DIF FS switch By DIF FS OC5 or OCD or both elements can be selected If the switch is set to OFF the signal of DIFFS_OP is 1 and the...

Page 15: ...that the remote terminal is out of service Figure 2 2 4 1 shows the remote terminal out of service detection logic The local terminal can detect that the remote terminal is out of service if it receives no interlink signal I LINK R1 from the remote terminal The interlink signal is configured from the circuit breaker CB and disconnector DS status signal shown in Figure 2 2 4 2 Each terminal detects...

Page 16: ...re transmitted to monitor the communication channel If a communication failure is detected at the local terminal the output of differential protection is blocked A synchronized test trigger signal is used to test the differential protection simultaneously at all terminals For details see Section 4 2 7 4 User programmable commands Any signals On off data shown in Appendix B can be assigned to COM1 ...

Page 17: ...t as the master terminal The other terminal is set as the slave terminal The scheme switch SP SYN is used for the settings Note The master and slave terminals are set only for the convenience of the sampling timing synchronization The GRL150s at both terminals perform identical protection functions and operate simultaneously Timing synchronization is performed using the receiving time for a data f...

Page 18: ...communication signals in a multi core pilot wire cable the optional G1RE1 resistor box is available for reducing the transmission level Refer to Appendix N 2 2 8 Telecommunication Channel Monitoring If a failure occurs or noise causes a disturbance in the telecommunication channel they may interrupt the data transmission or generate erroneous data thus causing the relay to operate incorrectly The ...

Page 19: ...ith relation to the primary current in the same manner of the DIFI1 setting CT ratio 2000 1A Terminal A Terminal B GRL150 GRL150 DIFI1 800A CT ratio 2000 1A 0 4A CT ratio 4000 1A DIFI1 800A CT ratio 4000 1A 0 2A Primary sensitivity 800A Figure 2 2 9 1 Example of CT Ratio Matching If the CT secondary ratings at the local and remote terminals are different relay model suitable for the CT secondary r...

Page 20: ...a Maximum erroneous current generated by CT saturation in case of an external fault Maximum load current Maximum outflow current in case of an internal fault In the case of the first criterion DIFI2 should be set as small as possible so that unwanted operation is not caused by the maximum erroneous current generated by CT saturation during heavy through current for an external fault It is recommen...

Page 21: ...ent schemes 2 3 1 Inverse Time IDMT Operation The overcurrent protection element OC1 has the IDMT characteristics defined by equation 1 c Is I k TMS t a 1 where t operating time for constant current I seconds I energising current amps Is overcurrent setting amps TMS time multiplier setting k a c constants defining curve Nine curve types are available as defined in Table 2 3 1 1 They are illustrate...

Page 22: ...es Time Multiplier 1 0 1 1 10 100 1000 1 10 100 Current Multiple of Setting Operating Time s LTI NI VI EI IEEE US Inverse Curves Time Multiplier 1 0 1 1 10 100 1 10 100 Current Multiple of Setting Operating Time s MI VI CO2 CO8 EI Figure 2 3 1 1 IDMT Characteristics Programmable Reset Characteristics OC1 has a programmable reset feature instantaneous definite time delayed or dependent time delayed...

Page 23: ...tripping then resetting is delayed for a user definable period When the energising current falls below the reset threshold the integral state the point towards operation that it has travelled of the timing function IDMT is held for that period This does not apply following a trip operation in which case resetting is always instantaneous Dependent time reset The dependent time resetting characteris...

Page 24: ...OC1C according to the required IDMT characteristic and trip signal OC1 TRIP is given Figure 2 3 2 3 to Figure 2 3 2 4 show the scheme logic of the definite time phase overcurrent protection OC2 to OC4 The OC2 to OC4 give trip and alarm signals OC2 TRIP OC3 TRIP and OC4 ALARM through the delayed pick up timers TOC2 to TOC4 respectively The signal OC1 INST to OC4 INST are available to trip instantan...

Page 25: ... Phase Fault Overcurrent Protection TOC2 t 0 t 0 0 00 300 00s t 0 1 1 1 1 ON OC2 EN OC2 A OC2 B OC2 C OC2_INST_TP 1621 OC2_BLOCK 1557 1 OC2_TRIP 277 279 278 276 84 86 85 OC_IC_BLK 1683 1 OC ICD BLK 373 ICD By PLC Figure 2 3 2 2 OC2 Phase Fault Overcurrent Protection TOC3 t 0 t 0 0 00 300 00s t 0 1 1 1 1 ON OC3 EN OC3 A OC3 B OC3 C OC3_INST_TP 1622 OC3_BLOCK 1558 1 OC3_TRIP 281 283 282 280 88 90 89...

Page 26: ...te time delayed reset Required if OC1R DEF TOC1RM RTMS 0 010 1 500 0 001 1 000 OC1 dependent time delayed reset time multiplier Required if OC1R DEP OC2 0 1 25 0 A 0 02 5 00 A 0 1 A 0 01 A 5 0 A 1 00 A OC2 threshold setting TOC2 0 00 300 00 s 0 01 s 1 00 s OC2 definite time setting OC3 0 1 250 0 A 0 02 50 00 A 0 1 A 0 01 A 50 0 A 10 00 A OC3 threshold setting TOC3 0 00 300 0 s 0 01 s 1 00 s OC3 de...

Page 27: ...rmed to provide selectivity in relation with the relays on the adjacent lines Suppose a minimum source impedance when the current flowing in the relay becomes the maximum In Figure 2 3 3 1 in the event of a fault at near end F2 of the adjacent line the operating time is set so that terminal A may operate by time grading Tc behind terminal B The current flowing in the relays may sometimes be greate...

Page 28: ...ll terminals but graded settings are better than identical settings in order to provide a margin for current sensitivity The further from the power source the terminal is located the higher sensitivity i e the lower setting is required The operating time of the overcurrent element of each terminal is constant irrespective of the magnitude of the fault current and selective protection is implemente...

Page 29: ...EC IEEE US or CON and then setting MEF1C according to the required IDMT characteristic and the trip signal EF1 TRIP is given Figure 2 4 1 2 to Figure 2 4 1 4 show the scheme logic of the definite time earth fault protection EF2 to EF4 The EF2 to EF4 give trip and alarm signals EF2 TRIP EF3 TRIP and EF4 ALARM through the delayed pick up timers TEF2 TEF3 and TEF4 respectively The signal EF1 INST to ...

Page 30: ...5 EF2_INST_TP 1627 EF2_BLOCK 1563 ON EF4 EN OC_IC_BLK 1683 1 OC ICD BLK 373 ICD By PLC Figure 2 4 1 4 EF4 Earth Fault Protection 2 4 2 Setting The table shows the setting elements necessary for the earth fault protection and their setting ranges Element Range Step Default Remarks EF1 0 1 25 0 A 0 02 5 00 A 0 1 A 0 01 A 1 5 A 0 30 A EF1 threshold setting TEF1 0 00 300 00 s 0 01 s 1 00 s EF1 definit...

Page 31: ...A 50 0 A 10 00 A EF4 threshold setting TEF4 0 00 300 00 s 0 01 s 1 00 s EF4 definite time setting EF1EN Off On On EF1 Enable MEF1 DT IEC IEEE US CON DT EF1 time characteristic MEF1C MEF1C IEC MEF1C IEEE MEF1C US NI VI EI LTI MI VI EI CO2 CO8 NI MI CO2 EF1 inverse curve type Required if MEF1 IEC Required if MEF1 IEEE Required if MEF1 US EF1R DEF DEP DEF EF1 reset characteristic Required if MEF1 IEE...

Page 32: ...ault current for SEF may be fed from a core balance CT but if it is derived from three phase CTs the erroneous current may be caused also by the CT error in phase faults Transient false functioning may be prevented by a relatively long time delay 2 5 1 Scheme Logic Figure 2 5 1 1 to 2 5 1 4 show the scheme logic of sensitive earth fault protection Figure 2 5 1 1 shows the scheme logic of sensitive...

Page 33: ...TSE2 t 0 117 302 SEF2_INST_TP 1629 SEF2_BLOCK 1565 ON SE2 EN OC_IC_BLK 1683 1 OC ICD BLK 373 ICD By PLC Figure 2 5 1 2 SEF2 Sensitive Earth Fault Protection SEF3 1 SEF3_TRIP 1 0 00 300 00s TSE3 t 0 118 303 SEF3_INST_TP 1630 SEF3_BLOCK 1566 ON SE3 EN OC_IC_BLK 1683 1 OC ICD BLK 373 ICD By PLC Figure 2 5 1 3 SEF3 Sensitive Earth Fault Protection SEF4 1 SEF4_ALARM 1 0 00 300 00s TSE4 t 0 119 304 SEF4...

Page 34: ...10 A SEF2 threshold setting TSE2 0 00 300 00 s 0 01 s 1 00 s SEF2 definite time setting SE3 0 025 0 125 A 0 005 0 025 A 0 001 A 0 001 A 0 050 A 0 010 A SEF3 threshold setting TSE3 0 00 300 00 s 0 01 s 1 00 s SEF3 definite time setting SE4 0 025 0 125 A 0 005 0 025 A 0 001 A 0 001 A 0 050 A 0 010 A SEF4 threshold setting TSE4 0 00 300 00 s 0 01 s 1 00 s SEF4 definite time setting SE1EN Off On Off S...

Page 35: ...ws the undercurrent element characteristic Figure 2 6 1 1 Undercurrent Element Characteristic Each phase has two independent undercurrent elements for tripping and alarming The elements are programmable for instantaneous or definite time delayed operation The undercurrent element operates on per phase basis although tripping and alarming is three phase only 2 6 1 Scheme Logic Figure 2 6 1 2 shows ...

Page 36: ... PLC Figure 2 6 1 2 Undercurrent Protection Scheme Logic 2 6 2 Setting The table below shows the setting elements necessary for the undercurrent protection and their setting ranges Element Range Step Default Remarks UC1 0 5 10 0 A 0 10 2 00 A 0 1 A 0 01 A 1 0 A 0 20 A UC1 threshold setting TUC1 0 00 300 00 s 0 01 s 1 00 s UC1 definite time setting UC2 0 5 10 0 A 0 10 2 00 A 0 1 A 0 01 A 2 0 A 0 40...

Page 37: ...d state and 100 represents the thermal limit which is the point at which no further temperature rise can be safely tolerated and the system should be disconnected The thermal limit for any given system is fixed by the thermal setting IAOL The relay gives a trip output when θ 100 The thermal overload protection measures the largest of the three phase currents and operates according to the character...

Page 38: ...e of IAOL Operate Time minutes Thermal Curves Hot Curve 90 prior load 0 001 0 01 0 1 1 10 100 1000 1 10 Overload Current Multiple of IAOL Operate Time minutes Figure 2 7 1 1 Thermal Curves 2 7 1 Scheme Logic Figure 2 7 1 2 shows the scheme logic of the thermal overload protection The thermal overload element THM has independent thresholds for alarm and trip and outputs alarm signal THM ALARM and t...

Page 39: ...g THM IAOL allowable overload current THMIP 0 0 5 0 A 0 00 1 00 A 0 1 A 0 01 A 0 0 A 0 00 A Previous load current TTHM 0 5 300 0 min 0 1 min 10 0 min Thermal time constant THMA 50 99 1 80 Thermal alarm setting Percentage of THM setting THMT Off On Off Thermal OL enable THMAL Off On Off Thermal alarm enable THMRST Off On Off Thermal element test Current values shown in the parenthesis are in the ca...

Page 40: ...f the left and right side system of the fault location is in the ratio of k1 to 1 k1 k2 to 1 k2 and k0 to 1 k0 Figure 2 8 1 1 Equivalent Circuit for a Single phase Series Fault Positive phase sequence current I1F negative phase sequence current I2F and zero phase sequence current I0F at fault location in an single phase series fault are given by Positive phase sequence Single phase series fault Ze...

Page 41: ...r source voltages behind both ends Broken conductor protection element BCD detects series faults by measuring the ratio of negative to positive phase sequence currents I2F I1F This ratio is given with negative and zero sequence impedance of the system I2F I1F I2F I1F Z0 Z2 Z0 The ratio is higher than 0 5 in a system when the zero sequence impedance is larger than the negative sequence impedance It...

Page 42: ... Default Remarks BCD 0 10 1 00 0 01 0 20 I2 I1 TBCD 0 00 300 00s 0 01s 0 00 s BCD definite time setting BCDEN Off On Off BCD Enable Minimum setting of the BC threshold is restricted by the negative phase sequence current normally present on the system The ratio I2 I1 of the system is measured in the relay continuously and displayed on the metering screen of the relay front panel along with the max...

Page 43: ...is Figure 2 9 1 1 shows the scheme logic for the BFP The BFP is started by the PLC logic per phase base signals CBF_INIT A to CBF_INIT C or three phase base signal CBF_INIT The BFP can be disabled by the PLC logic signal CBF_BLOCK These signals must continuously exist as long as the fault is present The BFP can be disabled by the PLC logic signal CBF_BLOCK The back tripping signal to the upstream ...

Page 44: ...CBF_INIT 1599 CBF_BLOCK 1570 124 125 126 1 CBF_TRIP 333 334 335 332 1 CBF_RETRIP 329 330 331 328 1 By PLC 348 GEN TRIP Figure 2 9 1 1 Breaker Failure Protection Scheme Logic Fault CBF TRIP TBTC CBF RETRIP TRTC OCBF Original breakers Adjacent breakers TRIP Retrip Toc Toc Tcb Tcb TRTC TBTC Normal trip Open Closed Start CBFP Open Open Closed Trip Figure 2 9 1 2 Sequence Diagram ...

