background image

155

High speed binary output logic (HSBO)

Chapter 10

Logic

2.4

Logic diagram

Figure 78:

High speed binary output, simplified logic diagram

99000548.vsd

ZC1P-CRLn

ZC1P-CRMPH

ZCOM-CR

BIx

BIy

BIz

....

....

IOxx

HSBO-
ZC1PCACCLn

HSBO-CRLn

HSBO-CRMPH

HSBO-
BLKZCTR

HSBO-CR

HSBO-
ZCOMCACC

HSBO-
TRIPPSLn

HSBO-TRLn

HSBO-HSTRLn

HSBO-
BLKHSTR

HSBO-HSCSLn

HSBO-
HSCSMPH

HSBO-CSLn

HSBO-CSMPH

HSBO

ZC1P

ZC1P-CACCLn

ZCOM-CACC

TRIP-PSLn

TRIP

ZCOM

HS-TRLn

HS-CSLn

HS-CSMPH

HS

HSBO-
BLKHSCS

HSBO-ERROR

BIx

BIy

BIz

BOx

BOx

BOz

BOz

....

IOxx

BOy

BOz

Binary output contacts

Binary input contacts

Regular function

block in/out

'Internal' in/out

Fast Trip/CS

outputs configured

through settings:

IOMOD

TRmLnOUT

CSLnOUT

CSMPHOUT

&

TEST/BLOCK

TEST/BLOCK

&

TEST/BLOCK

&

Summary of Contents for REL 501-C1 2.5

Page 1: ...Technical reference manual Line distance protection terminal REL 501 C1 2 5 ...

Page 2: ......

Page 3: ... Copyright 2006 ABB All rights reserved Technical reference manual Line distance protection terminal REL 501 C1 2 5 About this manual Document No 1MRK 506 187 UEN Issued February 2006 Revision A ...

Page 4: ...ELOW THE DATA CONTAINED IN THIS MANUAL IS INTENDED SOLELY FOR THE CONCEPT OR PRODUCT DESCRIPTION AND IS NOT TO BE DEEMED TO BE A STATEMENT OF GUARAN TEED PROPERTIES IN THE INTERESTS OF OUR CUSTOMERS WE CONSTANTLY SEEK TO ENSURE THAT OUR PRODUCTS ARE DEVELOPED TO THE LATEST TECHNOLOGICAL STAN DARDS AS A RESULT IT IS POSSIBLE THAT THERE MAY BE SOME DIFFERENCES BETWEEN THE HW SW PRODUCT AND THIS INFO...

Page 5: ...rotection parameters 16 Calendar and clock 20 Technical data 21 Case dimensions 21 Weight 26 Unit 26 Power consumption 26 Environmental properties 26 Chapter 3 Common functions 31 Real time clock with external time synchronization TIME 32 Application 32 Function block 32 Input and output signals 32 Setting parameters 32 Technical data 33 Four parameter setting groups GRP 34 Application 34 Logic di...

Page 6: ... block TQ 48 Setting parameters 48 Exclusive OR function block XO 49 Set reset function block SR 49 Set reset with memory function block SM 50 Controllable gate function block GT 50 Setting parameters 51 Settable timer function block TS 51 Setting parameters 52 Technical data 52 Blocking of signals during test BST 53 Application 53 Function block 53 Input and output signals 53 Chapter 4 Line dista...

Page 7: ...C 77 Application 77 Functionality 77 Function block 79 Logic diagram 79 Input and output signals 83 Setting parameters 83 Technical data 86 Power swing detection PSD 87 Application 87 Functionality 87 Function block 88 Logic diagram 89 Input and output signals 90 Setting parameters 90 Technical data 91 Scheme communication logic ZCOM 93 Application 93 Functionality 93 Function block 93 Logic diagr...

Page 8: ...lication 112 Functionality 112 Function block 112 Logic diagram 113 Input and output signals 113 Setting parameters 114 Technical data 115 Scheme communication logic for residual overcurrent protection EFC 116 Application 116 Functionality 116 Function block 116 Logic diagram 117 Input and output signals 117 Setting parameters 118 Technical data 118 Current reversal and weak end infeed logic for r...

Page 9: ...32 Function block 132 Logic diagram 133 Input and output signals 133 Setting parameters 134 Technical data 134 Chapter 8 Secondary system supervision 135 Fuse failure supervision FUSE 136 Application 136 Functionality 136 Function block 136 Logic diagram 137 Input and output signals 138 Setting parameters 138 Technical data 138 Chapter 9 Control 139 Autorecloser AR 140 Application 140 Functionalit...

Page 10: ... parameters 160 Chapter 11 Monitoring 163 Disturbance report DRP 164 Application 164 Functionality 164 Function block 165 Input and output signals 166 Setting parameters 166 Technical data 168 Event recorder ER 169 Application 169 Design 169 Technical data 169 Trip value recorder TVR 170 Application 170 Design 170 Supervision of AC input quantities DA 171 Application 171 Functionality 171 Function...

Page 11: ...CM 195 Design SPA IEC 195 Design LON 196 Technical data 196 Chapter 13 Hardware modules 199 Modules 200 A D module ADM 201 Design 201 Transformer module TRM 202 Design 202 Technical data 202 Binary I O capabilities 203 Application 203 Technical data 203 Binary input module BIM 205 Application 205 Design 205 Function block 205 Input and output signals 205 Binary output module BOM 207 Application 20...

Page 12: ...11 Design 211 Serial communication modules SCM 213 SPA IEC 213 LON 213 Chapter 14 Diagrams 215 Terminal diagrams 216 Terminal diagram Rex5xx 216 Terminal diagram REL 501 C1 217 Chapter 15 Configuration 223 Configuration 224 ...

Page 13: ...1 About this chapter Chapter 1 Introduction Chapter 1 Introduction About this chapter This chapter introduces you to the manual as such ...

Page 14: ...s instructions on how to operate the protection terminal during normal service after commissioning and before periodic maintenance tests The opera tor s manual can be used to find out how to handle disturbances or how to view calculated and measured network data in order to determine the cause of a fault The Installation and Commissioning Manual ICM contains instructions on how to install and comm...

Page 15: ...e found in the signal list but described in the settings table Figure 1 Function block symbol example Logic diagram The description of the design is chiefly based on simplified logic diagrams which use IEC sym bols for the presentation of different functions conditions etc The functions are presented as a closed block with the most important internal logic circuits and configurable functional inpu...

Page 16: ...ctional input signals It is possible to configure them to functional output signals of other functions as well as to binary input terminals of the REx 5xx terminal Examples are TUV BLK TR TUV BLOCK and TUV VTSU Signals in frames with a shaded area on their right side present the logical setting signals Their values are high 1 only when the corresponding setting parameter is set to the symbolic val...

Page 17: ... Setting parameters The setting parameters table contains all available settings of the function block If a function consists of more than one block each block is listed in a separate table Table 3 Setting parameters for the time delayed undervoltage protection TUV TUV function Technical data The technical data specifies the terminal in general the functions and the hardware modules Signal Descrip...

Page 18: ...he handling electron ic equipment 1 4 Related documents 1 5 Revision notes 1 6 Acronyms and abbreviations Documents related to REL 501 C1 2 5 Identity number Operator s manual 1MRK 506 186 UEN Installation and commissioning manual 1MRK 506 188 UEN Technical reference manual 1MRK 506 187 UEN Application manual 1MRK 506 189 UEN Buyer s guide 1MRK 506 185 BEN Revision Description A First revision AC ...

Page 19: ...ule CIM Communication interface module CMPPS Combined Mega Pulses Per Second CO cycle Close Open cycle Co directional Way of transmitting G 703 over a balanced line Involves two twisted pairs making it possible to transmit information in both directions Contra directional Way of transmitting G 703 over a balanced line Involves four twisted pairs of with two are used for transmitting data in both d...

Page 20: ...h data and protection signals FOX 512 515 Access multiplexer FOX 6Plus Compact time division multiplexer for the transmission of up to seven duplex channels of digital data over optical fibers FPGA Field Programmable Gate Array FRRATED Rated system frequency FSMPL Physical channel number for frequency calculation G 703 Electrical and functional description for digital lines used by local tele phon...

Page 21: ...RGE Amount of compensated charging current IEC International Electrical Committee IEC 186A IEC 60044 6 IEC Standard Instrument transformers Part 6 Requirements for pro tective current transformers for transient performance IEC 60870 5 103 Communication standard for protective equipment A serial master slave protocol for point to point communication IEEE Institute of Electrical and Electronics Engi...

Page 22: ... Dust protected Protected against splashing water Equiva lent to NEMA type 12 Ip block Block of the function at high phase current in percentage of base IRVBLK Block of current reversal function IRV Activation of current reversal logic ITU International Telecommunications Union k2 Time multiplier in IDMT mode kForIEEE Time multiplier for IEEE inverse type curve LAN Local area network LIB 520 LCD L...

Page 23: ... Power supply module PST Parameter setting tool PT ratio Potential transformer or voltage transformer ratio PUTT Permissive underreach transfer trip R1A Source resistance A near end R1B Source resistance B far end RADSS Resource Allocation Decision Support System RASC Synchrocheck relay from COMBIFLEX range RCA Functionality characteristic angle REVAL Evaluation software RFPP Resistance of phase t...

Page 24: ...and before next shot tCBCLosedMin Minimum time that the circuit breaker must be closed before new sequence is permitted tExtended t1 Open time extended by this value if Extended t1 is true THL Thermal Overload Line cable THOL Thermal overload tInhibit Reset reclosing time for inhibit tPulse Pulse length for single command outputs TP Logic Pulse Timer tReporting Cycle time for reporting of counter ...

Page 25: ... signals V 36 Same as RS449 A generic connector specification that can be used to support RS422 and others VDC Volts Direct Current WEI Week end infeed logic VT Voltage transformer VTSZ Block of trip from weak end infeed logic by an open breaker X1A Source reactance A near end X1B Source reactance B far end X1L Positive sequence line reactance X 21 A digital signalling interface primarily used for...

Page 26: ...14 Introduction to the technical reference manual Chapter 1 Introduction ...

Page 27: ...15 About this chapter Chapter 2 General Chapter 2 General About this chapter This chapter describes the terminal in general ...

Page 28: ...ction 1 2 Basic protection parameters Path in local HMI Configuration AnalogInputs General Table 5 Setting parameters for Analog Inputs General Path in local HMI Configuration AnalogInputs TrafoinpModule Parameter Range Default Unit Description Station Name 0 16 Station Name char Identity name for the station Station No 0 99999 0 Identity number for the station Object Name 0 16 Object Name char Id...