Page 45: ...llowed to respond to load current it can be set to 10 to 200 of the rated current The settings of TRTC and TBTC are determined by the opening time of the original circuit breaker Tcb in Figure 2 9 1 2 and the reset time of the overcurrent element Toc in Figure 2 9 1 2 The timer setting example when using retrip can be obtained as follows Setting of TRTC Breaker opening time CBF reset time Margin 4...

Page 46: ...t GRL150 GRL150 Transformer Figure 2 10 1 1 Protection with In zone Transformer The blocking can be enabled or disabled by setting the scheme switches DIF ICD and OC ICD The ICD detects the ratio ICD 2f between second harmonic current I2f and fundamental current I1f in each phase current and operates if its ratio is larger than the setting value Figure 2 10 1 2 shows the characteristic of the ICD ...

Page 47: ...ogic are shown in Figure 2 10 2 1 and Figure 2 10 2 2 for the cold load protection Note that the scheme requires the use of two binary inputs one each for CB OPEN and CB CLOSED Under normal conditions where the circuit breaker has been closed for some time the scheme is in STATE 0 and the normal default settings group is applied to the overcurrent protection If the circuit breaker opens then the s...

Page 48: ...ings ColdLoad Run TCLR timer Monitor CB status Monitor load current IL CB opens CB closes within TCLE time TCLE timer expires CB closes CB opens within CLR time TCLR timer expires IL ICLDO for TCLDO time Figure 2 10 2 1 State Transition Diagram for Cold Load Protection 1 1 Change to STATE 2 CB_OPEN 0 10000s TCLE t 0 Change to STATE 0 STATE 2 STATE 3 t 0 0 10000s 0 00 100 00s TCLDO TCLR t 0 Change ...

Page 49: ...0 A 0 1 A 0 01 A 100 0 A 20 00 A OC3 threshold setting OC4 0 1 250 0 A 0 02 50 00 A 0 1 A 0 01 A 200 0 A 40 00 A OC4 threshold setting OC5 0 1 250 0 A 0 02 50 00 A 0 1 A 0 01 A 20 0 A 4 00 A OC5 threshold setting EF1 0 1 25 0 A 0 02 5 00 A 0 01 A 0 01 A 10 0 A 2 00 A EF1 threshold setting EF2 0 1 25 0 A 0 02 5 00 A 0 01 A 0 01 A 25 0 A 5 00 A EF2 threshold setting EF3 0 1 250 0 A 0 02 50 00 A 0 1 ...

Page 50: ... driven When set to BO the binary output for tripping is not driven and only user configurable binary output is driven TR1_TRIP 340 TR1 R1 1648 1 TR1_BLOCK 1554 BO TTSW1 TRIP 341 INTER_TRIP1 TR2_TRIP 342 TR2 R1 1649 1 TR2_BLOCK 1555 BO TTSW1 TRIP 343 INTER_TRIP2 Figure 2 11 1 Transfer Trip Scheme Logic Setting The setting elements necessary for the transfer trip function and their setting ranges a...

Page 51: ...put relays TP1 and TP2 one auxiliary relay FAIL for relay fail output and five programmable auxiliary relays BO1 to BO5 BO1 to BO5 can be programmed by setting Refer to Section 3 2 3 DIF_TRIP TR1_TRIP TR2_TRIP OC1_TRIP OC2_TRIP OC3_TRIP EF1_TRIP EF2_TRIP EF3_TRIP SEF1_TRIP SEF2_TRIP SEF3_TRIP UC1_TRIP THM_TRIP BCD_TRIP OC4 ALARM EF4 ALARM SEF4 ALARM UC2 ALARM THM ALARM 1 GEN TRIP 1 1 1 GEN ALARM 1...

Page 52: ...C_ALARM EF4_ALARM SEF4_ALARM GEN _TRIP A 1 1 TP A_DELAY 1664 361 349 PLC 1 GEN _TRIP B 1 1 TP B_DELAY 1665 362 350 PLC 1 GEN _TRIP C 1 1 TP C_DELAY 1666 363 351 PLC 1 GEN _TRIP N 1 1 TP N_DELAY 1667 364 352 PLC 1 1 GEN ALARM A 354 1 GEN ALARM B 355 1 GEN ALARM C 356 1 GEN ALARM N 357 1 GEN TP A GEN TP B GEN TP C GEN TP N Reset time delay default setting 60ms Reset time delay default setting 60ms R...

Page 53: ...owing hardware modules These modules are fixed in a frame and cannot be taken off individually The human machine interface module is provided with the front panel Power module POWD Signal processing module SPMP Human machine interface module HMI The hardware block diagram of GRL150 is shown in Figure 3 1 1 2 IN SERVICE TRIP ALARM VIEW RESET END CEL CAN ENTER A B 0V Figure 3 1 1 1 Hardware Structur...

Page 54: ...currents and a residual current depending on the relay model This module incorporates max 4 auxiliary CTs DC DC converter and 8 photo coupler circuits for binary input signals The available input voltage ratings of the DC DC converter are 24V 48V 110V 125V or 220 250V The normal range of input voltage is 20 to 20 SPMP Module The SPMP module consists of analogue filter multiplexer analogue to digit...

Page 55: ...lows Label Color Remarks IN SERVICE Green Lit when the relay is in service and flickered when the relay is in Test menu TRIP Red Lit when a trip command is issued ALARM Red Lit when a failure is detected LED1 Yellow Configurable LED to assign signals with or without latch when relay operates LED2 Yellow Configurable LED to assign signals with or without latch when relay operates LED3 Yellow Config...

Page 56: ...l IN SERVICE TRIP ALARM VIEW RESET END CEL CAN ENTER A B 0V Liquid crystal display Light emitting diodes LED Operation keys RS232C connector Screw for cover Screw for cover Screw for handle To a local PC Monitoring Jacks Light emitting diodes LED ...

Page 57: ...ed contacts Where the driving contact meets the contact conditions then the BISNS can be set to Norm normal If not then Inv inverted should be selected The pick up and drop off delay times can be set 0 0 to 300 00s respectively Logic level inversion function and pick up and drop off delay timer settings are as follows Element Contents Range Step Default BI1SNS BI8SNS Binary switch Norm Inv Norm BI...

Page 58: ...ime of the tripping output relay following fault clearance can be programmed by PLC function The setting is respective for each output relay For example when the GEN TRIP signal of the protection is linked to the binary output auxiliary relay TP1 the PLC logic is assigned to the signal No 348 of GEN TRIP for PLC input and the signal No 2560 of TP1 for PLC output as shown in Figure 3 2 3 1 by the P...

Page 59: ...ous drop off Ins for delayed drop off Dl for dwell operation Dw or for latching operation Lat by the scheme switch RESET The time of the delayed drop off Dl or dwell operation Dw can be set by TBO When the relay is latched it can be reset with the RESET key on the relay front panel or a binary input This resetting resets all the output relays collectively Figure 3 2 3 2 Configurable Output The rel...

Page 60: ...nd linked to signals corresponding to relay elements or binary circuits Configurable binary inputs and binary outputs and the initiation trigger of fault record and disturbance record are programmed by the PLC function Temporary signals are provided for complicated logics or for using a user configured signal in many logic sequences PLC logic is assigned to protection signals by using the PLC tool...

Page 61: ...ircuit is checked CT circuit current monitoring Max Ia Ib Ic 4 Min Ia Ib Ic k0 where Max Ia Ib Ic Maximum amplitude among Ia Ib and Ic Min Ia Ib Ic Minimum amplitude among Ia Ib and Ic k0 20 of rated current The CT circuit current monitoring allows high sensitivity detection of failures that have occurred in the AC input circuit This monitoring can be disabled by the scheme switch CTSVEN A D accur...

Page 62: ...put when the BIn output is 0 If the trip circuit failure is detected then ALARM LED is lit and Err TC is displayed in LCD message The monitoring is enabled by setting the scheme switch TCSPEN to ON or OPT ON When OPT ON is selected the monitoring is enabled only while CB is closed 1 TCSPEN ON OPT ON 1 CB CLOSE TC_FAIL 0 4s t 0 Trip circuit supervision BIn command 1359 TCSV 1548 BIn Trip output CB ...

Page 63: ...r is monitored because the disconnector contact signal is used for the out of service terminal detection To monitor the disconnector one pair of normally open contact and normally closed contact is introduced Disconnector failure is detected when both contacts are simultaneously in the open or closed state for the prescribed period The monitoring is blocked by setting the scheme switch DSSMEN to O...

Page 64: ...it breakers the dielectric withstand of the oil generally decreases as a function of I2 t and maintenance such as oil changes etc may be required I is the fault current broken by CB t is the arcing time within the interrupter tank and it cannot be determined accurately Therefore y is normally set to 2 to monitor the broken current squared For other circuit breaker types especially those for HV sys...

Page 65: ...ally LCD display and event recording of the failure may not function normally Table 3 3 1 Supervision Items and Alarms Supervision Item LCD Message LED IN SERVICE LED ALARM External alarm Alarm record Message AC input imbalance monitoring Err CT On Off 2 On 4 Relay fail or Relay fail A 2 A D accuracy check Err A D Off On 4 Relay fail Memory monitoring Err SUM Err RAM Err BRAM Err EEP Off On 4 Rela...

Page 66: ...h tripping is blocked and an alarm is output or if only an alarm is output 3 3 10 Setting The setting element necessary for the automatic supervision and its setting range are shown in the table below Element Range Step Default Remarks CTSVEN OFF ALM BLK ALM ALM BLK Alarming and blocking or alarming only IDSVEN OFF ALM BLK ALM ALM BLK Alarming and blocking or alarming only TCSPEN OFF ON OPT ON OFF...

Page 67: ...lts have been stored the record of the oldest fault is deleted and the record of the latest fault is then stored Date and time occurrence This is the time at which a tripping command has been initiated The time resolution is 1 ms using the relay internal clock Trip mode This shows the protection scheme that output the tripping command Operating phase This is the phase to which an operating command...

Page 68: ... have been stored the oldest event record is deleted and the latest event record is then stored 3 4 3 Disturbance Recording Disturbance recording is started when the overcurrent starter element operates or a tripping command is initiated Further disturbance recording is started when a start command by PLC is initiated User can configure four disturbance record triggers Signal No 2632 to 2635 by PL...

Page 69: ... EF 0 5 250 0 A 0 1 A 3 0 A Earth fault detection 0 10 50 00 A 0 01 A 0 60A SEF 0 01 1 00 A 0 01 A 1 00 A Sensitive earth fault detection 0 002 0 200 A 0 001 A 0 200 A Current values shown in the parentheses are for the case of a 1A rating Other current values are for the case of a 5A rating Starting the disturbance recording by a tripping command or the starter element listed above is enabled or ...

Page 70: ...M Maximum phase current Iamax Ibmax Icmax Maximum residual current Iemax Maximum negative and zero sequence currents I2max I0max Maximum ratio of negative to positive sequence current I21 max Note The displayed power system quantity Ie depends on relay model The Ie is not displayed in model 100 and 400 is a residual current for EF in model 110 and 410 and is a current for SEF fed from core balance...

Page 71: ...essing any key other than VIEW and RESET will display the menu screen These screens are turned off by pressing the RESET key or END key If any display is left for 5 minutes or longer without operation the back light will go off LED There are 6 LED displays The signal labels and LED colors are defined as follows Label Color Remarks IN SERVICE Green Lit when the relay is in service TRIP Red Lit when...

Page 72: ...on Alarm display and Indication Pressing RESET key turns off the display Monitoring jacks The two monitoring jacks A and B and their respective LEDs can be used when the test mode is selected on the LCD screen By selecting the signal to be observed from the Signal List and setting it on the screen the signal can be displayed on LED A or LED B or transmitted to an oscilloscope via a monitoring jack...

Page 73: ... Unit Remote Terminal Unit to connect between relays and to construct a network communication system See Figure 4 4 1 in Section 4 4 In the case of the two port type one port can be used for the relay setting and monitoring RSM system or IEC60870 5 103 communication while the other port is used for IEC60870 5 103 communication only Screw terminals for RS485 or ST connectors for fibre optic interfa...

Page 74: ... 8 Rear view TB3 E TB1 TB2 TB4 RS485 connection terminal COM1 COM2 Note TB4 is provided only for RS485 two ports model TX and RX are provided only for model 400 series TX RX Figure 4 1 2 1 Location of Communication Port ...

Page 75: ...d LED Displays Displays during normal operation Indication I N D 1 0 0 0 0 0 0 0 0 I N D 2 0 0 0 1 0 0 0 0 Metering 1 I a k A Metering 2 I b k A Metering 3 I c k A Metering 4 I e k A Available for models 110 and 410 Metering 5 I s e A Available for models 120 and 420 Metering 6 I a R k A Metering 7 I b R k A Metering 8 I c R k A Metering 9 I d a k V Metering 10 I d b k V Metering 11 I d c k V ...

Page 76: ...t fault P h a s e A B C Faulted phases O C 1 Tripping element If a fault occurs and a tripping command is output when the LCD is off the red TRIP LED and other configurable LED if signals assigned to trigger by tripping Press the VIEW key to scroll the LCD screen to read the rest of messages Press the RESET key to turn off the LEDs and LCD display Notes 1 When configurable LEDs LED1 through LED3 a...

Page 77: ...ervision operation Auto supervision E r r R O M A D If the automatic supervision function detects a failure while the LCD is off the Auto supervision screen is displayed automatically showing the location of the failure and the ALARM LED lights Press the VIEW key to display other digest screens in turn including the Metering and Latest fault screens Press the RESET key to turn off the LEDs and LCD...

Page 78: ...RESET keys do not function To return to the digest Auto supervision screen do the following Return to the top screen of the menu by repeatedly pressing the END key Press the END key to turn off the LCD Press the VIEW key to display the digest screen Press the RESET key to turn off the LCD Alarm Display Alarm Display ALM1 to ALM4 A L M 1 The four alarm screens can be provided and their text message...

Page 79: ...archy see Appendix D Record F record E record D record Counter Status Metering Binary I O Relay element Time sync Clock adjust LCD contrast Set view Version Description Comms Record Status Protection Binary I P Binary O P LED Set change Password Description Comms Record Status Protection Binary I P Binary O P LED Test Switch Binary O P Logic circuit Sim fault Menu Figure 4 2 1 Relay Menu ...

Page 80: ...nge settings related to relay tripping it has password security protection Test The Test menu is used to set testing switches and to forcibly operate binary output relays When the LCD is off press any key other than the VIEW and RESET keys to display the top MENU screen and then proceed to the relay menus M E N U R e c o r d S t a t u s S e t v i e w S e t c h a n g e T e s t To display the MENU s...

Page 81: ...W and RESET keys Select Record to display the Record sub menu 1 R e c o r d F r e c o r d E r e c o r d D r e c o r d C o u n t e r Select F record to display the F record screen 2 F r e c o r d D i s p l a y C l e a r Select Display to display the dates and times of fault records stored in the relay from the top in new to old sequence 3 F r e c o r d 1 1 6 J u l 2 0 0 1 1 8 1 3 5 7 0 3 1 2 2 0 M ...

Page 82: ...A I d c k A F a u l t v a l u e s I a k A I b k A I c k A I e k A Available for model 110 and 410 I e A Available for model 120 and 420 I 1 k A I 2 k A I 0 k A I 2 I 1 I a R k A I b R k A I c R k A I d a k A I d b k A I d c k A T H M The lines which are not displayed in the window can be displayed by pressing the and keys To clear all the fault records do the following Open the Record sub menu ...

Page 83: ...d to display the Record sub menu Select E record to display the E record screen 2 E r e c o r d D i s p l a y C l e a r Select Display to display the events with date from the top in new to old sequence 3 E r e c o r d 2 1 S e p 2 0 0 2 4 8 0 O C 1 A t r i p O n 2 1 S e p 2 0 0 2 4 7 9 O C 1 A O n The time is displayed by pressing the key 3 E r e c o r d 1 3 2 2 4 5 2 1 1 D I F t r i p O n 1 3 2 2...

Page 84: ...0 1 1 8 1 3 5 7 4 0 1 2 2 0 M a y 2 0 0 1 1 5 2 9 2 2 3 8 8 3 0 4 F e b 2 0 0 1 1 1 5 4 5 3 4 4 4 4 2 8 J a n 2 0 0 1 0 7 3 0 1 8 8 7 6 The lines which are not displayed in the window can be displayed by pressing the and keys To clear all the disturbance records do the following Open the Record sub menu Select D record to display the D record screen Select Clear to display the following confirmati...

Page 85: ... the window can be displayed by pressing the and keys To clear each count do the following Open the Record sub menu Select Counter to display the Counter screen Select Clear Trips to display the following confirmation screen C l e a r T r i p s E N D Y C A N C E L N Select Clear Trips A to display the following confirmation screen C l e a r T r i p s A E N D Y C A N C E L N Select Clear Trips B to...

Page 86: ... time synchronisation source Status of clock adjustment Status of LCD contrast The data are updated every second 4 2 4 1 Displaying Metering Data To display metering data on the LCD do the following Select Status on the top MENU screen to display the Status screen 1 S t a t u s M e t e r i n g B i n a r y I O R e l a y e l e m e n t T i m e s y n c C l o c k a d j u s t L C D c o n t r a s t Selec...

Page 87: ...he following Press the RESET key on any max demand screen primary or secondary to display the following confirmation screen C l e a r m a x E N D Y C A N C E L N Press the END Y key to clear all max data stored in non volatile memory If the primary side unit A is required select 2 Pri A on the Metering screen See Section 4 2 6 6 Note When changing the units kA A of primary side current with RSM100...

Page 88: ...es press the and keys 4 2 4 3 Displaying the Status of Measuring Elements To display the status of measuring elements on the LCD do the following Select Status on the top MENU screen to display the Status screen Select 3 Ry element to display the status of the relay elements 2 R y e l e m e n t D I F 0 0 0 0 O C 1 2 0 0 0 0 0 0 O C 3 4 0 0 0 0 0 0 O C 5 0 0 0 E F 1 4 0 0 0 0 S E 1 4 0 0 0 0 U C 1 ...

Page 89: ...internal clock is synchronised with the marked source clock If the marked source clock is inactive the internal clock runs locally Note If the Binary input signal has not been detected for one hour or more after the last detection the status becomes inactive For details of the setting time synchronisation see Section 4 2 6 6 4 2 4 5 Clock Adjustment To adjust the clock when the internal clock is r...

Page 90: ...key and deep by pressing the key 4 2 5 Viewing the Settings The sub menu Set view is used to view the settings made using the sub menu Set change The following items are displayed Relay version Description Relay address and baud rate in the RSM relay setting and monitoring system or IEC60870 5 103 communication Record setting Status setting Protection setting Binary input setting Binary output set...

Page 91: ...nge sub menu is used to make or change settings for the following items Password Description Relay address and baud rate in the RSM or IEC60870 5 103 communication Recording setting Status setting Protection setting Binary input setting Binary output setting LED setting All of the above settings except the password can be seen using the Set view sub menu CAUTION Modification of settings Care shoul...

Page 92: ...ge is not required skip the line with the and keys 1 S e t c h a n g e P a s s w o r d D e s c r i p t i o n C o m m s R e c o r d S t a t u s P r o t e c t i o n B i n a r y I P B i n a r y O P L E D Move the cursor to a setting item Press the ENTER key To enter a text string Texts strings are entered under Plant name or Description screen 2 D e s c r i p t i o n P l a n t n a m e D e s c r i p t...

Page 93: ...or can be moved to upper or lower lines within the screen by pressing the and keys If setting change is not required skip the line with the and keys 4 T i m e s t a r t e r T i m e s 2 0 _ O C A 2 0 0 E F A 0 6 0 S E F A 0 2 0 0 Move the cursor to a setting line Press the or key to set a desired value The value is up or down by pressing the or key Press the ENTER key to enter the value After compl...

Page 94: ...be set as follows Select Set change on the main MENU screen to display the Setting change screen Select Password to display the Password screen Enter a 4 digit number within the brackets after Input and press the ENTER key I n p u t _ 1 2 3 4 5 6 7 8 9 0 For confirmation enter the same 4 digit number in the brackets after Retype R e t y p e _ 1 2 3 4 5 6 7 8 9 0 Press the END key to display the co...

Page 95: ...scription to display the Description screen 2 D e s c r i p t i o n P l a n t n a m e D e s c r i p t i o n To enter the plant name select Plant name on the Description screen To enter special items select Description on the Description screen _ A B C D E F G H I J K L M N O P Q R S T U V W X Y Z a b c d e f g h i j k l m n o p q r s t u v w x y z 0 1 2 3 4 5 6 7 8 9 _ ˆ Enter the text string 4 2 ...

Page 96: ...C60870 5 103 applied select 1 IEC103 CAUTION When changing the setting to the HDLC during the IEC103 operation the IEC103 command INF18 in Appendix M is canceled The output of IEC103 command INF18 can be observed by assigning their signal numbers to LEDs or binary output relays see Sections 4 2 6 9 and 4 2 6 10 232C This line is to select the RS 232C baud rate when the RSM system applied Note The ...

Page 97: ...off trigger events EV Enter the signal number to be assigned Setting the disturbance recording Select D record to display the D record screen 3 D r e c o r d T i m e s t a r t e r S c h e m e s w B i n a r y s i g Select Time starter to display the Time starter screen 4 T i m e s t a r t e r T i m e s 2 0 _ O C A 2 0 0 E F A 0 6 0 S E F A 0 2 0 0 Enter the recording time and starter element settin...

Page 98: ...l number to record binary signals in Appendix B Setting the counter Select Counter to display the Counter screen 3 C o u n t e r S c h e m e s w T h r e s h o l d s e t To set each counter to use or not to use do the following Select Scheme sw on the Counter screen to display the Scheme sw screen 4 S c h e m e s w T C S P E N 0 _ O f f O n O p t O n C B S M E N 0 O f f O n D S S M E N 0 O f f O n ...

Page 99: ...S t a t u s M e t e r i n g T i m e s y n c T i m e z o n e Option Setting the metering Select Metering to display the Metering screen 3 M e t e r i n g D i s p l a y 1 _ P r i S e c P r i A Enter 0 or 1 or 2 and press the ENTER key Enter 0 Pri to display the primary side current in kilo amperes kA Enter 1 Sec to display the secondary side current Enter 2 Pri A to display the primary side current ...

Page 100: ...orm GMT to the local time Select Time zone to display the Time zone screen 3 T i m e z o n e G M T h r s 9 _ Enter the difference between GMT and local time and press the ENTER key 4 2 6 7 Protection The GRL150 can have 4 setting groups for protection in order to accommodate changes in the operation of the power system one setting group is assigned active To set the protection do the following Sel...

Page 101: ...key IDSVEN To set differential current monitoring enable do the following Enter 0 Off or 1 ALM BLK or 2 ALM by pressing the or key and press the ENTER key Changing the Group settings Select the Group on the Act gp screen to change the settings and press the ENTER key 4 G r o u p P a r a m e t e r T e l e c o m m T r i p Setting the parameter Enter the line name and the CT ratio as follows Select P...

Page 102: ... u a l SP SYN To set Master or Slave terminal in sampling synchronisation do the following Enter 0 Master or 1 Slave by pressing the or key and press the ENTER key COM I F To set PW pilot wire or OPT fibre optic in communication system do the following Enter 0 PW or 1 OPT by pressing the or key and press the ENTER key RL MODE To set the receiving signal mode do the following Enter 0 Auto or 1 Manu...

Page 103: ...e sw screen to display the Application screen 7 A p p l i c a t i o n M O C 1 1 _ D I E C I E E E U S C M E F 1 1 _ D I E C I E E E U S C M S E 1 1 _ D I E C I E E E U S C O T D 1 _ O f f O n MOC1 MEF1 MSE1 To set the OC1 EF1 and SEF1 time delay characteristic type do the following Enter 0 D DT or 1 IEC or 2 IEEE or 3 US or 4 C CON and press the ENTER key OTD Enter 1 On to set the open terminal de...

Page 104: ... V I E I M O C 1 C U S 0 C O 2 C O 8 O C 1 R 0 D E F D E P O C 2 E N 0 O f f O n O C 3 E N 0 O f f O n O C 4 E N 0 O f f O n OC EN Enter 1 On to enable the OC and press the ENTER key If disabling the OC enter 0 Off and press the ENTER key MOC1C To set the OC1 Inverse Curve Type do the following If MOC1 is 1 IEC enter 0 NI or 1 VI or 2 EI or 3 LTI and press the ENTER key If MOC1 is 2 IEEE enter 0 M...

Page 105: ...O n EF EN Enter 1 On to use an earth fault protection and press the ENTER key If disabling the EF enter 0 Off and press the ENTER key MEF1C To set the EF1 Inverse Curve Type do the following If MEF1 is 1 IEC enter 0 NI or 1 VI or 2 EI or 3 LTI and press the ENTER key If MEF1 is 2 IEEE enter 0 MI or 1 VI or 2 EI and press the ENTER key If MEF1 is 3 US enter 0 CO2 or 1 CO8 and press the ENTER key EF...

Page 106: ... enter 0 Off and press the ENTER key MSE1C To set the SEF1 Inverse Curve Type do the following If MSE1 is 1 IEC enter 0 NI or 1 VI or 2 EI or 3 LTI and press the ENTER key If MSE1 is 2 IEEE enter 0 MI or 1 VI or 2 EI and press the ENTER key If MSE1 is 3 US enter 0 CO2 or 1 CO8 and press the ENTER key SE1R To set the Reset Characteristic do the following If MSE1 is 2 IEEE or 3 US enter 0 DEF or 1 D...

Page 107: ...0 O f f T r i p B O UC EN Enter 1 On to enable the UC and press the ENTER key If disabling the UC enter 0 Off and press the ENTER key THMEN Enter 1 On to enable the Thermal OL and press the ENTER key If disabling the Thermal OL enter 0 Off and press the ENTER key THMAEN Enter 1 On to enable the Thermal Alarm and press the ENTER key If disabling the Thermal Alarm enter 0 Off and press the ENTER key...

Page 108: ...N A B L K CLEN To set the Cold load function enable do the following Enter 1 On to enable the Cold Load function and press the ENTER key If disabling the Cold Load enter 0 Off and press the ENTER key CLDOEN Enter 1 On to enable the Cold Load drop off and press the ENTER key If disabling the Cold Load drop off enter 0 Off and press the ENTER key DIF ICD Enter 1 BLK to block the DIF tripping when th...

Page 109: ... S V Differential current supervision 5 0 _ T I D S V s 1 0 _ Differential current supervision timer Enter the numerical value and press the ENTER key After setting press the END key to display the following confirmation screen C h a n g e s e t t i n g s E N T E R Y C A N C E L N Press the ENTER Y key to change settings and return to the Prot element screen Setting the OC elements Select OC on th...

Page 110: ...ing confirmation screen C h a n g e s e t t i n g s E N T E R Y C A N C E L N Press the ENTER Y key to change settings and return to the Prot element screen Setting the EF elements Select EF on the Prot element screen to display the EF screen 7 E F E F 1 A 0 3 0 _ T E F 1 M 1 0 0 0 T E F 1 s 1 0 0 T E F 1 R s 0 0 T E F 1 R M 1 0 0 0 E F 2 A 3 0 0 T E F 2 s 1 0 0 E F 3 A 5 0 0 T E F 3 s 0 0 0 E F 4...