Page 29: ...nsformer on input U4 U5r 10 000 500 000 Step 0 001 63 509 V Rated voltage of transformer on input U5 Setting can be done through the local HMI only The setting should normally not be changed by the user The setting is factory preset and depends on the selected transformer input module Parameter Range Default Unit Description U1b 30 000 500 000 Step 0 001 63 509 V Base voltage of input U1 U1Scale 1...

Page 30: ...er ratio input U5 Name_U5 0 13 U5 char User defined name of input U5 Parameter Range Default Unit Description Ir 0 1000 10 0000 Step 0 0001 1 0000 A Rated current of transformer mod ule I1r 0 1000 10 0000 Step 0 0001 1 0000 A Rated current of transformer on input I1 I2r 0 1000 10 0000 Step 0 0001 1 0000 A Rated current of transformer on input I2 I3r 0 1000 10 0000 Step 0 0001 1 0000 A Rated curren...

Page 31: ... 001 2000 000 Main current transformer ratio input I2 Name_I2 0 13 I2 char User defined name of input I2 I3b 0 1 10 0 Step 0 1 1 0 A Base current of input I3 I3Scale 1 000 40000 000 Step 0 001 2000 000 Main current transformer ratio input I3 Name_I3 0 13 I3 char User defined name of input I3 I4b 0 1 10 0 Step 0 1 1 0 A Base current of input I4 I4Scale 1 000 40000 000 Step 0 001 2000 000 Main curre...

Page 32: ..._I 0 13 I Char Name for analogue input I Name_P 0 13 P Char Name for analogue input P Name_Q 0 13 Q Char Name for analogue input Q Name_S 0 13 S Char Name for analogue input S Name_f 0 13 f Char Name for analogue input f Parameter Range Default Unit Description Parameter Range Built in calender With leap years through 2098 ...

Page 33: ...se without rear cover Figure 4 Case without rear cover with 19 rack mounting kit A B C D E xx02000646 vsd F G H J K xx02000647 vsd Case size A B C D E F G H J K 6U 1 2 x 19 265 9 223 7 204 1 252 9 205 7 190 5 203 7 186 6 The H and K dimensions are defined by the 19 rack mounting kit mm ...

Page 34: ... data Chapter 2 General Figure 5 Case with rear cover Figure 6 Case with rear cover and 19 rack mounting kit Figure 7 Rear cover case with details A B C D E F xx02000648 vsd J I H G K xx02000649 vsd xx02000650 vsd ...

Page 35: ...nsions are in millimeters Panel cut outs for REx 500 series single case Flush mounting Semi flush mounting Case size Cut out dimensions mm A 1 B 1 6U 1 2 x 19 210 1 254 3 C 4 10 mm D 16 5 mm E 187 6 mm without rear protection cover 228 6 mm with rear protection cover F 106 5 mm G 97 6 mm without rear protection cover 138 6 mm with rear protection cover A B C D E xx02000665 vsd F G xx02000666 vsd ...

Page 36: ...fasteners 2 with appropriate mounting details 4 and a sealing strip 5 for fastening to the IED 3 To receive IP54 class protection an additional sealing 1 must be ordered with the IED This sealing is factory mounted Figure 8 The flush mounting kit en04000451 vsd panel 2 4 1 3 5 ...

Page 37: ...25 Technical data Chapter 2 General Dimensions wall mounting Figure 9 Wall mounting 80 mm xx02000653 vsd E A B C D Screws M6 or corresponding en02000654 vsd ...

Page 38: ...aterial Steel sheet Front plate Steel sheet profile with cut out for HMI and for 18 LED when included Surface treatment Aluzink preplated steel Finish Light beige NCS 1704 Y15R Degree of protection Front side IP40 optional IP54 with sealing strip Rear side IP20 Size of terminal Typical value 1 2 of 19 rack 18 W Parameter Reference value Nominal range Influence Ambient temperature Operative range 2...

Page 39: ...s 1 MHz burst disturbance 2 5 kV IEC 60255 22 1 Class III Electrostatic discharge Direct application Air 8 kV Contact 6 kV IEC 60255 22 2 Class III Fast transient disturbance 4 kV IEC 60255 22 4 Class A Surge immunity test 1 2 kV 1 2 50μs high energy IEC 60255 22 5 Power frequency immunity test 150 300 V 50 Hz IEC 60255 22 7 Class A Power frequency magnetic field test 1000 A m 3s IEC 61000 4 8 Cla...

Page 40: ...ic field test 1000 A m 3 s IEC 61000 4 8 Class V Radiated electromagnetic field dis turbance 10 V m 80 1000 MHz IEC 60255 22 3 Radiated electromagnetic field dis turbance 10 V m 80 1000 MHz 1 4 2 0 GHz IEC 61000 4 3 Class III Radiated electromagnetic field dis turbance 35V m 26 1000 MHz IEEE ANSI C37 90 2 Conducted electromagnetic field disturbance 10 V 0 15 80 MHz IEC 60255 22 6 Radiated emission...

Page 41: ... Technical data Chapter 2 General Table 22 Mechanical tests Test Type test values Reference standards Vibration Class I IEC 60255 21 1 Shock and bump Class I IEC 60255 21 2 Seismic Class I IEC 60255 21 3 ...

Page 42: ...30 Technical data Chapter 2 General ...

Page 43: ...31 About this chapter Chapter 3 Common functions Chapter 3 Common functions About this chapter This chapter presents the common functions in the terminal ...

Page 44: ...een all terminals in a SA system possible 1 2 Function block 1 3 Input and output signals Table 23 Input signals for the TIME TIME function block Path in local HMI ServiceReport Functions Time Table 24 Output signals for the TIME TIME function block 1 4 Setting parameters Path in local HMI Configuration Time xx00000171 vsd TIME TIME MINSYNC SYNCSRC RTCERR SYNCERR Signal Description MINSYNC Minute ...

Page 45: ...on Parameter Range Default Unit Description SYNCSRC 0 5 0 Selects the time synchronization source 0 No source Internal real time clock is used without fine tuning 1 LON bus 2 SPA bus 3 IEC 60870 5 103 bus 4 Minute pulse positive flank 5 Minute pulse negative flank Function Accuracy Time tagging resolution 1 ms Time tagging error with synchronisation once 60 s 1 5 ms Time tagging error without sync...

Page 46: ...uman machine in terface or configurable binary inputs results in a highly adaptable terminal that can cope with a variety of system scenarios 2 2 Logic diagram Figure 10 Connection of the function to external circuits 2 3 Function block GRP ACTGRP1 GRP ACTGRP2 GRP ACTGRP3 GRP ACTGRP4 IOx Bly1 IOx Bly2 IOx Bly3 IOx Bly4 RL2 en01000144 vsd ACTIVATE GROUP 4 ACTIVATE GROUP 3 ACTIVATE GROUP 2 ACTIVATE ...

Page 47: ...up FuncOutputs Table 28 Output signals for the ACTIVEGROUP GRP function block Signal Description ACTGRP1 Selects setting group 1 as active ACTGRP2 Selects setting group 2 as active ACTGRP3 Selects setting group 3 as active ACTGRP4 Selects setting group 4 as active Signal Description GRP1 Setting group 1 is active GRP2 Setting group 2 is active GRP3 Setting group 3 is active GRP4 Setting group 4 is...

Page 48: ...or con figuration The HMI BLOCKSET functional input can be configured only to one of the available binary inputs of the terminal The terminal is delivered with the default configuration HMI BLOCK SET connected to NONE NOSIGNAL The configuration can be made from the local HMI only see the Installation and comissioning manual The function permits remote changes of settings and reconfiguration throug...

Page 49: ...ting restriction of HMI function SettingRestrict Block RESTRICT SETTINGS HMI BLOCKSET SW ITCH W ITH KEY REx 5xx en01000152 vsd Signal Description BLOCKSET Input signal to block setting and or configuration changes from the local HMI WARNING Read the instructions before use Default con figuration to NONE NOSIGNAL Parameter Range Default Unit Description SettingRestrict Open Block Open Open Setting ...

Page 50: ...d to create internal address mappings between modules and protections and other functions 4 2 Logic diagram Figure 12 Example of an I O configuration in the graphical tool CAP 531 for a REx 5xx with two BIMs IOP1 S11 S14 S15 S16 S17 S18 S13 S12 S19 S20 S21 S23 S22 I OPosition S24 S25 S26 S27 S28 S30 S32 S34 S36 IO01 IO02 I O module I O module POSITION ERROR BI1 BI6 POSITION ERROR BI1 BI6 en0100014...

Page 51: ... Input and output signals Table 31 Output signals for the I OPOSITION IOPn function block xx00000238 vsd IOP1 I OPOSITION S11 S12 S13 S14 S15 S16 S17 S18 S19 S20 S21 S22 S23 S24 S25 S26 S27 S28 S29 S30 S32 S33 S34 S35 S36 S37 S39 Signal Description Snn Slot position nn nn 11 39 ...

Page 52: ...MS or SCS to view the status of the self supervision function The self su pervision operates continuously and includes Normal micro processor watchdog function Checking of digitized measuring signals Checksum verification of PROM contents and all types of signal communication 5 2 Function block xx00000169 vsd INT INTERNSIGNALS FAIL WARNING CPUFAIL CPUWARN ADC SETCHGD ...

Page 53: ...ential free alarm contact Power supply fault Watchdog TX overflow Master resp Supply fault ReBoot I O Checksum fault Supply fault Parameter check Power supply module I O nodes A D conv module Main CPU Fault Fault Fault Fault INTERNAL FAIL I O nodes BIM BOM IOM PSM MIM or DCM DSP Digital Signal Processor xxxx Inverted signal 99000034 vsd ...

Page 54: ...r 1 1 INT ADC Send Rem Error OK OK 1 TIME RTCERR INT CPUWARN 1 TIME SYNCERR RTC WARNING INT CPUWARN INT WARNING Watchdog Check CRC RAM check DSP Modules 1 12 OK OK OK OK INT CPUFAIL Parameter check Watchdog Flow control OK OK OK 1 INT CPUFAIL INT ADC I O node FAIL INT FAIL Start up self test Fault Main CPU Remote terminal communication A D Converter Module RTC WARNING DIFL COMFAIL or RTC1 COMFAIL ...

Page 55: ... block 5 5 Technical data Table 33 Internal event list Signal Description FAIL Internal fail status WARNING Internal warning status CPUFAIL CPU module fail status CPUWARN CPU module warning status ADC A D converter error SETCHGD Setting changed Data Value Recording manner Continuous event controlled List size 40 events first in first out ...