Page 111: ...elements Select SEF on the Prot element screen to display the SEF screen 7 S E F S E 1 A 0 0 1 0 T S E 1 M 1 0 0 0 T S E 1 s 1 0 0 T S E 1 R s 0 0 T S E 1 R M 1 0 0 0 T S 1 S 2 s 0 0 0 S E 2 A 0 0 1 0 T S E 2 s 1 0 0 S E 3 A 0 0 1 0 T S E 3 s 0 0 0 S E 4 A 0 0 1 0 T S E 4 s 0 0 0 S E 1 k SE1 User configurable IDMT curve setting 0 0 0 0 S E 1 α ditto 0 0 0 S E 1 C ditto 0 0 0 0 S E 1 k r ditto 0 0 ...

Page 112: ...I P A 0 0 0 T T H M m i n 1 0 0 T H M A 8 0 B C D 0 2 0 T B C D s 0 0 0 C B F A 0 5 0 T B T C s 0 5 0 T R T C s 1 0 0 Enter the numerical value and press the ENTER key After setting press the END key to display the following confirmation screen C h a n g e s e t t i n g s E N T E R Y C A N C E L N Press the ENTER Y key to change settings and return to the Prot element screen Setting the CLP ICD el...

Page 113: ...h a n g e s e t t i n g s E N T E R Y C A N C E L N Press the ENTER Y key to change settings and return to the Prot element screen Setting group copy To copy the settings of one group and overwrite them to another group do the following Select Copy gp on the Protection screen to display the Copy A to B screen 3 C o p y A t o B A _ B Enter the group number to be copied in line A and press the ENTER...

Page 114: ...n 3 B I T i m e r s F u n c t i o n s Setting timers Select Timers on the BI screen to display the Timers screen 4 T i m e r s B I 1 P U D s Pick up delay setting 0 0 0 _ B I 1 D O D s Drop off delay setting 0 0 0 Enter the numerical value and press the ENTER key After setting press the END key to return to the BI screen Setting Functions Select Functions on the BI screen to display the Functions ...

Page 115: ...lable signals are listed in Appendix B It is also possible to attach Instantaneous or delayed or latched reset timing to these signals Appendix C shows the factory default settings CAUTION When having changed the binary output settings release the latch state on a digest screen by pressing the RESET key for more than 3 seconds To configure the binary output signals do the following Selection of ou...

Page 116: ...3 2 4 I n 4 0 T B O s 0 2 0 Assign signals to gates In 1 to 4 by entering the number corresponding to each signal referring to Appendix C Do not assign the signal numbers 546 to 550 signal names BO1 OP to BO5 OP And set the delay time of timer TBO Note If signals are not assigned to all the gates 1 to 4 enter 0 for the unassigned gate s Repeat this process for the outputs to be configured 4 2 6 10...

Page 117: ... R e s e t L o g i c 0 _ O R A N D R e s e t 0 I n s t L a t c h Enter 0 OR or 1 AND to use an OR gate or AND gate and press the ENTER key Enter 0 Instantaneous or 1 Latched to select the reset timing and press the ENTER key Press the END key to return to the LED screen Note To release the latch state refer to Section 4 2 1 Assigning signals Select Functions on the LED screen to display the Functi...

Page 118: ...iming and press the ENTER key Press the END key to return to the IND screen Note To release the latch state push the RESET key for more than 3 seconds Assigning signals Select Functions on the IND screen to display the Functions screen 5 F u n c t i o n s B I T 1 5 1 _ B I T 2 5 4 B I T 8 7 8 Assign signals to bits 1 to 8 by entering the number corresponding to each signal referring to Appendix B ...

Page 119: ... LCD described in Section 4 2 1 No events related to A M F are recorded either Disabling A M F is useful for blocking the output of unnecessary alarms during testing Select Test on the top MENU screen to display the Test screen 1 T e s t S w i t c h B i n a r y O P L o g i c c i r c u i t S i m f a u l t Select Switch to display the Switch screen 2 S w i t c h A M F 1 _ O f f O n C L P T S T 0 O f...

Page 120: ... to 1 On the local current data is looped into the receiving circuit interrupting the current data from the remote terminal as well as transmitted to the remote terminal Note The switch T test must be used only when all the terminals are out of service If not the local test current may cause a disturbance at the in service remote terminal because this switching is not recognized at the remote term...

Page 121: ...o operate the output relays forcibly After completing the entries press the END key Then the LCD displays the screen shown below O p e r a t e E N T E R Y C A N C E L N Keep pressing the ENTER key to operate the assigned output relays Release pressing the ENTER key to reset the operation Press the CANCEL key to return to the upper Binary O P screen 4 2 7 3 Logic Circuit It is possible to observe t...

Page 122: ...rigger a simultaneous test current application to the local and remote terminal differential elements when the END key is pressed on the Sim fault screen at either terminal The signal transmission delay time is automatically compensated in the relay and the operation time difference of the auxiliary relays is within 1ms For the signal list see Appendix B Select Sim fault on the Test screen to disp...

Page 123: ...Setting and Monitoring RSM system is a system that retrieves and analyses the data on power system quantities fault and event records and views or changes settings in individual relays via a telecommunication network using a remote PC Figure 4 4 1 shows the typical configuration of the RSM system via a protocol converter G1PR2 The relays are connected through twisted pair cables and the maximum 25...

Page 124: ...e calendar clock can run locally or be synchronised with the external clock such as the binary time standard input signal RSM clock IEC60870 5 103 or IRIG B available for model 4 series only This can be selected by setting The clock synchronise function synchronises the relay internal clock to the binary input signal by the following method A binary input Bin is assigned to SYNC_CLOCK signal No 26...

Page 125: ...ces when handling electronic circuits can cause serious damage This damage often may not be immediately apparent but the reliability of the circuit will have been reduced The electronic circuits are completely safe from electrostatic discharge when housed in the case Do not expose them to risk of damage by withdrawing the relay unit unnecessarily The relay unit incorporates the highest practical p...

Page 126: ...that detailed investigations on electronic circuitry should be carried out in a Special Handling Area such as described in the aforementioned IEC 60747 5 5 External Connections Typical external connections for each relay model are shown in Appendix F ...

Page 127: ...ent damage Hardware tests These tests are performed for the following hardware to ensure that there is no hardware defect Defects of hardware circuits other than the following can be detected by monitoring which circuits function when the DC power is supplied User interfaces Binary input circuits and output circuits AC input circuits Function tests These tests are performed for the following funct...

Page 128: ...unit Before turning on the power check the following Make sure the polarity and voltage of the power supply are correct Make sure the CT circuit is not open If dc power has not been supplied to the relay for two days or more then all fault records event records and disturbance records and internal clock may be cleared soon after restoring the power This is because the back up RAM may have discharg...

Page 129: ...ing appendixes Appendix C Binary Output Default Setting List Appendix G Relay Setting Sheet Visual inspection After unpacking the product check for any damage to the relay case If there is any damage the internal module might also have been affected Contact the vendor Relay ratings Check that the items described on the nameplate on the front of the relay conform to the user s specification The ite...

Page 130: ...ar on the whole screen LED display Apply the rated DC voltage and check that the IN SERVICE LED is lit in green Press the RESET key for one second or more and check that remaining five LEDs are lit in red or yellow Programmable LEDs are yellow VIEW and RESET keys Press the VIEW key when the LCD is off and check that the Virtual LED and Metering screens are sequentially displayed on the LCD Press t...

Page 131: ...terminal to another or for all the terminals at once 6 4 3 Binary Output Circuit This test can be performed by using the Test sub menu and forcibly operating the relay drivers and output relays Operation of the output contacts is monitored at the output terminal The output contact and corresponding terminal number are shown in Appendix G Select Binary O P on the Test screen to display the Binary O...

Page 132: ...the values applied coincide with the values displayed on the LCD screen The testing circuit is shown in Figure 6 4 4 1 A single phase current source is required TB1 1 Ia Single phase current source 2 3 4 6 5 Ib GRL150 Ic A DC power supply A9 B9 E TB2 7 8 I e Figure 6 4 4 1 Testing AC Input Circuit To check the metering data on the Metering screen do the followings Set view sub menu Status screen M...

Page 133: ... A 1 _ T e r m B 4 8 _ When a signal number is entered for the Term A line the signal is observed at monitoring jack A and when entered for the Term B line it is observed at monitoring jack B Note The voltage level at the monitoring jacks is 5V for logic level 1 and less than 0 1V for logic level 0 CAUTION Use test equipment with more than 1 kΩ of internal impedance when observing the output signa...

Page 134: ...X Ia Monitoring jack A 0V DC voltmeter TB2 A9 B9 E DC power supply Figure 6 5 1 1 Testing Phase Current Differential Element The output signal numbers of the DIF element are as follows Element Signal number DIF A 48 DIF B 49 DIF C 50 Set the L test to 1 On on the Switch screen of the Test sub menu See Section 4 2 7 Select the Logic circuit on the Test sub menu screen to display the Logic circuit s...

Page 135: ...rminals of one relay are directly connected to those of another relay as shown in Figure 6 5 1 2 Single phase current source TB1 TB2 1 2 A9 B9 E Relay A GRL150 Monitoring jack φ A 0V Ia A DC power supply Single phase current source A TB1 TB2 1 2 A9 B9 E Relay B GRL150 Monitoring jack A 0V Ia TX RX TX RX TB3 A16 A17 TB3 A16 A17 Note Connect TX and RX of the relay A to RX and TX of the relay B respe...

Page 136: ...ristic B is expressed by the following equation Iout DIFI2 where DIFI1 and DIFI2 are setting values Select the Logic circuit on the Test sub menu screen to display the Logic circuit screen Enter a signal number 48 to observe the DIF A output at monitoring jack A and press the ENTER key Apply a fixed infeed current to one relay Apply an outflow current to another relay change the magnitude of the c...

Page 137: ...ment Refer to Table 3 2 1 DC voltmeter Monitoring jack A 0V 0V Figure 6 5 1 4 Operating Current Value Test The output signal of testing element is assigned to the monitoring jack A The output signal numbers of the elements are as follows Element Signal No Element Signal No Element Signal No Element Signal No OC1 A 80 EF1 112 SEF1 116 UC1 A 176 OC2 A 84 EF2 113 SEF2 117 UC2 A 180 OC3 A 88 EF3 114 S...

Page 138: ...al No OC1 A 80 EF1 112 SEF1 116 Fix the time characteristic to test by setting the scheme switch MOC1 MEF1 or MSE1 on the OC EF or SEF screen Example Settings sub menu Protection screen Group screen OC screen The test procedure is as follows Enter the signal number to observe the operating time at the monitoring jack A as shown in Section 6 5 1 Apply a test current and measure the operating time T...

Page 139: ...ure the operating time The magnitude of the test current should be between 1 2 Is to 10 Is where Is is the current setting CAUTION After the setting of a test current apply the test current after checking that the THM has become 0 on the Metering screen Calculate the theoretical operating time using the characteristic equations shown in Section 2 7 Check that the measured operating time is within ...

Page 140: ...itch CLPTST to S0 Check that the OC1 operates at the setting value of normal setting group Next set the scheme switch CLPTST to S3 Check that the OC1 operates at the setting value of cold load setting group CLSG 6 5 1 8 Current Change Detection Element OCD The test circuit is shown in Figure 6 5 1 6 Single phase current source A TB1 DC voltmeter TB2 1 2 A9 B9 E GRL150 DC power supply Monitoring ja...

Page 141: ...and RTC to DIR or OC Apply a fault retain it and input an external trip signal Check that the retrip output relays operate after the time setting of the TRTC and the adjacent breaker tripping output relay operates after the time setting of the TBTC 6 5 3 Metering and Recording The metering function can be checked while testing the AC input circuit See Section 6 4 4 Fault recording can be checked w...

Page 142: ... I 1 I a R k A I b R k A I c R k A I d a k A I d b k A I d c k A I r a k A I r b k A I r c k A I p u a k A I p u b k A I p u c k A T H M R L Note The magnitude of current can be set in values on the primary side or on the secondary side by the setting The default setting is the secondary side 6 6 2 Communication Circuit Test Check whether the communication circuit is correctly connected between th...

Page 143: ...he value of M RL in increments recording the CF L values at each stage 6 The value of M RL that should be used as the final setting is that at which the lowest value of CF L is recorded Input current at a remote terminal relay Check the current by the Metering screen from the Status sub menu at the local relay 6 6 3 Tripping Circuit Test The tripping circuit including the circuit breaker is checke...

Page 144: ... t e E N T E R Y C A N C E L N Keep pressing the ENTER key to operate the output relay BO1 and check that the A phase breaker is tripped Stop pressing the ENTER key to reset the operation Repeat the above for TP1 BO2 to BO5 and FAIL ...

Page 145: ...r screen on the LCD Table 6 7 1 shows LCD messages and failure locations The locations marked with 1 have a higher probability than locations marked with 2 Table 6 7 1 LCD Message and Failure Location Message Failure location Relay Unit AC cable CB DS or cable Comm channel Err SUM Err RAM Err BRAM Err EEP Err A D Err Id 1 2 Err DC Err TC 1 2 Err CT 1 2 Err CB 1 2 Err DS 1 2 Err COM 2 1 Err SYN 2 1...

Page 146: ...odel Number is indicated on the front of the relay For the relay version see Section 4 2 5 1 Replacing the relay unit CAUTION After replacing the relay unit check the settings The procedure of relay withdrawal and insertion is as follows Switch off the DC power supply Hazardous voltage may remain in the DC circuit just after switching off the DC power supply It takes about 30 seconds for the volta...