Page 56: ...ed to create application specific functionality 6 2 Inverter function block INV The inverter function block INV has one input and one output where the output is in inverse ratio to the input Table 34 Input signals for the INV IVnn function block Path in local HMI ServiceReport Functions INV Table 35 Output signals for the INV IVnn function block 6 3 OR function block OR The OR function is used to ...

Page 57: ... inputs and one of the outputs are inverted Table 38 Input signals for the AND Annn function block Path in local HMI ServiceReport Functions AND1n Signal Description INPUT1 Input 1 to OR gate INPUT2 Input 2 to OR gate INPUT3 Input 3 to OR gate INPUT4 Input 4 to OR gate INPUT5 Input 5 to OR gate INPUT6 Input 6 to OR gate Signal Description OUT Output from OR gate NOUT Inverted output from OR gate S...

Page 58: ...s Table 42 Setting parameters for the Timer TMnn function 6 6 Timer long function block TL The function block TL timer with extended maximum time delay at pick up and at drop out is identical with the TM timer The difference is the longer time delay Signal Description OUT Output from AND gate NOUT Inverted output from AND gate Signal Description INPUT Input to timer T Time value See setting parame...

Page 59: ...f out puts The pulse timer TP has a settable length Table 46 Input signals for the TP TPnn function block Path in local HMI ServiceReport Functions Pulsen Signal Description INPUT Input to long timer T Time value See setting parameters Signal Description OFF Output from long timer drop out delayed ON Output from long timer pick up delayed xx00000162 vsd TL01 TIMERLONG INPUT T OFF ON Parameter Rang...

Page 60: ...erviceReport Functions pulseLongn Table 50 Output signals for the PULSELONG TQnn function block 6 8 1 Setting parameters Table 51 Setting parameters for the PulseLong TQnn function Signal Description OUT Output from pulse timer Parameter Range Default Unit Description T 0 000 60 000 Step 0 010 0 010 s Pulse length Can only be set from CAP configuration tool Signal Description INPUT Input to pulse ...

Page 61: ...able 53 Output signals for the XOR XOnn function block 6 10 Set reset function block SR The Set Reset SR function is a flip flop that can set or reset an output from two inputs respec tively Each SR function block has two outputs where one is inverted Table 54 Input signals for the SR SRnn function block Path in local HMI ServiceReport Functions SR Signal Description INPUT1 Input 1 to XOR gate INP...

Page 62: ...Mem1 FuncOutputs Table 57 Output signals for the SRM SMnn function block Path in local HMI Settings Function Groupn SRWithMem1 SRMem01 MemoryFunct Table 58 Setting parameters for the SRM SMnn function 6 12 Controllable gate function block GT The GT function block is used for controlling if a signal should be able to pass from the input to the output or not depending on a setting Signal Description...

Page 63: ... TS The function block TS timer has outputs for delayed input signal at drop out and at pick up The timer has a settable time delay It also has an Operation setting On Off that controls the opera tion of the timer Table 62 Input signals for the TS TSnn function block Path in local HMI ServiceReport Functions TimerSet1 FuncOutputs Signal Description INPUT Input to gate Signal Description Out Output...

Page 64: ...ayed OFF Output from timer drop out delayed Parameter Range Default Unit Description Operation Off On Off Operating mode for TSn function T 0 00 60 00 Step 0 01 0 00 s Delay for settable timer n Update rate Block Availability 10 ms AND 30 gates OR 60 gates INV 20 inverters SM 20 flip flops GT 5 gates TS 5 timers 200 ms SR 5 flip flops XOR 39 gates Block Availability Setting range Accuracy TM 10 ti...

Page 65: ... possible to see when a function is activated or trips It also enables the user to follow the operation of several related functions to check correct functionality and to check parts of the configuration etc 7 2 Function block 7 3 Input and output signals Table 67 Input signals for the Test TEST function block Path in local HMI ServiceReport Functions Test Table 68 Output signals for the Test TEST...

Page 66: ...54 Blocking of signals during test BST Chapter 3 Common functions ...

Page 67: ...55 About this chapter Chapter 4 Line distance Chapter 4 Line distance About this chapter This chapter describes the line impedance functions in the terminal ...

Page 68: ...ts in all kinds of networks regardless of the treatment of the neutral point Inde pendent setting of the reach in the reactive and the resistive direction for each zone separately makes it possible to create fast and selective short circuit protection in power systems Phase to earth distance protection serves as basic earth fault protection in networks with directly or low impedance earthed networ...

Page 69: ... and trip The additional distance protection zones four and five have the same basic functionality as zone one to three but lack the possibility of issuing phase selective output signals Distance protection zone five has shorter operating time than other zones but also higher tran sient overreach It should generally be used as a check zone together with the SOTF switch onto fault function or as a ...

Page 70: ...e for phase to phase and phase to earth faults are independent for each zone The operating characteristic is thus au tomatically adjusted to the line characteristic angle if the simplified operating characteristic has not been especially requested The earth return compensation factor for the earth fault measure ment is calculated automatically by the terminal itself Voltage polarization for direct...

Page 71: ...e measuring zone or only its tripping function by the operation of fuse failure function power swing detection function etc 1 3 Function block zone 1 3 Figure 17 ZM1 function block for single two and or three phase tripping Figure 18 ZM1 function block for three phase tripping Figure 19 ZM2 function block for single two and or three phase tripping xx00000173 vsd ZM1 ZM1 BLOCK BLKTR VTSZ STCND TRIP...

Page 72: ...re 22 ZM3 function block for three phase tripping 1 4 Function block zone 4 Figure 23 ZM4 function block xx00000703 vsd ZM2 ZM2 BLOCK BLKTR VTSZ STCND TRIP START STND xx00000175 vsd ZM3 ZM3 BLOCK BLKTR VTSZ STCND TRIP TRL1 TRL2 TRL3 START STL1 STL2 STL3 STND xx00000704 vsd ZM3 ZM3 BLOCK BLKTR VTSZ STCND TRIP START STND xx00000176 vsd ZM4 ZM4 BLOCK BLKTR VTSZ STCND TRIP START STND ...

Page 73: ...gic diagram Figure 25 Conditioning by a group functional input signal ZM1 STCND xx00000177 vsd ZM5 ZM5 BLOCK BLKTR VTSZ STCND TRIP START STND 99000557 vsd L1L2 L2L3 L3L1 AND AND AND AND AND AND L1N L2N L3N STCND STNDL1L2 STNDL2L3 STNDL3L1 STNDL1N STNDL2N STNDL3N STZMPP STNDPE AND BLOCK VTSZ STND BLK OR OR OR OR ...

Page 74: ...0000488 vsd STNDL1N STNDL2N STNDL3N STNDL1L2 STNDL2L3 STNDL3L1 OR OR OR OR AND AND AND AND BLK t 15 ms t 15 ms t 15 ms t 15 ms START STL3 STL2 STL1 en00000489 vsd STNDL1N cont DIRL1N STNDL2N cont DIRL2N STNDL3N cont DIRL3N STNDL1L2 cont DIRL1L2 STNDL2L3 cont DIRL2L3 STNDL3L1 cont DIRL3L1 1 1 1 1 1 1 BLK cont t 15 ms t 15 ms t 15 ms t 15 ms STZMPE cont ZM1 STL1 ZM1 STL2 ZM1 STL3 ZM1 START STZMPP co...

Page 75: ...tPE On STZMPE AND t tPP t tPE OR BLKTR t 15ms AND AND AND STL1 STL2 STL3 TRIP TRL1 TRL2 TRL3 AND Signal Description BLOCK Blocks the operation of distance protection zone n BLKTR Blocks tripping outputs of distance protection zone n VTSZ Blocks the operation of distance protection zone n connected to fuse failure signal FUSE VTSZ STCND External starting condition for the operation of the distance ...

Page 76: ...distance protection zone n in phase L1 available only with single pole tripping unit STL2 Start of directional distance protection zone n in phase L2 available only with single pole tripping unit STL3 Start of directional distance protection zone n in phase L3 available only with single pole tripping unit STND Non directional start of distance protection zone n Signal Description BLOCK Blocks the ...

Page 77: ... 3 Table 76 General setting parameters for ZM1 3 ZMn function Signal Description BLOCK Blocks the operation of distance protection zone 5 BLKTR Blocks tripping outputs of distance protection zone 5 VTSZ Blocks the operation of distance protection zone 5 connected to fuse failure signal FUSE VTSZ STCND External starting condition for the operation of the distance protection zone n Connected to one ...

Page 78: ... 10 00 Positive sequence reactive reach of dis tance protection zone n for Ph Ph faults R1PP 0 10 400 00 Step 0 01 ohm ph 10 00 Positive sequence line resistance included in distance protection zone n for Ph Ph faults RFPP 0 10 400 00 Step 0 01 ohm loop 10 00 Resistive reach of distance protection zone n for Ph Ph faults Timer t1PP Timer t2PP Timer t3PP Off On Off Operating mode of time delayed tr...

Page 79: ... tance protection zone 4 for Ph Ph faults Parameter Range Default Unit Description Operation PE Off On Off Operating mode for ZM4 for Ph E faults X1PE 0 10 400 00 Step 0 01 10 00 ohm ph Positive sequence reactive reach of dis tance protection zone 4 for Ph E faults R1PE 0 10 400 00 Step 0 01 10 00 ohm ph Positive sequence line resistance included in distance protection zone 4 for Ph E faults X0PE ...

Page 80: ... of dis tance protection zone 5 for Ph Ph faults R1PP 0 10 400 00 Step 0 01 10 00 ohm ph Positive sequence line resistance included in distance protection zone 5 for Ph Ph faults RFPP 0 10 400 00 Step 0 01 10 00 ohm loop Resistive reach of distance protection zone 5 for Ph Ph faults Timer t5PP Off On On Operating mode of time delayed trip for the distance protection zone 5 for Ph Ph faults t5PP 0 ...

Page 81: ...10 400 00 Step 0 01 10 00 ohm loop Resistive reach of distance protection zone 5 for Ph E faults Timer t5PE Off On On Operating mode of time delayed trip for the distance protection zone 5 for Ph E faults t5PE 0 000 60 000 Step 0 001 0 000 s Time delayed trip operation of the dis tance protection zone 5 for Ph E faults Parameter Range Default Unit Description ArgDir 5 45 Step 1 15 degrees Lower an...

Page 82: ...is tance 0 10 1200 00 Ω phase in steps of 0 01 Ω Fault resistance For phase phase faults 0 10 400 00 Ω loop in steps of 0 01 Ω For phase earth faults 0 10 400 00 Ω loop in steps of 0 01 Ω Setting range of timers for impedance zones 0 000 60 000 s in steps of 1 ms Static accuracy at 0 degrees and 85 degrees Voltage range 0 1 1 1 x Ur 5 Current range 0 5 30 x Ir Static angular accu racy at 0 degrees...