Page 147: ...N SERVICE green LED is lit and the ALARM red LED is not lit Supply the AC inputs and reconnect the trip outputs 6 7 5 Storage The spare relay should be stored in a dry and clean room Based on IEC Standard 60255 6 the storage temperature should be 25 C to 70 C but the temperature of 0 C to 40 C is recommended for long term storage INSERVICE TRIP ALARM VIEW RESET A B 0V END CEL CAN ENTER END INSERVI...

Page 148: ...tests If dc power has not been supplied to the relay for two days or more then internal clock may be cleared soon after restoring the power This is because the back up RAM may have discharged and may contain uncertain data Set the internal clock again Press the VIEW key and check that no failure message is displayed on the Auto supervision screen Check that the green IN SERVICE LED is lit and no o...

Page 149: ... 148 6 F 2 S 0 8 2 8 ...

Page 150: ... 149 6 F 2 S 0 8 2 8 Appendix A Programmable Reset Characteristics and Implementation of Thermal Model to IEC60255 8 ...

Page 151: ...plastic insulated cables where the fault energy melts the cable insulation and temporarily extinguishes the fault after which the insulation again breaks down and the process repeats An inverse time overcurrent protection with instantaneous resetting cannot detect this condition until the fault becomes permanent thereby allowing a succession of such breakdowns to occur with associated damage to pl...

Page 152: ...he cold state and 100 represents the thermal limit that is the point at which no further temperature rise can be safely tolerated and the system should be disconnected The thermal limit for any given electrical plant is fixed by the thermal setting IAOL The relay gives a trip output when θ 100 If current I is applied to a cold system then θ will rise exponentially from 0 to I2 IAOL 2 100 with time...

Page 153: ... a cold system is switched on to an immediate overload Figure A 3 shows a typical thermal profile for a system which initially carries normal load current and is then subjected to an overload condition until a trip results before finally cooling to ambient temperature θ t s 100 Normal Load Current Condition Cooling Curve Overload Current Condition Trip at 100 Figure A 3 ...

Page 154: ... 153 6 F 2 S 0 8 2 8 Appendix B Signal List ...

Page 155: ... 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 DIF A DIF A element output 49 DIF B ditto 50 DIF C ditto 51 52 53 54 55 56 57 58 59 60 61 62 63 RELAY_BLOCK DIF relay block 64 OC5 A OC5 A element output 65 OC5 B ditto 66 OC5 C ditto 67 68 OCD A OCD A element output 69 OCD B ditto 70 OCD C ditto ...

Page 156: ...rush current detection Phase A 105 ICD B Inrush current detection Phase B 106 ICD C Inrush current detection Phase C 107 108 ICLDO A ICLDO relay OC relay element output used in CLP scheme 109 ICLDO B ditto 110 ICLDO C ditto 111 112 EF1 EF1 relay element output 113 EF2 EF2 relay element output 114 EF3 EF3 relay element output 115 EF4 EF4 relay element output 116 SEF1 SEF1 relay element output 117 S...

Page 157: ...71 172 173 174 175 176 UC1 A UC1 relay element output 177 UC1 B ditto 178 UC1 C ditto 179 180 UC2 A UC2 relay element output 181 UC2 B ditto 182 UC2 C ditto 183 184 185 186 187 188 THM T Thermal trip relay element output 189 THM A Thermal alarm relay element output 190 191 192 193 194 195 196 197 198 199 200 UCDO A UCDO relay element output 201 UCDO B ditto 202 UCDO C ditto 203 204 205 206 207 208...

Page 158: ...256 DIF_TRIP DIF trip command 257 DIF A_TRIP ditto Phase A 258 DIF B_TRIP B 259 DIF C_TRIP C 260 261 262 263 264 DIFFS_OP Fail safe for DIF trip 265 DIFFS A_OP ditto 266 DIFFS B_OP ditto 267 DIFFS C_OP ditto 268 269 270 271 272 OC1_TRIP OC1 trip command 273 OC1 A_TRIP ditto Phase A 274 OC1 B_TRIP B 275 OC1 C_TRIP C 276 OC2_TRIP OC2 trip command 277 OC2 A_TRIP ditto Phase A 278 OC2 B_TRIP B 279 OC2...

Page 159: ...P ditto Phase A 310 UC1 B TRIP B 311 UC1 C TRIP C 312 UC2 ALARM UC2 alarm command 313 UC2 A ALARM ditto Phase A 314 UC2 B ALARM B 315 UC2 C ALARM C 316 317 318 319 320 THM ALARM Thermal Overload alarm command 321 THM TRIP trip command 322 BCD TRIP Broken Conductor trip command 323 324 325 326 327 328 CBF RETRIP CBF retrip command 329 CBF A RETRIP ditto Phase A 330 CBF B RETRIP B 331 CBF C RETRIP C...

Page 160: ...TATE3 ditto 372 373 ICD Inrush current detection 3 phase OR 374 ICD_BLK S Inrush current detection send to remote terminal 375 376 377 378 379 380 381 382 383 384 CB_CLOSE CB close condition 385 CB_OPEN CB open condition 386 DS_CLOSE DS close condition 387 DS_OPEN DS open condition 388 I LINK Interlink signal CB and DS both closed 389 43C_ON Differential protection enable 390 LOCAL_TEST LOCAL TEST...

Page 161: ...minal 1 in service 433 REM1_OFF_SRV Terminal 1 out of service 434 435 436 437 438 UNREADY1_ALM Terminal 1 communication not ready 439 CFSV1 Terminal 1 CFSV 440 SPSV1 Sampling synchronization with terminal 1 failure signal 441 442 443 444 445 446 447 448 449 450 COMM1_FAIL Communication with terminal 1 failure signal 451 452 READY1_ALARM Terminal 1 ready 453 454 455 456 457 458 459 460 461 462 463 ...

Page 162: ...8 520 521 522 523 524 525 526 527 528 BI1_COM_T Binary input signal BI1 529 BI2_COM_T Binary input signal BI2 530 BI3_COM_T Binary input signal BI3 531 BI4_COM_T Binary input signal BI4 532 BI5_COM_T Binary input signal BI5 533 BI6_COM_T Binary input signal BI6 534 BI7_COM_T Binary input signal BI7 535 BI8_COM_T Binary input signal BI8 536 537 538 539 540 541 542 543 544 TP1_OP Binary output signa...

Page 163: ..._IND1 LCD indication1 Virtual LED command 719 LCD_IND2 LCD indication2 Virtual LED command 720 721 722 TELE_COM_ON IEC103 communication command 723 PROT_COM_ON IEC103 communication command 724 725 726 727 728 729 730 731 732 733 734 735 736 737 738 739 740 741 742 743 744 745 746 747 748 749 750 751 752 753 754 755 756 757 758 759 760 761 762 763 764 765 766 767 768 769 770 ...

Page 164: ...oup3 active 1027 GROUP4_ACTIVE group4 active 1028 1029 1030 1031 1032 1033 1034 LOCAL_OP_ACT local operation active 1035 REMOTE_OP_ACT remote operation active 1036 1037 GEN_TRIP General trip 1038 GEN_PICKUP General start pick up 1039 IEC_TESTMODE IEC61870 5 103 testmode 1040 IEC_MDBLK monitor direction blocked 1041 1042 1043 1044 1045 1046 1047 1048 1049 1050 1051 1052 1053 1054 1055 1056 1057 105...

Page 165: ...F ditto 1100 COM5 R1_UF ditto 1101 1102 1103 1104 SUB_COM1 R1 Sub comm data receive signal from term 1 1105 SUB_COM2 R1 ditto 1106 SUB_COM3 R1 ditto 1107 SUB_COM4 R1 ditto 1108 SUB_COM5 R1 ditto 1109 1110 1111 1112 SUB2_COM1 R1 Sub comm data2 receive signal from term 1 1113 SUB2_COM2 R1 ditto 1114 SUB2_COM3 R1 ditto 1115 SUB2_COM4 R1 ditto 1116 SUB2_COM5 R1 ditto 1117 SUB2_COM6 R1 ditto 1118 SUB2_...

Page 166: ...ed 1286 BI3_COM_UF Binary input signal BI3 unfiltered 1287 BI4_COM_UF Binary input signal BI4 unfiltered 1288 BI5_COM_UF Binary input signal BI5 unfiltered 1289 BI6_COM_UF Binary input signal BI6 unfiltered 1290 BI7_COM_UF Binary input signal BI7 unfiltered 1291 BI8_COM_UF Binary input signal BI8 unfiltered 1292 1293 1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 1306 1307 1308 1309 1...

Page 167: ...accuracy checking error 1355 1356 CT_err CT circuit current monitoring error 1357 1358 DC_err DC supply monitoring error 1359 TC_fail Trip circuit fail 1360 CB_err CB contact monitoring error 1361 TP_COUNT_ALM Trip count alarm 1362 OP_time_ALM Operate time alarm 1363 Sigma_I y_ALM ΣI y count alarm 1364 1365 1366 Id_err Differential current monitoring err 1367 1368 1369 DS_err DS contact monitoring...

Page 168: ...37 1438 1439 1440 1441 1442 1443 1444 1445 1446 1447 1448 DEMAND_CLR Demand clear 1449 F Record_DONE 1450 F Record_CLR Fault record clear 1451 1452 E Record_CLR Event record clear 1453 D Record_CLR Disturbance record clear 1454 CF_count_CLR CF counter clear 1455 Reserved for counter clear 1456 D REC_FULL Disturbance record full 1457 Reserved for disturbance record status 1458 Reserved for disturba...

Page 169: ...p block command 1569 UC2 BLOCK 2 1570 CBF BLOCK CBF protection block command 1571 1572 THM BLOCK Thermal Overload trip block command 1573 THMA BLOCK Thermal Overload alarm block command 1574 BCD BLOCK Broken conductor trip block command 1575 1576 1577 1578 1579 1580 1581 1582 1583 1584 DIF A FS Fail safe command for DIF A trip 1585 DIF B FS Fail safe command for DIF B trip 1586 DIF C FS Fail safe ...

Page 170: ...p command 1630 SEF3_INST_TP SEF3 instantly trip command 1631 SEF4_INST_TP SEF4 instantly trip command 1632 UC1_INST_TP UC1 instantly trip command 1633 UC2_INST_TP UC2 instantly trip command 1634 1635 1636 1637 1638 1639 1640 1641 1642 1643 1644 1645 1646 1647 1648 TR1 R1 Transfer trip 1 command from remote term 1649 TR2 R1 Transfer trip 2 command from remote term 1650 L TEST R1 Local testing comma...

Page 171: ...ked command by inrush current 1683 OC_IC_BLK OC EF SEF blocked command by inrush current 1684 1685 1686 1687 1688 1689 1690 1691 1692 1693 1694 1695 1696 1697 1698 1699 1700 1701 1702 1703 1704 1705 1706 1707 1708 1709 1710 1711 1712 1713 1714 1715 1716 1717 1718 1719 1720 1721 1722 1723 1724 1725 1726 1727 1728 1729 1730 1731 1732 1733 1734 1735 1736 1737 1738 1739 1740 1741 1742 1743 1744 1745 1...

Page 172: ...itto reserved 2060 SUB_COM5 S ditto reserved 2061 2062 2063 2064 SUB2_COM1 S Sub communication on off data 2 send command 2065 SUB2_COM2 S ditto 2066 SUB2_COM3 S ditto 2067 SUB2_COM4 S ditto 2068 SUB2_COM5 S ditto 2069 SUB2_COM6 S ditto 2070 SUB2_COM7 S ditto 2071 SUB2_COM8 S ditto 2072 SUB2_COM9 S ditto 2073 SUB2_COM10 S ditto 2074 SUB2_COM11 S ditto 2075 SUB2_COM12 S ditto 2076 2077 2078 2079 20...

Page 173: ...2514 2515 2516 2517 2518 2519 2520 2521 2522 2523 2524 2525 2526 2527 2528 2529 2530 2531 2532 2533 2534 2535 2536 2537 2538 2539 2540 2541 2542 2543 2544 2545 2546 2547 2548 2549 2550 2551 2552 2553 2554 2555 2556 2557 2558 2559 2560 TP1 Binary output signal of TP1 2561 TP2 TP2 2562 2563 2564 2565 2566 2567 2568 2569 2570 ...

Page 174: ...02 2603 2604 2605 2606 2607 2608 2609 2610 2611 2612 2613 2614 2615 2616 2617 2618 2619 2620 2621 2622 2623 2624 F RECORD1 Fault record stored command 1 2625 F RECORD2 2 2626 F RECORD3 3 2627 F RECORD4 4 2628 2629 2630 2631 2632 D RECORD1 Disturbance record stored command 1 2633 D RECORD2 2 2634 D RECORD3 3 2635 D RECORD4 4 2636 2637 2638 2639 2640 SET GROUP1 Active setting group changed command C...

Page 175: ...MD4 ditto 2660 CON TPMD5 ditto 2661 CON TPMD6 ditto 2662 CON TPMD7 ditto 2663 CON TPMD8 ditto 2664 2665 2666 2667 2668 2669 2670 2671 2672 2673 2674 2675 2676 2677 2678 2679 2680 2681 2682 2683 2684 2685 TEL COM RECV Teleprotection inactivate command received 2686 PROT COM RECV protection inactivate command received 2687 2688 TPLED RST RCV TRIP LED RESET command received 2689 ALMLED RST RCV ALARM ...

Page 176: ...01 2877 TEMP002 2878 TEMP003 2879 TEMP004 2880 TEMP005 2881 TEMP006 2882 TEMP007 2883 TEMP008 2884 TEMP009 2885 TEMP010 2886 TEMP011 2887 TEMP012 2888 TEMP013 2889 TEMP014 2890 TEMP015 2891 TEMP016 2892 TEMP017 2893 TEMP018 2894 TEMP019 2895 TEMP020 2896 TEMP021 2897 TEMP022 2898 TEMP023 2899 TEMP024 2900 TEMP025 2901 TEMP026 2902 TEMP027 2903 TEMP028 2904 TEMP029 2905 TEMP030 2906 TEMP031 2907 TE...

Page 177: ...2936 TEMP121 2937 TEMP122 2938 TEMP123 2939 TEMP124 2940 TEMP125 2941 TEMP126 2942 TEMP127 2943 TEMP128 2944 TEMP129 2945 TEMP130 2946 TEMP131 2947 TEMP132 2948 TEMP133 2949 TEMP134 2950 TEMP135 2951 TEMP136 2952 TEMP137 2953 TEMP138 2954 TEMP139 2955 TEMP140 2956 TEMP141 2957 TEMP142 2958 TEMP143 2959 TEMP144 2960 TEMP145 2961 TEMP146 2962 TEMP147 2963 TEMP148 2964 TEMP149 2965 TEMP150 2966 TEMP1...

Page 178: ...3006 TEMP191 3007 TEMP192 3008 TEMP193 3009 TEMP194 3010 TEMP195 3011 TEMP196 3012 TEMP197 3013 TEMP198 3014 TEMP199 3015 TEMP200 3016 TEMP201 3017 TEMP202 3018 TEMP203 3019 TEMP204 3020 TEMP205 3021 TEMP206 3022 TEMP207 3023 TEMP208 3024 TEMP209 3025 TEMP210 3026 TEMP211 3027 TEMP212 3028 TEMP213 3029 TEMP214 3030 TEMP215 3031 TEMP216 3032 TEMP217 3033 TEMP218 3034 TEMP219 3035 TEMP220 3036 TEMP2...

Page 179: ...MP236 3052 TEMP237 3053 TEMP238 3054 TEMP239 3055 TEMP240 3056 TEMP241 3057 TEMP242 3058 TEMP243 3059 TEMP244 3060 TEMP245 3061 TEMP246 3062 TEMP247 3063 TEMP248 3064 TEMP249 3065 TEMP250 3066 TEMP251 3067 TEMP252 3068 TEMP253 3069 TEMP254 3070 TEMP255 3071 TEMP256 ...

Page 180: ... 179 6 F 2 S 0 8 2 8 Appendix C Binary Output Default Setting List ...

Page 181: ...71 In 4 0 In 4 Timer 0 00 10 00 0 20 3 BO3 OR AND Ins Dl Dw Lat In 1 0 3071 OR Del In 1 256 DIF_TRIP In 1 In 2 0 3071 In 2 0 In 2 In 3 0 3071 In 3 0 In 3 In 4 0 3071 In 4 0 In 4 Timer 0 00 10 00 0 20 4 BO4 OR AND Ins Dl Dw Lat In 1 0 3071 OR Del In 1 256 DIF_TRIP In 1 In 2 0 3071 In 2 0 In 2 In 3 0 3071 In 3 0 In 3 In 4 0 3071 In 4 0 In 4 Timer 0 00 10 00 0 20 5 BO5 OR AND Ins Dl Dw Lat In 1 0 307...

Page 182: ... 181 6 F 2 S 0 8 2 8 Appendix D Details of Relay Menu ...

Page 183: ...ANCEL N Clear records END Y CANCEL N 1 Record xF record xE record xD record xCounter 2 F record xDisplay xClear 3 F record 1 16 Jul 2002 18 13 57 031 3 D record 1 16 Jul 2002 18 13 57 401 2 E record xDisplay xClear 3 E record 16 Jul 2002 480 DIF trip On 2 D record xDisplay xClear Refer to Section 4 2 3 1 Refer to Section 4 2 3 2 Refer to Section 4 2 3 3 ...

Page 184: ...on 4 2 3 4 2 Counter xDisplay xClear Trips xClear Trips A xClear Trips B xClear Trips C xClear ΣI yA xClear ΣI yB xClear ΣI yC xClear CF Clear Trips A END Y CANCEL N Clear Trips B END Y CANCEL N Clear Trips C END Y CANCEL N Clear ΣI yA END Y CANCEL N Clear ΣI yB END Y CANCEL N a 1 b 1 Clear ΣI yC END Y CANCEL N Clear CF END Y CANCEL N ...

Page 185: ...nt xTime sync xClock adjust xLCD contrast 1 Set view xVersion xDescription xComms xRecord xStatus xProtection xBinary I P xBinary O P xLED Refer to Section 4 2 4 2 Version xRelay type xSerial No xSoftware xPLC data xIEC103 data 2 Description xPlant name xDescription Refer to Section 4 2 5 GS1PM1 01 GRL150 100A 10 10 2 Metering xCurrent xDemand 3 Demand lamax kA Clear max END Y CANCEL N PLCDefault1...

Page 186: ... 1 c 1 2 Act gp xCommon xGroup1 xGroup2 xGroup3 xGroup4 2 Status xMetering 3 Time sync 3 Metering xTime sync xTime zone 4 Time starter Time 2 0s 4 Scheme sw 4 Scheme sw 4 Threshold TCALM 10000 3 Counter xScheme sw xThreshold 4 Binary sig SIG1 3 D record xTime starter xScheme sw xBinary sig xSignal name 4 Signal no BITRN 100 4 Event name 4 Signal name 3 Time sync ...

Page 187: ... e 1 4 Trip xScheme sw xProt element a 1 b 1 c 1 5 Scheme sw xApplication xDIF xOC xEF xSEF xMisc xCLP ICD 6 Misc 6 CLP ICD 6 DIF 6 SEF 5 CT ratio xCT 400 4 Parameter xLine name xCT ratio 6 Application 6 OC 6 EF 5 Scheme sw 5 Threshold M RL 20 0 4 Telecomm xScheme sw xThreshold set ...

Page 188: ...P ICD OC1 2 00A 6 OC OC1 1 00A 3 Group4 xParameter 3 Group2 xParameter 2 Binary I P xBI1 xBI8 xAlarm1 Text xAlarm4 Text 3 BI1 xTimers xFunctions 3 BI8 xTimers xFunctions 4 Timers BI1PUD 0 00s 4 Functions Alarm Text 2 Binary O P BO1 AND D 1 10 29 0 BO5 OR L 1 2 3 4 TBO1 0 20s TBO5 0 20s 3 LED LED1 AND I 2 LED xLED xVirtual LED 3 Virtual LED xIND1 xIND2 4 LED1 BIT1 I O ...

Page 189: ...me sw xThreshold set 4 Binary sig 3 E record xBITRN _ xEV1 a 1 b 1 a 1 Refer to Section 4 2 6 4 Input _ 1234567890 Retype _ 1234567890 Confirmation trap Password trap Password _ 1234567890 Change settings ENTER Y CANCEL N _ ABCDEFG _ ABCDEFG 2 Description xPlant name xDescription Refer to Section 4 2 6 3 Refer to Section 4 2 6 2 2 Comms xAddr Param xSwitch 3 Addr Param 3 Switch 1 Set change xPassw...

Page 190: ...n xChange act gp xChange set xCopy gp 3 Change act gp 3 Act gp 1 xCommon xGroup1 xGroup2 xGroup3 xGroup4 Refer to Section 4 2 6 7 Refer to Section 4 2 6 6 4 Common 4 Group1 xParameter xTelecomm xTRIP _ ABCDEFG 6 CT ratio 5 Parameter xLine name xCT ratio 6 Scheme sw 6 Threshold 5 Telecomm xScheme sw xThreshold set 3 Time zone ...

Page 191: ... 2 c 2 d 2 e 2 7 SEF 5 Trip xScheme sw xProt element 6 Scheme sw xApplication xDIF xOC xEF xSEF xMisc xCLP ICD 7 Misc 7 CLP ICD 7 EF 7 Application 7 DIF 7 OC 7 OC 6 Prot element xDIF xOC xEF xSEF xMisc xCLP ICD 7 EF 7 SEF 7 Misc 7 CLP ICD 7 DIF ...

Page 192: ...r to Section 4 2 6 9 Refer to Section 4 2 6 8 2 Binary I P xBI1 xBI2 xBI8 xAlarm1 Text xAlarm4 Text 3 BI1 xTimers xFunctions 3 BI8 xTimers xFunctions ABCDEFG 4 Timers 4 Functions Alarm Text 4 Group4 xParameter 4 Group2 xParameter Refer to Section 4 2 6 10 5 Logic Reset 5 Functions 4 LED1 xLogic Reset xFunctions 3 LED xLED1 xLED3 4 LED3 xLogic Reset xFunctions 2 LED xLED xVirtual LED ...

Page 193: ...ions 4 IND2 xReset xFunctions Operate ENTER Y CANCEL N 1 Test xSwitch xBinary O P xLogic circuit xSim fault 2 Switch A M F 1 _ Off On CLPTST 0 Off S0 S3 COM1 0 Off On SCOM12 0 Off On 2 Binary O P TP1 0 _ Disable Enable FAIL 0 Disable Enable Refer to Section 4 2 7 2 Logic circuit TermA 1 _ TermB 48 _ ...

Page 194: ... ON 1 RECORD 1 FAULT RECORD 2 EVENT RECORD 2 STATUS 1 METERING 2 BINARY INPUT OUPUT 3 RELAY ELELMENT 4 TIME SYNC SOURCE 5 CLOCK ADJUSTMENT 3 SETTING VIEW 1 RELAY VERSION 2 DESCRIPTION 3 COMMUNICATION 4 RECORD 5 STATUS 6 PROTECTION 7 BINARY INPUT 8 BINARY OUTPUT 9 LED 5 TEST 1 SWITCH 2 BINARY OUTPUT 1 PRESS ARROW KEY TO MOVE TO EACH DISPLAYED ITEMS 2 PRESS END KEY TO BACK TO PREVIOUS SCREEN LATEST ...

Page 195: ... 194 6 F 2 S 0 8 2 8 ...

Page 196: ... 195 6 F 2 S 0 8 2 8 Appendix E Case Outline ...

Page 197: ... ENTER 2 4 9 Panel cut out 56 102 4 holes φ5 5 2 3 9 4 holes φ4 5 TB3 Rear view E TB1 TB2 TB4 Terminal block TB3 A1 B1 A18 B18 TB1 TB2 TB3 Screw terminal M3 5 Ring TB4 Screw terminal TB4 is provided only for RS485 two ports model 1 2 3 4 5 6 TB1 TB2 A1 B1 A10 B10 7 8 A1 A3 TB4 B1 B3 A B 0V TX RX Case Outline of GRL150 ...

Page 198: ...ormer EB 110 Option 4 holes for M6 screw for mounting M4 screw M5 screw 106 207 62 26 2 66 7 19 13 1 U V E v u 152 4 170 190 10 18 8 130 8 8 84 8 67 8 Outline Dimensions External Connections TB2 TB1 u v U V E Pilot wire side High voltage side Relay side ...

Page 199: ... 198 6 F 2 S 0 8 2 8 ...

Page 200: ... 199 6 F 2 S 0 8 2 8 Appendix F Typical External Connections ...

Page 201: ... A A1 A3 B3 RS485 I F for IEC60870 5 103 Dual port model only option COM2 0V B1 B2 TB3 B1 B2 Pilot wire Interface Optical Interface 2 For telecommunication 1 This connection is connected by wire link before shipment 2 Model 100 is not provided with Optical interface 3 Model 100 is not provided with IRIG port IRIG 3 P B1 BI1 B2 BI2 B3 BI3 A2 A3 B4 BI4 A4 B5 BI5 A5 TB2 A1 N BI1 COMMAND BI2 COMMAND B...

Page 202: ... B COM2 A A1 A3 B3 RS485 I F for IEC60870 5 103 Dual port model only option COM2 0V B1 B2 TB3 B1 B2 Pilot wire Interface Optical Interface 2 For telecommunication 1 This connection is connected by wire link before shipment 2 Model 110 is not provided with Optical interface 3 Model 110 is not provided with IRIG port IRIG 3 P B1 BI1 B2 BI2 B3 BI3 A2 A3 B4 BI4 A4 B5 BI5 A5 TB2 A1 N BI1 COMMAND BI2 CO...

Page 203: ...4 A2 COM2 B COM2 A A1 A3 B3 RS485 I F for IEC60870 5 103 Dual port model only option COM2 0V B1 B2 TB3 B1 B2 Pilot wire Interface Optical Interface 2 For telecommunication IRIG 3 1 This connection is connected by wire link before shipment 2 Model 120 is not provided with Optical interface 3 Model 120 is not provided with IRIG port P B1 BI1 B2 BI2 B3 BI3 A2 A3 B4 BI4 A4 B5 BI5 A5 TB2 A1 N BI1 COMMA...

Page 204: ... 203 6 F 2 S 0 8 2 8 Appendix G Relay Setting Sheet 1 Relay Identification 2 Line parameter 3 Binary output setting 4 Relay setting 5 Disturbance record signal setting 6 LED setting ...

Page 205: ... 00 10 00 0 20 BO2 OR AND Ins Dl Dw Lat In 1 0 500 OR Del In 1 348 GEN TRIP In 1 In 2 0 500 In 2 0 In 2 In 3 0 500 In 3 0 In 3 In 4 0 500 In 4 0 In 4 Timer 0 00 10 00 0 20 BO3 OR AND Ins Dl Dw Lat In 1 0 500 OR Del In 1 256 DIF_TRIP In 1 In 2 0 500 In 2 0 In 2 In 3 0 500 In 3 0 In 3 In 4 0 500 In 4 0 In 4 Timer 0 00 10 00 0 20 BO4 OR AND Ins Dl Dw Lat In 1 0 500 OR Del In 1 256 DIF_TRIP In 1 In 2 ...