Page 83: ...nes secures switch on to fault tripping for fault situations where directional information can not be established for example due to lack of polarizing voltage Use of non directional protection also gives fast fault clearance when energizing a bus from the line with a short circuit fault on the bus 2 2 Functionality The SOTF function is a logical function built up from logical elements It is a com...

Page 84: ...ng parameters for the automatic switch onto fault logic SOTF SOTF function SOTF BC SOTF DLCND SOTF NDACC t 200 m s 1 SOTF BLOCK t 1000 m s t 15 m s SOTF TRIP en00000492 vsd Signal Description BLOCK Blocks function NDACC Connected to function s to be released for immediate tripping when SOTF function is enabled DLCND Connected to dead line detection function to provide automatic enabling of SOTF fu...

Page 85: ...l data Table 89 SOTF Automatic switch onto fault function Parameter Value Accuracy Delay following dead line detection input before SOTF function is automatically enabled 200 ms 0 5 10 ms Time period after circuit breaker closure in which SOTF function is active 1000 ms 0 5 10 ms ...

Page 86: ...s a complementary function to the distance protection function The local acceleration logic can be enabled for operation in two ways The first way uses an au tomatic recloser ready signal either from the internal recloser or an external recloser The sec ond way uses loss of load detection When enabled by either method the local acceleration logic will produce an immediate output on pickup of the f...

Page 87: ...EADY 1 1 ZCLC NDST ZCLC EXACC ZCLC BC ZCLC LLACC 1 STILL t 15 ms ZoneExtension On LossOfLoad On 1 ZCLC TRIP Signal Description BLOCK Blocks function BC Circuit breaker closed LLACC Connected to function to be used for tripping at loss of load accelera tion ARREADY Releases function used for zone extension for immediate tripping EXACC Connected to function to be used for tripping at zone extension ...

Page 88: ...ttings Functions Groupn Impedance ComLocal Table 92 Setting parameters for the local acceleration logic ZCLC ZCLC function Parameter Range Default Unit Description ZoneExtension Off On Off Operating mode for zone extension logic LossOfLoad Off On Off Operating mode for loss of load accelera tion logic ...

Page 89: ...selectivity in networks with different protective relays used for short circuit and earth fault protection 4 2 Functionality For the impedance based phase selection all six fault loops are measured separately and contin uously The reaches are independently settable in the forward and reverse directions and for phase to phase and phase to ground faults The resistive reaches are also independently s...

Page 90: ...d operate characteristic for an impedance based GFC func tion Different designations have the following meaning XFW reactive reach in forward direction XRV reactive reach in reverse direction RF resistive reach within the unlimited area RLoad resistive reach restricted by the minimum load impedance LA expected load impedance angle ZONE 3 ZONE 2 ZONE 1 ZONE 4 R jX 99000189 vsd XFW RLoad XRV RF LA ...

Page 91: ...s xx00000393 vsd GFC GFC BLOCK TRIP STFWL1 STFWL2 STFWL3 STFWPE STRVL1 STRVL2 STRVL3 STRVPE STNDL1 STNDL2 STNDL3 STNDPE STFW1PH STFW2PH STFW3PH STPE STPP STCND GFC BLOCK t 10 ms t 20 ms t 15 ms t 15 ms GFC STPE GFC STPP IRELPE cont IRELPP cont 3 I0 0 5 IMinOp 3 I0 INRelease PE 100 Iph max 3 I0 0 2 Ir or 3 I0 INBlockPP 100 Iph max en01000048 vsd ...

Page 92: ...e preference logic INDL1N cont INDL2N cont INDL3N cont INDL3L1 cont INDL2L3 cont INDL1L2 cont GFC STNDPE GFC STNDL1 GFC STNDL2 GFC STNDL3 99000546 vsd 1 t 15 ms t 15 ms t 15 ms t 15 ms STUL1 ST3U0 NO FILTER ACTIVE 1 STUL2 STUL3 IRELPE cont GFCL1N GFCN GFCL2N GFCL3N GFCL1L2 GFCL2L3 GFCL3L1 IRELPP cont 1 1 1 1 1 1 1 1 ...

Page 93: ...WL1N INDL1L2 cont DFWL1L2 INDL3L1 cont DFWL3L1 INDL2N cont DFWL2N INDL1L2 cont DFWL2L3 INDL2L3 cont INDL3N cont DFWL3N INDL2L3 cont INDL3L1 cont 1 1 1 1 t 15 ms t 15 ms t 15 ms t 15 ms 1 1 t 15 ms t 15 ms t 15 ms t 15 ms t 15 ms GFC STFW1PH GFC STFWL1 GFC STFWPE GFC STFWL2 GFC STFW2PH GFC STFWL3 GFC STFW3PH en00000483 vsd ...

Page 94: ...L1 cont DRVL3L1 INDL2N cont DRVL2N INDL1L2 cont DRVL2L3 INDL2L3 cont INDL3N cont DRVL3N INDL2L3 cont INDL3L1 cont 1 1 1 1 t 15 ms t 15 ms t 15 ms t 15 ms GFC STRVL1 GFC STRVPE GFC STRVL2 GFC STRVL3 en00000484 vsd INDL1N cont INDL2N cont INDL3N cont INDL1L2 cont INDL2L3 cont INDL3L1 cont Bool to integer GFC STCND en000000485 vsd Timer tPE On INDL1N cont INDL2N cont INDL3N cont Timer tPP On INDL1L2 ...

Page 95: ...rward operation of ph E loop STRVL1 General fault criteria reverse operation in phase L1 STRVL2 General fault criteria reverse operation in phase L2 STRVL3 General fault criteria reverse operation in phase L3 STRVPE General fault criteria reverse operation of ph E loop STNDL1 General fault criteria non directional operation in phase L1 STNDL2 General fault criteria non directional operation in pha...

Page 96: ...p 1 20 of lphMax 3I0 limit for releasing phase to earth measuring loops INBlockPP 10 100 Step 1 40 of lphMax 3I0 limit for blocking phase to phase measuring loops Timer tPP Off On Off Time delayed of trip for phase to phase faults enabled or disabled tPP 0 000 60 000 Step 0 001 5 000 s Time delay of trip for phase to phase faults Timer tPE Off On Off Time delay of trip for phase to earth faults en...

Page 97: ...p 0 01 50 ohm phas e Positive sequence reactive reach in for ward direction for phase to phase faults RFPP 0 10 400 00 Step 0 01 50 ohm loop Resistive reach forward and reverse for phase to phase measurement X1RvPE 0 1 400 00 Step 0 01 50 ohm phas e Positive sequence reactive reach in reverse direction for phase to earth faults X1FwPE 0 1 400 00 Step 0 01 50 ohm phas e Positive sequence reactive r...

Page 98: ... 0 01 ohm phase Resistive reach forward reverse For phase phase faults 0 1 400 ohm loop in steps of 0 01 ohm loop For phase earth faults 0 1 400 ohm loop in steps of 0 01 ohm loop Load encroachment 0 1 400 ohm loop in steps of 0 01 ohm loop Safety load impedance angle 5 45 degrees in steps of 1 degrees Overcurrent setting range Phase currents 10 400 of I1b in steps of 1 Residual current 10 150 of ...

Page 99: ...through the impedance area between the outer and the inner characteristics Power swings are identified by transition times longer than timer settings The impedance mea suring principle is the same as that used for the distance protection zones The impedance and the transient impedance time are measured in all three phases separately One out of three or two out of three operating modes can be selec...

Page 100: ...and characteristic of the PSD function 5 3 Function block jX R tP1 Impedance locus at power swing 99000159 vsd KX X IN 1 X IN 1 X IN 1 KX X IN 1 KR R IN 1 KR R IN 1 R IN 1 IN R1 xx00000180 vsd PSD PSD BLOCK BLKI01 BLKI02 BLK1PH REL1PH BLK2PH REL2PH I0CHECK TRSP EXTERNAL START ZIN ZOUT ...

Page 101: ... PSD BLKI02 1 1 PSD BLKI01 PSD BLOCK INHIBIT ZOUTL3 ZOUTL2 ZOUTL1 DET1of3 int PSD REL1PH PSD BLK1PH DET2of3 int PSD REL2PH PSD BLK2PH 1 PSD EXTERNAL 1 PSD START PSD ZOUT ZINL1 ZINL2 ZINL3 PSD ZIN DET2of3 int PSD CONS int ZOUTLn ZINLn PSD DET Ln PSD CONS int 1 t tP2 t tP1 PSD DET L1 PSD DET L2 PSD DET L3 DET1of3 int t tR1 t tR2 1 1 1 1 t tH t 10 ms t tEF ...

Page 102: ...e out of three phase operating mode REL1PH Releases one out of three phase operating mode BLK2PH Blocks two out of three phase operating mode REL2PH Releases two out of three phase operating mode I0CHECK Residual current 3I0 detection used to inhibit PSD START output TRSP Single pole tripping command issued by tripping function EXTERNAL Input for external detection of power swing Signal Descriptio...

Page 103: ...ng single pole reclos ing dead time tR1 0 000 60 000 Step 0 001 0 300 s Timer giving delay to blocking of output by the residual current tR2 0 000 60 000 Step 0 001 2 000 s Timer giving delay to blocking of output at very slow swings Parameter Range Default Unit Description Parameter Setting range Accuracy Impedance setting range at Ir 1A divide values by 5 for Ir 5A Reactive reach XIN 0 10 400 00...

Page 104: ...PSD detected 0 000 60 000 s in steps of 1 ms 0 5 10 ms Timer tEF overcoming 1ph reclosing dead time 0 000 60 000 s in steps of 1 ms 0 5 10 ms Timer tR1 to time delay block by the residual current 0 000 60 000 s in steps of 1 ms 0 5 10 ms Timer tR2 to time delay block at very slow swings 0 000 60 000 s in steps of 1 ms 0 5 10 ms Parameter Setting range Accuracy ...

Page 105: ...al function built up from logical elements It is a supplementary function to the distance or overcurrent protection requiring for its operation inputs from the dis tance or overcurrent protection and the teleprotection equipment The type of communication aided scheme to be used can be selected by way of the settings The ability to select which protection zone is assigned to which input of the ZCOM...

Page 106: ...e Figure 40 Basic logic for trip carrier in permissive scheme Figure 41 Carrier guard logic with unblock logic xx00000574 vsd ZCOM CACC ZCOM CR ZCOM TRIP t tCoord ZCOM CACC ZCOM CR ZCOM TRIP t tCoord xx00000575 vsd Z C O M C R G t 2 00 m s 1 t tS ecu rity 1 t 1 5 0 m s 1 Z C O M C R Z C O M C R L Z C O M L C G e n 0 0 0 0 0 4 9 1 vsd ...

Page 107: ...00192 vsd ZCOM CRG ZCOM CR ZCOM CRL CRL cont 1 1 t tSecurity t 200 ms t 150 ms 1 ZCOM LCG Unblock Restart Unblock NoRestart Unblock Off ZCOM CSUR ZCOM BLOCK ZCOM CSBLK CRL cont ZCOM CSNBLK ZCOM CSOR ZCOM CACC ZCOM CS ZCOM TRIP t 25 ms t tCoord 1 1 1 tSendMin 1 1 1 tSendMin SchemeType Blocking Schemetype Permissive OR Schemetype Permissive UR SchemeType Intertrip ...

Page 108: ...reaching protection zone to be used as the local criterion for per missive tripping on receipt of the carrier signal CSUR Underreaching function s to be used for sending a carrier signal CSOR Overreaching function s to be used for sending a carrier signal CSBLK Reverse directed protection zone to be used for sending a carrier sig nal in a blocking scheme CSNBLK Forward directed protection zone to ...

Page 109: ...ermissi veOR Block ing Intertrip Operating mode for scheme communica tion logic tCoord 0 000 60 000 Step 0 001 0 050 s Coordination timer tSendmin 0 000 60 000 Step 0 001 0 100 s Minimum duration of carrier send signal Unblock Off NoRe start Restart Off Operating mode for unblocking logic tSecurity 0 000 60 000 Step 0 001 0 035 s Security timer Parameter Setting range Accuracy Coordination timer t...

Page 110: ...ential tripping when for a fault on the line the initial infeed of fault current from one end is too weak to operate the measuring elements 7 2 Functionality The ZCAL function block provides the current reversal and weak end infeed logic functions that supplement the standard scheme communication logic or the phase segregated scheme commu nication logic On detection of a current reversal the curre...

Page 111: ...ee phase scheme communication logic 7 4 Logic diagram Figure 45 Current reversal logic xx00000186 vsd ZCAL ZCAL BLOCK IRV IRVL1 IRVL2 IRVL3 IRVBLK IRVBLKL1 IRVBLKL2 IRVBLKL3 CBOPEN VTSZ WEIBLK WEIBLK1 WEIBLK2 WEIBLK3 CRL CRLL1 CRLL2 CRLL3 TRWEI TRWEIL1 TRWEIL2 TRWEIL3 IRVL IRVLL1 IRVLL2 IRVLL3 ECHO ECHOL1 ECHOL2 ECHOL3 xx01000186 vsd ZCAL ZCAL BLOCK IRV IRVBLK CBOPEN VTSZ WEIBLK CRL TRWEI IRVL ECH...

Page 112: ...the ZCAL ZCAL function block ZCAL BLOCK ZCAL CRLLn ZCAL WEIBLKn ZCAL ECHOLn ECHOLn cont xx03000079 vsd ZCAL VTSZ 1 t tWEI t 200 ms t 50 ms t 200 ms WEI Trip ZCAL CBOPEN STUL1N STUL2N STUL3N t 100 ms 1 ECHOLn cont t 15 ms t 15 ms t 15 ms 1 ZCAL TRWEI ZCAL TRWEIL1 ZCAL TRWEIL2 ZCAL TRWEIL3 en00000551 vsd Signal Description BLOCK Blocks function IRV Activates current reversal logic IRVL1 Activates cu...

Page 113: ...infeed logic in phase L1 WEIBLK2 Blocks weak end infeed logic in phase L2 WEIBLK3 Blocks weak end infeed logic in phase L3 CRL Carrier received CRLL1 Carrier received in phase L1 CRLL2 Carrier received in phase L2 CRLL3 Carrier received in phase L3 Signal Description TRWEI Weak end infeed logic trip output TRWEIL1 Weak end infeed logic trip output in phase L1 TRWEIL2 Weak end infeed logic trip out...

Page 114: ...Off Trip Echo Off Operating mode for the WEI function tWEI 0 000 60 000 Step 0 001 0 010 s Coordination time for the WEI function UPN 10 100 Step 1 70 of U1b Under voltage detection ph N measure ment UPP 20 170 Step 1 70 of U1b Under voltage detection ph ph measure ment Parameter Setting range Accuracy Pickup time for current reversal tPickUp 0 000 60 000 s in steps of 0 001s 0 5 10ms Delay time f...

Page 115: ...103 About this chapter Chapter 5 Current Chapter 5 Current About this chapter This chapter describes the current protection functions ...

Page 116: ...current protection is blocked from the fuse supervision function 1 2 Functionality The current measuring element continuously measures the current in all three phases and com pares it to the set operate value IP A filter ensures immunity to disturbances and dc compo nents and minimizes the transient overreach If any phase current is above the set value IP the phase overcurrent trip signal TRP is a...

Page 117: ... trip Figure 50 IOC function block phase with 1 2 3 phase trip Figure 51 IOC function block phase with 3 phase trip Figure 52 IOC function block N 3 phase trip xx01000176 vsd IOC IOC BLOCK TRIP TRP TRN xx00000683 vsd IOC IOC BLOCK TRIP TRP TRL1 TRL2 TRL3 xx01000079 vsd IOC IOC BLOCK TRIP TRP xx00000684 vsd IOC IOC BLOCK TRIP TRN ...

Page 118: ...ignals for the IOC IOC function block Path in local HMI ServiceReport Functions InstantOC FuncOutputs IOC BLOCK IOC TRIP en01000180 vsd Function Enable IOC INSTANTANEOUS PHASE OVERCURRENT FUNCTION 1 STIL1 STIL2 STIL3 IOC TRP IOC TRL1 IOC TRL2 IOC TRL3 1 1 IOC TRN STIN TEST ACTIVE TEST BlockIOC Yes Signal Description BLOCK Block of the instantaneous overcurrent protection function ...

Page 119: ... pole tripping is included TRL2 Trip by instantaneous overcurrent function phase L2 when single pole tripping is included TRL3 Trip by instantaneous overcurrent function phase L3 when single pole tripping is included TRN Trip by the instantaneous residual overcurrent function when included Parameter Range Default Unit Description Operation Off On Off Operating mode for the IOC function IP 50 2000 ...

Page 120: ...ults or as a fault detection for some other protection functions 2 2 Functionality The current measuring element continuously measures the current in all three phases and com pares it to the set operate value IP A filter ensures immunity to disturbances and dc compo nents and minimizes the transient overreach If the current in any of the three phases is above the set value IP a common start signal...

Page 121: ...n block Figure 54 TOC function block phase N Figure 55 TOC function block phase Figure 56 TOC function block N xx00000197 vsd TOC TOC BLOCK BLKTR TRIP TRP TRN STP STL1 STL2 STL3 STN xx00000681 vsd TOC TOC BLOCK BLKTR TRIP TRP STP STL1 STL2 STL3 xx00000709 vsd TOC TOC BLOCK BLKTR TRIP TRN STN ...

Page 122: ... STL1 TOC STL2 STIN TOC STL3 TOC STN t tN TOC TRN 1 Signal Description BLOCK Block of the overcurrent function BLKTR Block of trip from the overcurrent function Signal Description TRIP Trip by time delayed overcurrent function TRP Trip by time delayed phase overcurrent function when included TRN Trip by the time delayed residual overcurrent function when included STP Start of phase overcurrent fun...

Page 123: ...100 of I1b Operating phase overcurrent tP 0 000 60 000 Step 0 001 10 000 s Time delay of phase overcurrent function IN 10 150 Step 1 100 of I4b Operating residual current tN 0 000 60 000 Step 0 001 10 000 s Time delay of residual overcurrent func tion Function Setting range Accuracy Operate current Phase measuring ele ments IP 10 400 of I1b in steps of 1 2 5 of Ir at I Ir 2 5 of I at I Ir Residual...

Page 124: ...ation the directional residual overcurrent function is used together with the communication logic for residual overcurrent protection 3 Back up protection for phase to earth faults for lines in solidly earthed systems By using the directional residual protection as back up function the back up fault clearance time can be kept relatively short together with the maintained selectiv ity 4 Etc 3 2 Fun...

Page 125: ...eport Functions EarthFault TimeDelayEF FuncOutputs 99000204 vsd Operation ON Def NI VI EI LOG 1 EFCh k IN Σ 300ms t 1000ms t 3Io t tMin t t1 IMin 20 50ms t TEF TRIP Directional 100 FORWARD 60 REVERSE 3Iox cos φ 65 EF3IoSTD 0 01Un 2fn 2fn Direction Option Directional check 3Uo TEF BLOCK TEF TRSOTF TEF STFW TEF STRV TEF START TEF BC TEF BLKTR 3Io 1 Signal Description BLOCK Block of function BLKTR Bl...

Page 126: ...red I4 I5 I4 Current signal used for earth fault func tion Characteristic Def NI VI EI LOG Def Time delay characteristic for TEF protec tion IN 5 300 Step 1 5 of Inb Start current for TEF function I4b or I5b IMin 100 400 Step 1 100 of IN Minimum operating current t1 0 000 60 000 Step 0 001 0 000 s Independent time delay k 0 05 1 10 Step 0 01 0 05 Time multiplier for dependent time delay tMin 0 000...

Page 127: ...and Iset 35 of Ir Definite time delay 0 000 60 000 s in steps of 1ms 0 5 10 ms Time multiplier for inverse time delay k 0 05 1 10 in steps of 0 01 According to IEC 60255 3 Normal inverse characteristic I Imeas Iset IEC 60255 3 class 5 60 ms Very inverse characteristic IEC 60255 3 class 7 5 60 ms Extremely inverse characteristic IEC 60255 3 class 7 5 60 ms Logarithmic characteristic 5 of t at I 1 3...

Page 128: ...hemes In the blocking scheme a signal is sent to the remote end of the line if the directional element in the directional residual overcurrent protection sending end detects the fault in the reverse di rection If no blocking signal is received and the directional element in the directional residual overcurrent protection receiving end detects the fault in the forward direction a trip signal will b...

Page 129: ... EFC function block t 50 ms t 0 60 s t Coord t 25 ms EFC CSBLK EFC BLOCK EFC CACC EFC CR EFC CS EFC TRIP EFC CRL 99000107 vsd t 0 60 s t 25 ms 1 t 50 ms t Coord EFC CRL EFC TRIP EFC CS EFC BLOCK EFC CR EFC CACC EFC CSBLK EFC CSPRM 99000108 vsd Signal Description BLOCK Block function CACC Permits the operation when high CSPRM Initiates sending of carrier signal in permissive scheme CSBLK Initiates ...