Page 206: ...e Curve Type if MSE1 US CO2 CO2 37 SE1R DEF DEP SEF1 Reset Characteristic if MSEI IEEE orUS DEF DEF 37 SE1S2 Off On SEF1 Stage 2 Timer Enable if MSE1EN On Off Off 38 SE2EN Off On SEF2 Enable Off Off 39 SE3EN Off On SEF3 Enable Off Off 40 SE4EN Off On SEF4 Enable Off Off 41 UC UC1EN Off On UC1 Enable Off 42 UC2EN Off On UC2 Enable Off 43 Thermal THMEN Off On Thermal OL Enable Off 44 THMAEN Off On T...

Page 207: ...to 0 00 0 00 0 00 0 00 108 UC UC1 0 5 10 0 0 10 2 00 A UC1 Threshold setting if UC1EN On 1 0 0 20 109 TUC1 0 00 300 00 s UC1 Definite time setting if UC1EN On 1 00 110 UC2 0 5 10 0 0 10 2 00 A UC2 Threshold setting if UC2EN On 2 0 0 40 111 TUC2 0 00 300 00 s UC2 Definite time setting if UC2EN On 1 00 112 Thermal THM 2 0 10 0 0 40 2 00 A Thermal overload setting if OLTEN On 5 0 1 00 113 THMIP 0 0 5...

Page 208: ...ecord binarysignal 12 ditto 31 SIG13 0 3071 Disturbance record binarysignal 13 ditto 32 SIG14 0 3071 Disturbance record binarysignal 14 ditto 33 SIG15 0 3071 Disturbance record binarysignal 15 ditto 34 SIG16 0 3071 Disturbance record binarysignal 16 ditto 35 SIG17 0 3071 Disturbance record binarysignal 17 ditto 36 SIG18 0 3071 Disturbance record binarysignal 18 ditto 37 SIG19 0 3071 Disturbance re...

Page 209: ...ff delay 0 00 87 BI7SNS Norm Inv BinaryInput Sense Norm 88 BI8 BI8PUD 0 00 300 00 s BinaryInput Pick up delay 0 00 89 BI8DOD 0 00 300 00 s BinaryInput Drop off delay 0 00 90 BI8SNS Norm Inv BinaryInput Sense Norm 91 Alarm1Text Specifiedbyuser Alarm1 Text ALARM1 92 Alarm2Text Specifiedbyuser Alarm2 Text ALARM2 93 Alarm3Text Specifiedbyuser Alarm3 Text ALARM3 94 Alarm4Text Specifiedbyuser Alarm4 Tex...

Page 210: ...FAIL IND RESET X 535 BI8 COM T X PROT BLOCK DIF BLOCK TR1 BLOCK TR2 BLOCK OC1 BLOCK OC2 BLOCK OC3 BLOCK OC4 BLOCK EF1 BLOCK EF2 BLOCK EF3 BLOCK EF4 BLOCK SEF1 BLOCK SEF2 BLOCK SEF3 BLOCK SEF4 BLOCK UC1 BLOCK UC2 BLOCK CBF BLOCK THM BLOCK THMA BLOCK BCD BLOCK DIF A FS X 264 DIFFS OP X DIF B FS X 264 DIFFS OP X DIF C FS X 264 DIFFS OP X R DATA ZERO EXT TRIP A EXT TRIP B EXT TRIP C EXT TRIP CBF INIT ...

Page 211: ... OC4 INST TP 1624 EF1 INST TP 1625 EF2 INST TP 1626 EF3 INST TP 1627 EF4 INST TP 1628 SEF1 INST TP 1629 SEF2 INST TP 1630 SEF3 INST TP 1631 SEF4 INST TP 1632 UC1 INST TP 1633 UC2 INST TP 1634 1635 1636 1637 1638 1639 1640 1641 1642 1643 1644 1645 1646 1647 1648 TR1 R1 1649 TR2 R1 1650 L TEST R1 X 1104 SUB COM1 R1 X 1651 I LINK R1 X 1092 COM5 R1 X 1652 1653 1654 1655 1656 1657 1658 1659 1660 1661 1...

Page 212: ...679 1680 DIF A IC BLK X 373 ICD 1099 COM4 R1 UF X 1681 DIF B IC BLK X 373 ICD 1099 COM4 R1 UF X 1682 DIF C IC BLK X 373 ICD 1099 COM4 R1 UF X 1683 OC IC BLK X 373 ICD X 1684 1685 1686 1687 1688 1689 1690 1691 1692 1693 1694 1695 1696 1697 1698 1699 1700 1701 1702 1703 1704 1705 1706 1707 1708 1709 1710 1711 1712 1713 1714 1715 1716 1717 1718 1719 1720 1721 1722 1723 1724 1725 1726 1727 1728 1729 1...

Page 213: ...2053 2054 2055 2056 SUB_COM1 S X 390 LOCAL_TEST X 2057 SUB_COM2 S 2058 SUB_COM3 S 2059 SUB_COM4 S 2060 SUB_COM5 S 2061 2062 2063 2064 SUB2_COM1 S 2065 SUB2_COM2 S 2066 SUB2_COM3 S 2067 SUB2_COM4 S 2068 SUB2_COM5 S 2069 SUB2_COM6 S 2070 SUB2_COM7 S 2071 SUB2_COM8 S 2072 SUB2_COM9 S 2073 SUB2_COM10 S 2074 SUB2_COM11 S 2075 SUB2_COM12 S 2076 2077 2078 2079 2080 2081 2082 2083 2084 2085 2086 2087 2088...

Page 214: ...53 2554 2555 2556 2557 2558 2559 2560 TP1 X 348 GEN TRIP X 2561 TP2 X 348 GEN TRIP X 2562 2563 2564 2565 2566 2567 2568 2569 2570 2571 2572 2573 2574 2575 2576 2577 2578 2579 2580 2581 2582 2583 2584 2585 2586 2587 2588 2589 2590 2591 2592 2593 2594 2595 2596 2597 2598 2599 2600 2601 2602 2603 2604 2605 2606 2607 2608 2609 2610 2611 2612 2613 2614 2615 2616 2617 2618 2619 2620 None Signal Turn All...

Page 215: ... 2636 2637 2638 2639 2640 SET GROUP1 2641 SET GROUP2 2642 SET GROUP3 2643 SET GROUP4 2644 2645 2646 2647 2648 SYNC_CLOCK 2649 2650 2651 2652 ALARM1 2653 ALARM2 2654 ALARM3 2655 ALARM4 2656 CON_TPMD1 2657 CON_TPMD2 2658 CON_TPMD3 2659 CON_TPMD4 2660 CON_TPMD5 2661 CON_TPMD6 2662 CON_TPMD7 2663 CON_TPMD8 2664 2665 2666 2667 2668 2669 2670 2671 2672 2673 2674 2675 2676 2677 2678 2679 2680 2681 2682 2...

Page 216: ... 2831 TEMP016 2832 TEMP017 2833 TEMP018 2834 TEMP019 2835 TEMP020 2836 TEMP021 2837 TEMP022 2838 TEMP023 2839 TEMP024 2840 TEMP025 2841 TEMP026 2842 TEMP027 2843 TEMP028 2844 TEMP029 2845 TEMP030 2846 TEMP031 2847 TEMP032 2848 TEMP033 2849 TEMP034 2850 TEMP035 2851 TEMP036 2852 TEMP037 2853 TEMP038 2854 TEMP039 2855 TEMP040 2856 TEMP041 2857 TEMP042 2858 TEMP043 2859 TEMP044 2860 TEMP045 2861 TEMP...

Page 217: ...1 2897 TEMP082 2898 TEMP083 2899 TEMP084 2900 TEMP085 2901 TEMP086 2902 TEMP087 2903 TEMP088 2904 TEMP089 2905 TEMP090 2906 TEMP091 2907 TEMP092 2908 TEMP093 2909 TEMP094 2910 TEMP095 2911 TEMP096 2912 TEMP097 2913 TEMP098 2914 TEMP099 2915 TEMP100 2916 TEMP101 2917 TEMP102 2918 TEMP103 2919 TEMP104 2920 TEMP105 2921 TEMP106 2922 TEMP107 2923 TEMP108 2924 TEMP109 2925 TEMP110 2926 TEMP111 2927 TEM...

Page 218: ...1 2967 TEMP152 2968 TEMP153 2969 TEMP154 2970 TEMP155 2971 TEMP156 2972 TEMP157 2973 TEMP158 2974 TEMP159 2975 TEMP160 2976 TEMP161 2977 TEMP162 2978 TEMP163 2979 TEMP164 2980 TEMP165 2981 TEMP166 2982 TEMP167 2983 TEMP168 2984 TEMP169 2985 TEMP170 2986 TEMP171 2987 TEMP172 2988 TEMP173 2989 TEMP174 2990 TEMP175 2991 TEMP176 2992 TEMP177 2993 TEMP178 2994 TEMP179 2995 TEMP180 2996 TEMP181 2997 TEM...

Page 219: ...4 3030 TEMP215 3031 TEMP216 3032 TEMP217 3033 TEMP218 3034 TEMP219 3035 TEMP220 3036 TEMP221 3037 TEMP222 3038 TEMP223 3039 TEMP224 3040 TEMP225 3041 TEMP226 3042 TEMP227 3043 TEMP228 3044 TEMP229 3045 TEMP230 3046 TEMP231 3047 TEMP232 3048 TEMP233 3049 TEMP234 3050 TEMP235 3051 TEMP236 3052 TEMP237 3053 TEMP238 3054 TEMP239 3055 TEMP240 3056 TEMP241 3057 TEMP242 3058 TEMP243 3059 TEMP244 3060 TEM...

Page 220: ...EV27 0 3071 ditto 343 INTER_TRIP2 On Off 28 EV28 0 3071 ditto 0 On Off 29 EV29 0 3071 ditto 0 On Off 30 EV30 0 3071 ditto 0 On Off 31 EV31 0 3071 ditto 0 On Off 32 EV32 0 3071 ditto 0 On Off 33 EV33 0 3071 ditto 48 DIF A On Off 34 EV34 0 3071 ditto 49 DIF B On Off 35 EV35 0 3071 ditto 50 DIF C On Off 36 EV36 0 3071 ditto 368 CLP_STATE0 On Off 37 EV37 0 3071 ditto 369 CLP_STATE1 On Off 38 EV38 0 30...

Page 221: ... Off 92 EV92 0 3071 ditto 0 On Off 93 EV93 0 3071 ditto 0 On Off 94 EV94 0 3071 ditto 0 On Off 95 EV95 0 3071 ditto 0 On Off 96 EV96 0 3071 ditto 0 On Off 97 EV97 0 3071 ditto 0 On Off 98 EV98 0 3071 ditto 0 On Off 99 EV99 0 3071 ditto 0 On Off 100 EV100 0 3071 ditto 0 On Off 101 EV101 0 3071 ditto 1024 SET GROUP1 On 102 EV102 0 3071 ditto 1025 SET GROUP2 On 103 EV103 0 3071 ditto 1026 SET GROUP3 ...

Page 222: ...3 0 3071 ditto 0 NA 14 SIG14 0 3071 ditto 0 NA 15 SIG15 0 3071 ditto 0 NA 16 SIG16 0 3071 ditto 348 GEN TRIP 17 SIG17 0 3071 ditto 0 NA 18 SIG18 0 3071 ditto 0 NA 19 SIG19 0 3071 ditto 0 NA 20 SIG20 0 3071 ditto 0 NA 21 SIG21 0 3071 ditto 0 NA 22 SIG22 0 3071 ditto 0 NA 23 SIG23 0 3071 ditto 512 BI1_COMMAND 24 SIG24 0 3071 ditto 513 BI2_COMMAND 25 SIG25 0 3071 ditto 514 BI3_COMMAND 26 SIG26 0 3071...

Page 223: ... 222 6 F 2 S 0 8 2 8 ...

Page 224: ... output circuit check 3 3 AC input circuit check 4 Function test 4 1 Phase current differential element DIF test 4 2 Inverse definite minimum time overcurrent element IDMT OC EF and SEF test 4 3 Thermal overload element 4 4 CBF and UC element test 4 5 BCD element check 4 6 Cold load function check 5 Protection scheme test 6 Metering and recording check 7 Conjunctive test ...

Page 225: ... scheme Witness Active settings group number 2 Preliminary check Ratings CT shorting contacts DC power supply Power up Wiring Relay inoperative alarm contact Calendar and clock 3 Hardware check 3 1 User interface check 3 2 Binary input Binary output circuit check Binary input circuit Binary output circuit 3 3 AC input circuit ...

Page 226: ...p setting I Measured current I2 Tap Tap 20 Tap 4 2 Inverse definite minimum time overcurrent element IDMT OC EF and SEF test Element Test current Measured operating time OC 1 2 Is 20 Is EF 1 2 Is 20 Is SEF 1 2 Is 20 Is 4 3 Thermal overload element test Element Test current Measured operating time THM A 1 2 Is THM T 10 Is 4 4 CBF and UC element test Element Tap setting I Measured current CBF UC ...

Page 227: ... 0 8 2 8 4 5 BCD element check 4 6 Cold load function check 5 Protection scheme test Scheme Results 6 Metering and recording check 7 Conjunctive test Scheme Results On load check Signaling circuit Tripping circuit ...

Page 228: ... 227 6 F 2 S 0 8 2 8 Appendix I Return Repair Form ...

Page 229: ...GRL150 Model Example Type GRL150 Model 110A 22 10 Product No Serial No Date 1 Why the relay is being returned mal operation does not operate increased error investigation others 2 Fault records event records or disturbance records stored in the relay and relay settings are very helpful information to investigate the incident Please inform us of this information in respect to in the incident on a F...