Page 130: ...echnical data Table 126 EFC Scheme communication logic for residual overcurrent protection Signal Description TRIP Trip by communication scheme logic CS Carrier send by communication scheme logic CRL Carrier receive by the communication scheme logic Parameter Range Default Unit Description Operation Off On Off Operating mode for EFC function SchemeType Permissive Blocking Permissive Scheme type mo...

Page 131: ...e remote terminal can detect the fault The detection requires a suf ficient minimum residual fault current out from this terminal The fault current can be too low due to an opened breaker or high positive and or zero sequence source impedance behind this terminal To overcome these conditions weak end infeed WEI echo logic is used 5 2 Design The reverse directed signal from the directional residual...

Page 132: ...m weak end infeed Echo logic Figure 64 Simplified logic diagram weak end infeed Trip logic t t 10 ms 0 60 s t 0 60 s tPickUp tPickUp 0 60 s t tDelay EFCA BLOCK EFCA IRV EFCA IRVBLK EFCA IRVL 99000053 vsd t 200 ms t 50 ms t 200 ms EFCA CRL EFCA WEIBLK EFCA BLOCK EFCA ECHO WEI Echo 99000055 vsd EFCA CRL EFCA BLOCK EFCA WEIBLK EFCA TRWEI EFCA CBOPEN t 200 ms t 50 ms t 200 ms EFCA ECHO WEI Trip 990000...

Page 133: ...gnal Description BLOCK Blocking of function IRV Activation of current reversal logic IRVBLK Blocking of current reversal logic WEIBLK Blocking of weak end infeed logic CRL Carrier received for weak end infeed logic CBOPEN Blocking of trip when breaker is open Signal Description TRWEI Trip by weak end infeed logic IRVL Operation of current reversal logic ECHO Carrier send by weak end infeed logic P...

Page 134: ...Current reversal and weak end infeed logic for residual overcurrent protection Parameter Setting range Accuracy Operate voltage for WEI trip U 5 70 of U1b in steps of 1 5 of set value Current reversal pickup timer tPickUp 0 000 60 000 s in steps of 1 ms 0 5 10 ms Current reversal delay timer tDelay 0 000 60 000 s in steps of 1 ms 0 5 10 ms ...

Page 135: ...123 About this chapter Chapter 6 Voltage Chapter 6 Voltage About this chapter This chapter describes the voltage protection functions ...

Page 136: ...tion function TUV is applicable in all situations where reliable detection of low phase voltages is necessary The function can also be used as a super vision and fault detection function for some other protection functions to increase the security of a complete protection system 1 2 Function block xx00000207 vsd TUV BLOCK BLKTR VTSU TRIP STL1 STL2 STL3 START ...

Page 137: ...V function block Path in local HMI ServiceReport Functions TimeDelayUV FuncOutputs TUV TEST Block TUV Yes TUV STUL1N TUV STUL2N TUV STUL3N 1 TEST 1 xx03000076 vsd t TUV BLKTR TUV BLOCK TUV VTSU TUV TRIP TUV START TUV STL1 TUV STL2 TUV STL3 Signal Description BLOCK Block undervoltage function BLKTR Block of trip from time delayed undervoltage function VTSU Block from voltage transformer circuit sup...

Page 138: ...tection Signal Description TRIP Trip by time delayed undervoltage function STL1 Start phase undervoltage phase L1 STL2 Start phase undervoltage phase L2 STL3 Start phase undervoltage phase L3 START Start phase undervoltage Parameter Range Default Unit Description Operation Off On Off Operating mode for TUV function UPE 10 100 Step 1 70 of U1b Operate phase voltage t 0 000 60 000 Step 0 001 0 000 s...

Page 139: ...he power systems 2 2 Functionality The phase overvoltage protection function continuously measures the three phase voltages and initiates the corresponding output signals if the measured phase voltages exceed the preset value starting and remain high longer than the time delay setting on the timers trip This function also detects the phases which caused the operation 2 3 Function block Figure 66 T...

Page 140: ...ock Path in local HMI ServiceReport Functions TimeDelayOV FuncOutputs xx03000077 vsd TOV TEST Block TOV Yes TOV STUL1N TOV STUL2N TOV STUL3N TEST TOV ST3UO 1 t t 1 1 TOV BLKTR TOV BLOCK TOV TRIP TOV TRPE TOV STPE TOV STL1 TOV STL2 TOV STL3 TOV STN TOV TRN Signal Description BLOCK Block of time delayed overvoltage function BLKTR Block of trip output from time delayed overvoltage function ...

Page 141: ...phase L3 STN Start by residual overvoltage function Parameter Range Default Unit Description Operation Off On Off Operating mode for TOV function UPE 50 200 Step 1 120 of U1b Operate value for the phase overvoltage function t 0 000 60 000 Step 0 001 0 000 s Time delay of the phase overvoltage function 3U0 5 100 Step 1 30 of U1b Operate value for the neutral overvoltage function t 0 000 60 000 Step...

Page 142: ...130 Time delayed overvoltage protection TOV Chapter 6 Voltage ...

Page 143: ...131 About this chapter Chapter 7 Power system supervision Chapter 7 Power system supervision About this chapter This chapter describes the power system supervision functions ...

Page 144: ...m 1 2 Functionality The dead line detection function continuously measures all three phase currents and phase volt ages of a protected power line The line is declared as dead not energized if all three measured currents and voltages fall below the preset values for more than 200 ms If Switch onto fault logic SOTF and or Fuse failure FUSE are selected Dead line detection DLD is automatically includ...

Page 145: ...t and output signals Table 139 Input signals for the DLD DLD function block Path in local HMI ServiceReport Functions DeadLineDet FuncOutputs en00000493 vsd 1 STUL3N STUL1N STMIL3 STUL2N STMIL2 STMIL1 DLD STIL1 DLD STIL2 DLD STIL3 DLD STUL1 DLD STUL2 DLD STUL3 DLD STPH DLD START DLD BLOCK Signal Description BLOCK Block of dead line detection ...

Page 146: ...t value phase L2 STIL3 Current below set value phase L3 STUL1 Voltage below set value phase L1 STUL2 Voltage below set value phase L2 STUL3 Voltage below set value phase L3 STPH Dead phase condition detected in at least one phase Parameter Range Default Unit Description Operation Off On Off Operating mode for DLD function U 10 100 Step 1 70 of U1b Operating phase voltage undervoltage function IP 5...

Page 147: ...135 About this chapter Chapter 8 Secondary system supervision Chapter 8 Secondary system supervision About this chapter This chapter describes the secondary system supervision functions ...

Page 148: ...ro sequence current and voltage in all three phases It operates if the measured zero se quence voltage increases over preset operating value and if the measured zero sequence current remains below the preset operating value Three output signals are available The first depends directly on the voltage and current mea surement The second depends on the operation of the dead line detection function to...

Page 149: ...E BLOCK FUSE VTSU 99000500 vsd FUSE FUSE FAILURE SUPERVISION FUNCTION TEST ACTIVE TEST BlockFUSE Yes STZERO FUSE VTSZ FUSE VTF3PH FUSE MCB FUSE DISC t 150 ms FUSE DLCND t 200 ms t 5 s STUL3N STUL2N STUL1N STORE3PH 20 ms 1 All voltages are low From non volatile memory 0 All voltages are high Reset Latch 1 Fuse failure for more than 5 s Dead Line Block Set Latch 1 Function Enable 1 Fuse Failure Dete...

Page 150: ...ence Signal Description BLOCK Block of fuse failure function MCB Operation of MCB DISC Line disconnector position DLCND Dead line condition CBCLOSED Circuit breaker closed information Signal Description VTSU Block for voltage measuring functions VTSZ Block for impedance measuring functions VTF3PH Detection of 3 phase fuse failure Parameter Range Default Unit Description ZeroSeq Off On Off Operatin...

Page 151: ...139 About this chapter Chapter 9 Control Chapter 9 Control About this chapter This chapter describes the control functions ...

Page 152: ... terminal Therefore the specific circuit breaker arrangements that can be catered for or the num ber of bays of a specific arrangement that can be catered for depends on the type of terminal 1 2 Functionality The AR function is a logical function built up from logical elements It operates in conjunction with the trip output signals from the line protection functions the OK to close output signals ...

Page 153: ... Operation Off Operation Standby 1 1 S R 1 t 5 s 1 1 1 S R AR01 SETON INITIATE STARTAR AR01 READY AR01 UNSUC COUNT 0 INITIATE Blocked state Blocking and inhibit conditions X Y AR01 CBREADY AR01 CBCLOSED AR01 TRSOTF AR01 START AR01 OFF AR01 ON Additional condition Reclosing function reset 99000099 vsd ...

Page 154: ...142 Autorecloser AR Chapter 9 Control Figure 73 Control of extended AR open time shot 1 t tTRIP t t TRIP INITIATE AR01 PLCLOST STARTER Extend t1 INITIATE LONGDURA 99000116 vsd STARTER 1 ...

Page 155: ...143 Autorecloser AR Chapter 9 Control Figure 74 Automatic proceeding of shot 2 to 4 t tAuto Wait 1 1 AR01 START AR01 CBCLOSED INITIATE xx06000055 vsd AR01 CLOSECB S R Q Q ...

Page 156: ...R Open time timers SPTO TPTO Pulse AR X Blocking AR01 CBREADY INITIATE AR01 SYNC T4TO T3TO T2TO TPTO SPTO 0 1 2 3 4 CL R COUNTER AR State Control 0 1 2 3 4 1 t tReclaim LOGIC reclosing programs 1PT1 2PT1 T1 T2 T3 T4 1 1 1 t tInhibit 0 1 2 3 4 AR01 INPROGR AR01 P1P AR01 P3P Y Inhibit Y Blocking AR01 INHIBIT STARTAR INITIATE AR01 TR3P AR01 TR2P Pulse AR above 99000100 vsd ...

Page 157: ...ome signals may not be present depending on the ordered options tPulse 1 Pulse AR tPulse AR01 CLOSECB 1 ph Shot 1 2 ph Shot 1 3 ph Shot 1 3 ph Shot 2 3 ph Shot 3 3 ph Shot 4 No of Reclosings INITIATE AR01 1PT1 AR01 2PT1 AR01 T1 AR01 T2 AR01 T3 AR01 T4 Only if PulseCut On 99000300 vsd 1 t tUnsuc 1 S R Pulse AR AR01 CBCLOSED AR01 START AR already started COUNT 0 AR01 UNSUC 99000301 vsd ...

Page 158: ... protection TRSOFT Provides for start of automatic reclosing cycle from switch on to fault CBREADY Circuit breaker ready for operation CBCLOSED Circuit breaker closed PLCLOST Permissive communication channel out of service SYNC OK to close from synchronizing energizing function WAIT Wait from Master for sequential reclosing Signal Description BLOCKED Automatic recloser in blocked state SETON Autom...

Page 159: ...eclosing attempts Parameter Range Default Unit Description Operation Off Stand by On Off Operating mode for AR function NoOfReclosing 1 4 1 Maximum number of reclosing attempts Extended t1 Off On Off Extended dead time for loss of permis sive channel t1 0 000 60 000 Step 0 001 1 000 s Dead time for first three phase automatic reclosing shot t2 0 0 90000 0 Step 0 1 30 0 s Dead time for second autom...

Page 160: ...NOCBCheck CB Check enabled or disabled for unsuc cessful mode tUnsuc 0 0 90000 0 Step 0 1 30 0 s CB Check time before unsuccessful tCBClosed 0 000 60 000 Step 0 001 5 000 s The time a breaker must be closed before AR becomes ready for a reclosing cycle Parameter Range Default Unit Description Parameter Setting range Accuracy Automatic reclosing open time shot 1 t1 3ph 0 000 60 000 s in steps of 1 ...

Page 161: ...toWait 0 000 60 000 s in steps of 1 ms 0 5 10 ms Time delay before indicating reclosing unsuc cessful tUnsuc 0 0 90000 0 s in steps of 0 1 s 0 5 10 ms Time CB must be closed before AR becomes ready for a reclosing cycle tCBClosed 0 000 60 000 s in steps of 1 ms 0 5 10 ms Parameter Value Reclosing shots 1 4 Programs Three pole trip 1 Single two and three pole trip 6 Number of autoreclosers Up to si...

Page 162: ...150 Autorecloser AR Chapter 9 Control ...

Page 163: ...151 About this chapter Chapter 10 Logic Chapter 10 Logic About this chapter This chapter describes the logic functions ...

Page 164: ...t signal from the TR function is settable The TR function has a single input through which all trip output signals from the protection func tions within the terminal or from external protection functions via one or more of the terminal s binary inputs are routed It has a single trip output for connection to one or more of the termi nal s binary outputs as well as to other functions within the term...

Page 165: ...l data Table 156 TR Tripping logic Parameter Range Default Unit Description Operation Off On Off Operating mode for TR function tTripMin 0 000 60 000 Step 0 001 0 150 s Minimum duration of trip time Parameter Value Accuracy Setting for the minimum trip pulse length tTripMin 0 000 60 000 s in steps of 1 ms 0 5 10 ms ...

Page 166: ...uts The inputs to the HSBO logic utilize the same fast connections Input connections to the logic are derived from binary inputs from outputs of the high speed distance protection and from inputs to the regular trip logic and scheme communication logic The HSBO scheme communication logic runs in parallel with the regular scheme communication logic The fast connections to and from the HSBO logic co...

Page 167: ...BO ZCOMCACC HSBO TRIPPSLn HSBO TRLn HSBO HSTRLn HSBO BLKHSTR HSBO HSCSLn HSBO HSCSMPH HSBO CSLn HSBO CSMPH HSBO ZC1P ZC1P CACCLn ZCOM CACC TRIP PSLn TRIP ZCOM HS TRLn HS CSLn HS CSMPH HS HSBO BLKHSCS HSBO ERROR BIx BIy BIz BOx BOx BOz BOz IOxx BOy BOz Binary output contacts Binary input contacts Regular function block in out Internal in out Fast Trip CS outputs configured through settings IOMOD TR...

Page 168: ...onfiguration error HSBO Test Regular function block in and ouput Internal in and output HSBO HSCSMPH HSBO HSCSLn HSBO HSTRLn HSBO BLKHSCS HSBO BLKHSTR 1 HSBO CR HSBO ZCOMCACC HSBO TRIPPSLn 1 1 HSBO ZC1CACCLn HSBO CRMPH HSBO CRLn HSBO BLKZCTR HSBO TRLn HSBO ERROR HSBO CSLn HSBO CSMPH 15ms 15ms 15ms 1 1 Signal Description BLKHSTR Blocks high speed trip BLKHSCS Blocks high speed carrier send BLKZCTR ...

Page 169: ... L2 output contact on I O module according to IOMOD setting Can only be set from the CAP 540 configura tion tool TR1L3OUT 0 24 0 Fast trip phase L3 output contact on I O module according to IOMOD setting Can only be set from the CAP 540 configura tion tool TR2L3OUT 0 24 0 Fast trip phase L3 output contact on I O module according to IOMOD setting Can only be set from the CAP 540 configura tion tool...

Page 170: ...ty are available in REx 5xx When the function Apparatus control is used in the terminal additional 32 event func tion blocks EV13 EV44 running with a slower cyclicity are available Each event function block has 16 connectables corresponding to 16 inputs INPUT1 to INPUT16 Every input can be given a name with up to 19 characters from the CAP 540 config uration tool The inputs can be used as individu...

Page 171: ...NPUT14 INPUT15 INPUT16 T_SUPR01 T_SUPR03 T_SUPR05 T_SUPR07 T_SUPR09 T_SUPR11 T_SUPR13 T_SUPR15 NAME01 NAME02 NAME03 NAME04 NAME05 NAME06 NAME07 NAME08 NAME09 NAME10 NAME11 NAME12 NAME13 NAME14 NAME15 NAME16 PRCOL01 INTERVAL BOUND FUNCTEV1 INFONO01 INFONO02 INFONO03 INFONO04 INFONO05 INFONO06 INFONO07 INFONO08 INFONO09 INFONO10 INFONO11 INFONO12 INFONO13 INFONO14 INFONO15 INFONO16 ...

Page 172: ...SPA 2 LON 3 SPA LON INTERVAL Time setting for cyclic sending of data BOUND Input signals connected to other terminals on the network 0 not con nected 1 connected FuncTEVnn Function type for event block nn nn 01 06 used for IEC protocol communication Only present in blocks EV01 EV06 InfoNoy Information number for event input y y 01 16 Used for IEC protocol communication Only present in blocks EV01 ...

Page 173: ...nge valid only for blocks EV01 EV06 Can only be set from CAP 540 configuration tool PrCoInn 0 3 0 Protocol for event block nn nn 07 44 0 Not used 1 SPA 2 LON 3 SPA LON Range valid only for blocks EV07 EV44 Can only be set from CAP 540 configuration tool INTERVAL 0 60 Step 1 0 s Cyclic sending of data Can only be set from CAP 540 configuration tool BOUND 0 1 0 Event connected to other terminals on ...

Page 174: ...162 Event function EV Chapter 10 Logic ...

Page 175: ...163 About this chapter Chapter 11 Monitoring Chapter 11 Monitoring About this chapter This chapter describes the monitoring functions ...

Page 176: ...tion before during and after the fault The collection is started by a trigger Any binary input signal or function block output signal can be used as a trigger The analog signals can also be set to trigger the data collection Both over levels and under levels are available The trigger is common for all subsystems hence it acti vates them all simultaneously A triggered report cycle is indicated by t...

Page 177: ...29 INPUT30 INPUT31 INPUT32 NAME17 NAME18 NAME19 NAME20 NAME21 NAME22 NAME23 NAME24 NAME25 NAME26 NAME27 NAME28 NAME29 NAME30 NAME31 NAME32 FUNCT17 FUNCT18 FUNCT19 FUNCT20 FUNCT21 FUNCT22 FUNCT23 FUNCT24 FUNCT25 FUNCT26 FUNCT27 FUNCT28 FUNCT29 FUNCT30 FUNCT31 FUNCT32 INFONO17 INFONO18 INFONO19 INFONO20 INFONO21 INFONO22 INFONO23 INFONO24 INFONO25 INFONO26 INFONO27 INFONO28 INFONO29 INFONO30 INFONO3...

Page 178: ... signal to be recorded as signal no xx were xx 1 48 NAME01 48 Signal name set by user 13 char for disturbance presentation FuncT01 48 Function type set by user for IEC InfoNo01 48 Information number set by user for IEC Signal Description OFF Disturbance Report function turned off RECSTART Disturbance recording started RECMADE Disturbance recording made MEMUSED More than 80 of recording memory used...

Page 179: ...0 5 6 0 Step 0 1 1 0 s Fault recording time limit Parameter Range Default Unit Description TrigOperation Off On Off Determines if the signal should trigger disturbance recording TrigLevel Trig on 1 Trig on 0 Trig on 1 Selects the trigger signal transition IndicationMask Hide Show Hide Determines if the signal should be included in the HMI indications list SetLed Off On Off Determines if the signal...

Page 180: ... HMI for the two latest recorded disturbances until cleared The information is not stored in the terminal On On or Off The disturbance report works as in normal mode Disturbances are stored Data can be read from the local HMI a front connected PC or SMS LED information yellow start red trip is stored The disturbance summary is scrolled automatically on the local HMI for the two latest recorded dis...

Page 181: ...urbance report and lists the changes in status in chronological order Each list can contain up to 150 time tagged events that can come from both internal logic signals and binary input channels and up to ten disturbances can be recorded Events are recorded during the total recording time which depends on the set recording times and the actual fault time Events can be viewed via SMS and SCS 2 3 Tec...

Page 182: ...rbance report function is triggered the function looks for non periodic change in the analog channels Once the fault interception is found the function calculates the pre fault RMS values during one period starting 1 5 period before the fault interception The fault values are calculated starting a few samples after the fault interception and uses samples during 1 2 2 periods depending on the wavef...

Page 183: ...he ter minal In order to retrieve actual values however the terminal must be equipped with the appro priate hardware measuring module s i e Transformer Input Module TRM 4 3 Function block Table 171 AC monitoring function block types Instance name DAnn Function block name Description DA01 DirAnalogIn_U1 Input voltage U1 DA02 DirAnalogIn_U2 Input voltage U2 DA03 DirAnalogIn_U3 Input voltage U3 DA04 ...

Page 184: ... active power P measured by the first three voltage and current inputs DA14 DirAnalogIn_Q Three phase reactive power Q measured by the first three voltage and current inputs DA15 DirAnalogIn_f Mean value of frequency f as measured by the volt age inputs U1 U2 and U3 DA16 DirAnalogIn_S Three phase apparent power S measured by the first three voltage and current inputs Instance name DAnn Function bl...

Page 185: ...LowWarn 0 0 1999 9 Step 0 1 170 0 kV Low Warning level for U1 U5 LowAlarm 0 0 1999 9 Step 0 1 160 0 kV Low Alarm level for U1 U5 RepInt 0 3600 Step 1 0 s Time between reports for U1 U5 in sec onds Zero Off duration of time interval between two reports at periodic reporting function Setting to 0 disables the periodic reporting EnDeadB Off On Off Enable amplitude dead band supervision for U1 U5 Dead...