Page 230: ...onth Year Time Example 04 Nov 2004 15 09 58 442 Faulty phase Prefault values Ia A IaR A Ib A IbR A Ic A IcR A Ie A Ida A I1 A Idb A I2 A Idc A I0 A I2 I1 Fault values Ia A IaR A Ib A IbR A Ic A IcR A Ie A Ida A I1 A Idb A I2 A Idc A I0 A THM ...

Page 231: ...he time of the incident 4 Please write the detail of the incident 5 Date of the incident occurred Day Month Year Example 10 Nov 2004 6 Please write any comments on the GRL150 including the document Customer Name Company Name Address Telephone No Facsimile No Signature ...

Page 232: ... 231 6 F 2 S 0 8 2 8 Appendix J Technical Data ...

Page 233: ... 0 5W per input at 110Vdc Phase segregated current differential protection DIFI1 Small current region 0 10 to 2 00A in 0 01A steps 1A rating 0 50 to 10 00A in 0 01A steps 5A rating DIFI2 Large current region 0 2 to 24 0A in 0 1A steps 1A rating 1 0 to 120 0A in 0 1A steps 5A rating Operating time less than 35ms at 300 of DIFI1 Phase Overcurrent Protection P F 1st and 2nd Overcurrent thresholds OFF...

Page 234: ...S 0 010 1 500 in 0 001 steps Reset Type Definite Time or Dependent Time Reset Definite Delay 0 00 300 00s in 0 01s steps RTMS 0 010 1 500 in 0 001 steps Phase Undercurrent Protection Undercurrent 1st 2nd thresholds OFF 0 10 2 00A in 0 01A steps 1A rating OFF 0 5 10 0A in 0 1A steps 5A rating DTL Delay 0 00 300 00s in 0 01A steps Inrush Current Detector Second harmonic ratio setting I2f I1f Overcur...

Page 235: ...870 5 103 Communication port remote PC Fibre Optic for IEC60870 5 103 Cable type Graded index multi mode 50 125 or 62 5 125μm fibre Connector ST Transmission rate 9 6 19 2kbps for IEC60870 5 103 Time synchronization port Connection Time code IRIG B AM modulated TTL Screw terminals Binary Inputs Number of inputs 8 Operating voltage Typical 74Vdc min 70Vdc for 110 125Vdc rating Typical 138Vdc min 12...

Page 236: ...d to all ports in differential mode Electrostatic Discharge IEC60255 22 2 Class 3 IEC61000 4 2 EN61000 4 2 6kV contact discharge 8kV air discharge Radiated RF Electromagnetic Disturbance IEC60255 22 3 Class 3 IEC61000 4 3 EN61000 4 3 Field strength 10V m for frequency sweeps of 80MHz to 1GHz and 1 7GHz to 2 2GHz Additional spot tests at 80 160 450 900 and 1890MHz Fast Transient Disturbance IEC6025...

Page 237: ... 89 336 EEC Compliance with the European Commission Electromagnetic Compatibility Directive is demonstrated according to EN 61000 6 2 and EN 61000 6 4 73 23 EEC Compliance with the European Commission Low Voltage Directive is demonstrated according to EN 50178 and EN 60255 5 ...

Page 238: ... 237 6 F 2 S 0 8 2 8 Appendix K Symbols Used in Scheme Logic ...

Page 239: ...on Signal No Signal name Marked with Scheme switch Marked with Scheme switch position Unmarked Internal scheme logic signal AND gates A B C Output 1 1 1 1 Other cases 0 A B C Output 1 1 0 1 Other cases 0 A B C Output 1 0 0 1 Other cases 0 OR gates A B C Output 0 0 0 0 Other cases 1 A B C Output 0 0 1 0 Other cases 1 A B C Output 0 1 1 0 Other cases 1 A Output B C A Output B 1 C A Output B C A Outp...

Page 240: ... with variable setting XXX YYY Setting range Delayed drop off timer with variable setting XXX YYY Setting range One shot timer XXX YYY Setting range Flip flop S R Output 0 0 No change 1 0 1 0 1 0 1 1 0 Scheme switch A Switch Output 1 ON 1 Other cases 0 Switch Output ON 1 OFF 0 0 t XXX t 0 XXX 0 t XXX YYY XXX YYY t 0 Output Output ON ON A S Output F F R Output A 1 XXX YYY A Output A Output ...

Page 241: ... 240 6 F 2 S 0 8 2 8 ...

Page 242: ... 241 6 F 2 S 0 8 2 8 Appendix L Inverse Time Characteristics ...

Page 243: ... 1 5 0 1 1 10 100 1 10 100 Current Multiple of Setting Operating Time s 1 0 5 0 1 0 2 1 5 TMS IEC UK Inverse Curves VI Time Multiplier TMS 0 1 1 5 0 01 0 1 1 10 100 1 10 100 Current Multiple of Setting Operating Time s 1 0 0 5 0 2 0 1 1 5 TMS Normal Inverse Very Inverse ...

Page 244: ...1 0 1 1 10 100 1000 1 10 100 Current Multiple of Setting Operating Time s 1 0 0 5 0 2 0 1 1 5 TMS UK Inverse Curves LTI Time Multiplier TMS 0 1 1 5 0 1 1 10 100 1000 1 10 100 Current Multiple of Setting Operating Time s 1 0 0 2 0 5 0 1 1 5 TMS Extremely Inverse Long Time Inverse ...

Page 245: ...0 01 0 1 1 10 100 1 10 100 Current Multiple of Setting Operating Time s 1 5 1 0 0 5 0 2 0 1 TMS IEEE Inverse Curves VI Time Multiplier TMS 0 1 1 5 0 01 0 1 1 10 100 1 10 100 Current Multiple of Setting Operating Time s 1 5 1 0 0 5 0 2 0 1 TM Moderately Inverse Very Inverse ...

Page 246: ... 245 6 F 2 S 0 8 2 8 IEEE Inverse Curves EI Time Multiplier TMS 0 1 1 5 0 01 0 1 1 10 100 1 10 100 Current Multiple of Setting Operating Time s 1 5 1 0 0 5 0 2 0 1 TMS Extremely Inverse ...

Page 247: ...0 01 0 1 1 10 100 1 10 100 Current Multiple of Setting Operating Time s 1 5 1 0 0 5 0 2 0 1 TMS US Inverse Curves CO2 Time Multiplier TMS 0 1 1 5 0 01 0 1 1 10 1 10 100 Current Multiple of Setting Operating Time s 1 5 1 0 0 5 0 2 0 1 TMS CO8 Inverse CO2 Short Time Inverse ...

Page 248: ... 247 6 F 2 S 0 8 2 8 Appendix M IEC60870 5 103 Interoperability ...

Page 249: ...n IEC103 Configurator IEC60870 5 103 Interoperability 1 Physical Layer 1 1 Electrical interface EIA RS 485 Number of loads 32 for one protection equipment 1 2 Optical interface Glass fibre option ST type connector option 1 3 Transmission speed User setting 9600 or 19200 bit s 2 Application Layer COMMON ADDRESS of ASDU One COMMON ADDRESS OF ASDU identical with station address 3 List of Information ...

Page 250: ... relay using a Class 2 poll The rate at which the relay produces new measured values can be customized 3 1 4 Commands The supported commands can be customized The relay will respond to non supported commands with a cause of transmission COT of negative acknowledgement of a command For details refer to the standard IEC60870 5 103 section 7 4 4 3 1 5 Test mode In test mode both spontaneous messages ...

Page 251: ...ter Setting When a setting change has done at the local the event is sent to control system Not supported 23 Characteristic1 Setting group 1 active GI 1 1 9 11 12 192 1024 1 2 24 Characteristic2 Setting group 2 active GI 1 1 9 11 12 192 125 1 2 25 Characteristic3 Setting group 3 active GI 1 1 9 11 12 192 1026 1 2 26 Characteristic4 Setting group 4 active GI 1 1 9 11 12 192 1027 1 2 27 Auxiliary in...

Page 252: ...supported 76 Teleprotection Signal transmitted Carrier signal sending Not supported 77 Teleprotection Signal received Carrier signal receiving Not supported 78 Zone1 Zone 1 trip Not supported 79 Zone2 Zone 2 trip Not supported 80 Zone3 Zone 3 trip Not supported 81 Zone4 Zone 4 trip Not supported 82 Zone5 Zone 5 trip Not supported 83 Zone6 Zone 6 trip Not supported 84 General Start Pick up Any elem...

Page 253: ... 2 7 192 9 Generic Function 240 Read Headings Not supported 241 Read attributes of all entries of a group Not supported 243 Read directory of entry Not supported 244 Real attribute of entry Not supported 245 End of GGI Not supported 249 Write entry with confirm Not supported 250 Write entry with execute Not supported 251 Write entry aborted Not supported Details of MEA settings in IEC103 configura...

Page 254: ...0 192 26 Activate characteristic 4 Setting Group 4 ON 20 20 192 Generic functions 240 Read headings of all defined groups Not supported 241 Read values or attributes of all entries of one group Not supported 243 Read directory of a single entry Not supported 244 Read values or attributes of a single entry Not supported 245 General Interrogation of generic data Not supported 248 Write entry Not sup...

Page 255: ...1 Ia Configurable Current L2 Ib Configurable Current L3 Ic Configurable Voltage L1 E Va No Voltage L2 E Vb No Voltage L3 E Vc No Active power P P No Reactive power Q Q No Frequency f f No Voltage L1 L2 Vab No Details of Common settings in IEC103 configurator Remote operation valid time ms 4000 Local operation valid time ms 4000 Measurand period s 2 Function type of System functions 192 Signal No o...

Page 256: ...f transmission COT Cause of Transmission refer to IEC60870 5 103 section 7 2 3 1 spontaneous 2 cyclic 3 reset frame count bit FCB 4 reset communication unit CU 5 start restart 6 power on 7 test mode 8 time synchronization 9 general interrogation 10 termination of general interrogation 11 local operation 12 remote operation 20 positive acknowledgement of command 21 negative acknowledgement of comma...

Page 257: ...ows First draft _01 csv Second draft _02 csv Third draft _03 csv Revision number The name is recommended to be able to discriminate the relay type such as GRZ100 or GRL100 etc The setting files remark field of IEC103 is able to enter up to 12 one byte characters It is utilized for control of IEC103 setting data 2 Saving theIEC103 setting data The IEC103 setting data is recommended to be saved in e...

Page 258: ...nnection of optical cable The setting of converter is incorrect RS485 optic conversion is executed with the transmission channel etc Converter In the event of using G1IF2 change the DIPSW setting in reference to INSTRUCTION MANUAL 6F2S0794 The relationship between logical 0 1 of the signal and Sig on off is incorrect In the event of using optical cable BCU Check the following Logical0 Sig on Logic...

Page 259: ...on Type FUN between the relay and SAS The relay is not initialised after writing IEC103 configurator setting RY Check the sum value of IEC103 setting data from the LCD screen When differing from the sum value on IEC103 configurator initialise the relay 2 HMI does not display IEC103 event on the SAS side It changes to the block mode RY Change the IECBR settling to Normal BCU does not transmit the f...

Page 260: ... 259 6 F 2 S 0 8 2 8 Appendix N Resistor Box Option ...

Page 261: ...cation signals in a multi core pilot wire cable Specification 5kVac for 1 min between all terminals and DIN rail Outline and Mounting Outline 52 8 89 6 U1 U2 U3 U4 U5 U6 W1 W2 W3 62 45 26 3 48 58 Mounting DIN rail 35 mm Note DIN rail is not supplied User prepares DIN rail Connection terminal M3 screw Maximum wire size 2 1mm 14AWG for solid wire or 3 3mm 12AWG for stranded wire ...

Page 262: ...R5 150Ω RESISTOR BOX G1RE1 External connection The transmission level of GRL150 can be adjusted by selecting a terminal among U1 to U4 Pilot wire GRL150 TB3 A16 A17 U1 4 U5 W1 W2 U6 W3 G1RE1 GRL150 TB3 A16 A17 U1 4 U5 W1 W2 U6 W3 G1RE1 Note If U5 and W2 selected the transmission level of GRL150 is not reduced ...

Page 263: ... 262 6 F 2 S 0 8 2 8 ...

Page 264: ... 263 6 F 2 S 0 8 2 8 Appendix O Ordering ...

Page 265: ...5Vdc 2 5A 50Hz 110 125Vdc 3 5A 60Hz 110 125Vdc 4 1A 50Hz 220 250Vdc 5 1A 60Hz 220 250Vdc 6 5A 50Hz 220 250Vdc 7 5A 60Hz 220 250Vdc 8 1A 50Hz 48 54 60Vdc A 1A 60Hz 48 54 60Vdc B 5A 50Hz 48 54 60Vdc C 5A 60Hz 48 54 60Vdc D 1A 50Hz 24 30Vdc E 1A 60Hz 24 30Vdc F 5A 50Hz 24 30Vdc G 5A 60Hz 24 30Vdc H Rear communication port RS485 1 Fibre Optic 2 Dual RS485 3 RS485 Fibre Optic 9 Miscellaneous None 0 LED...

Page 266: ... 2 1 Modified LCD sample screens Modified Appendix B E and G 0 5 Jun 22 2006 4 2 3 1 4 2 4 1 4 2 6 6 Appendices Added the description and Note Modified the description and LCD sample screens in Setting the metering Modified Appendix N 0 6 Jul 19 2006 2 2 9 Modified the description of the CT Ratio matching Corrected figure number Figure 2 4 14 1 2 2 9 1 Figure 2 4 14 2 2 2 9 2 0 7 Sep 11 2006 2 2 2...

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