Page 186: ...ad band for I1 I5 EnIDeadB Off On Off Enable integrating dead band supervision for I1 I5 IDeadB 0 99999 Step 1 10000 A Integrating dead band for I1 I5 EnDeadBP Off On Off Enable periodic dead band reporting I1 I5 Mean phase to phase voltage measuring channel U DA11 Operation Off On Off Operating mode for DAnn function Hysteres 0 0 1999 9 Step 0 1 5 0 kV Alarm hysteresis for U EnAlRem Off On On Imm...

Page 187: ... for I produces an immediate event at reset of any alarm monitoring element when On EnAlarms Off On Off Set to On to activate alarm supervision for I produces an immediate event at operation of any alarm monitoring element when On HiAlarm 0 99999 Step 1 900 A High Alarm level for I HiWarn 0 99999 Step 1 800 A High Warning level for I LowWarn 0 99999 Step 1 200 A Low Warning level for I LowAlarm 0 ...

Page 188: ...0 0 9999 9 Step 0 1 50 0 MW Low Alarm level for P RepInt 0 3600 Step 1 0 s Time between reports for P in seconds Zero Off duration of time interval between two reports at periodic reporting function Setting to 0 disables the periodic reporting EnDeadB Off On Off Enable amplitude dead band supervision for P DeadBand 0 0 9999 9 Step 0 1 1 0 MW Amplitude dead band for P EnIDeadB Off On Off Enable int...

Page 189: ...Step 0 1 1 0 Mvar Amplitude dead band for Q EnIDeadB Off On Off Enable integrating dead band supervision for Q IDeadB 0 0 9999 9 Step 0 1 10 0 Mvar Integrating dead band for Q EnDeadBP Off On Off Enable periodic dead band reporting Q Frequency measuring channel f DA15 Operation Off On Off Operating mode for DAnn function Hysteres 0 0 99 9 Step 0 1 1 0 Hz Alarm hysteresis for f EnAlRem Off On On Im...

Page 190: ...sabled for S produces an immediate event at reset of any alarm monitoring element when On EnAlarms Off On Off Set to On to activate alarm supervision for S produces an immediate event at operation of any alarm monitoring element when On HiAlarm 0 0 9999 9 Step 0 1 300 0 MVA High Alarm level for S HiWarn 0 0 9999 9 Step 0 1 200 0 MVA High Warning level for S LowWarn 0 0 9999 9 Step 0 1 80 0 MVA Low...

Page 191: ...o Events Enables Report Events or disables No Events the reporting of events from channel DA05 to the SCS EventMask I1 No Events Report Events No Events Enables Report Events or disables No Events the reporting of events from channel DA06 to the SCS EventMask I2 No Events Report Events No Events Enables Report Events or disables No Events the reporting of events from channel DA07 to the SCS EventM...

Page 192: ... disables No Events the reporting of events from channel DA14 to the SCS EventMask f No Events Report Events No Events Enables Report Events or disables No Events the reporting of events from channel DA15 to the SCS EventMask S No Events Report Events No Events Enables Report Events or disables No Events the reporting of events from channel DA16 to the SCS Parameter Range Default Unit Description ...

Page 193: ...181 About this chapter Chapter 12 Data communication Chapter 12 Data communication About this chapter This chapter describes the data communication and the associated hardware ...

Page 194: ...ics 1 2 Design common The hardware needed for applying LON communication depends on the application but one very central unit needed is the LON Star Coupler and optic fibres connecting the star coupler to the terminals To communicate with the terminals from a Personal Computer PC the SMS 510 software or and the application library LIB 520 together with MicroSCADA is needed The communciation altern...

Page 195: ...lCom SPA IEC LON Table 177 Setting parameter for selection of communication protocols for rear ports 1 4 Serial communication SPA 1 4 1 Application This communication bus is mainly used for SMS It can include different numerical relays ter minals with remote communication possibilities Connection to a personal computer PC can be made directly if the PC is located in the substation or by telephone ...

Page 196: ...m SPACom Front Table 179 Setting parameters for SPA communication front comm port 1 4 4 Technical data Table 180 Serial communication SPA rear communication port Parameter Range Default Unit Description SlaveNo 1 899 30 SPA bus identification number BaudRate 300 1200 2400 4800 9600 19200 38400 9600 Baud Communication speed ActGrpRestrict Open Block Open Open Access right to change between active g...

Page 197: ...guration The IEC 60870 5 103 protocol implementation in REx 5xx consists of these functions Event handling Report of analog service values measurements Fault location Command handling Autorecloser ON OFF Teleprotection ON OFF Protection ON OFF LED reset Characteristics 1 4 Setting groups File transfer disturbance files Function Value Protocol SPA IEC 60870 5 103 Communication speed 9600 Bd Functio...

Page 198: ...no 11 Local operation Glass or plastic fibre should be used for the optical ports BFOC2 5 is the recommended inter face to use BFOC2 5 is the same as ST connectors ST connectors are used with the optical power as specified in standard please see the Installation and commissioning manual For the galvanic interface RS485 use terminated network according to EIA Standard RS 485 The modem contact for t...

Page 199: ...h fault L1 Yes 49 Earth fault L2 Yes 50 Earth fault L3 Yes 51 Earth fault forward e g Iine Yes 52 Earth fault reverse e g bus bar Yes 64 Start pickup L1 Yes 65 Start pickup L2 Yes 66 Start pickup L3 Yes 67 Start pickup N Yes 68 General trip Yes 69 Trip L1 Yes 70 Trip L2 Yes 71 Trip L3 Yes 72 Trip I back up operation Yes 73 Fault location X in Ohm Yes 74 Fault forward line Yes 75 Fault reverse busb...

Page 200: ... Q f Yes 240 Read headings of all defined groups No 241 Read values of all entries of one group No 243 Read directory of a single entry No 244 Read value of a single entry No 245 End of general interrogation generic data No 249 Write entry with confirmation No 250 Write entry with execution No Info no Message Supported 16 Autorecloser on off Yes 17 Teleprotection on off Yes 18 Protection on off Ye...

Page 201: ...o 251 Write entry abort No Measurand Rated value 1 2 2 4 Current L1 Yes Current L2 Yes Current L3 Yes Voltage L1 E Yes Voltage L2 E Yes Voltage L3 E Yes Voltage L1 L2 Yes Active power P Yes Reactive power Q Yes Supported Electrical Interface EIA RS485 NoYes number of loads No4 Optical Interface glass fibre Yes plastic Yes Transmission Speed 9600 bit s Yes 19200 bit s Yes Link Layer DFC bit used Ye...

Page 202: ... recorded disturbances Yes 26 Ready for transm of disturbance data Yes 27 Ready for transm of a channel Yes 28 Ready for transm of tags Yes 29 Transmission of tags Yes 30 Transmission of disturbance data Yes 31 End of transmission Yes Selection of standard ASDUs in control direction ASDU 6 Time synchronization Yes 7 General interrogation Yes 10 Generic data No 20 General command Yes 21 Generic com...

Page 203: ...YPE Main function type operation for terminal Signal Description ARBLOCK Command used for switching autorecloser on off ZCOMBLK Command used for switching teleprotection on off BLKFNBLK Command used for switching protection on off LEDRS Command used for resetting the LEDs SETG1 Command used for activation of setting group 1 SETG2 Command used for activation of setting group 2 SETG3 Command used fo...

Page 204: ...ocal HMI Configuration TerminalCom IECCom Measurands Table 195 Setting parameter for measurand type Path in local HMI Configuration TerminalCom IECCom FunctionType Parameter Range Default Unit Parameter description Operation On Off Off Operation mode of autorecloser com mand On Blocked Off Released Parameter Range Default Unit Parameter description Operation On Off Off Operation mode of protection...

Page 205: ...station Automation system This enables commu nication with the terminal through the LON bus from the operator s workplace from the control center and also from other terminals Parameter Range Default Unit Parameter description Operation On Off Off MainFuncType 1 255 Main function types according to the stan dard Parameter Range Default Unit Parameter description SlaveNo 0 255 30 Slave number BaudR...

Page 206: ... in local HMI Configuration TerminalCom LONCom NodeInfo AddressInfo These parameters can only be set with the LNT LON Network Tool They can be viewed in the local HMI Table 201 Setting parameters for the LON communication Path in local HMI Configuration TerminalCom LONCom NodeInfo These parameters can only be set with the LNT LON Network Tool They can be viewed in the local HMI Table 202 LON node ...

Page 207: ...ering the terminal Parameter Range Default Unit Parameter description SessionTmo 1 60 20 s Session timeout Only to be changed after recommendation from ABB RetryTmo 100 10000 2000 ms Retransmission timeout Only to be changed after recommendation from ABB IdleAckCycle 1 30 5 s Keep active ack Only to be changed after recommendation from ABB BusyAckTmo 100 5000 300 ms Wait before sending ack Only to...

Page 208: ...f connection is chosen when ordering the terminal The incoming optical fibre is connected to the Rx receiver input and the outgoing optical fibre to the Tx transmitter output The module is identified with a number on the label on the module 1 7 3 Technical data Table 206 Optical fibre connection requirements for SPA IEC Table 207 RS485 connection requirements for SPA IEC Note Pay special attention...

Page 209: ...12 Data communication Table 208 LON Optical fibre connection requirements for LON bus Glass fibre Plastic fibre Cable connector ST connector HFBR Snap in connector Fibre diameter 62 5 125 μm 50 125 μm 1 mm Max cable length 1000 m 25 m ...

Page 210: ...198 Serial communication Chapter 12 Data communication ...

Page 211: ...199 About this chapter Chapter 13 Hardware modules Chapter 13 Hardware modules About this chapter This chapter describes the different hardware modules ...

Page 212: ... communication Carries up to 12 digital signal processors performing all measur ing functions Human machine interface LCD HMI The module consist of LED s a LCD push buttons and an optical connector for a front connected PC Signal processing module SPM Module for protection algorithm processing Carries up to 12 digital signal processors performing all measur ing functions Module Description Binary ...

Page 213: ... two shunts with separate A D channels are used for each input current By that a 16 bit dynamic range is obtained with a 12 bits A D con verter The input signals passes an anti aliasing filter with a cut off frequency of 500 Hz Each input signal 5 voltages and 5 currents is sampled with a sampling frequency of 2 kHz The A D converted signals are low pass filtered with a cut off frequency of 250 Hz...

Page 214: ... a parallel core used for CT circuit supervi sion function or independent earth fault function Phase voltages Open delta voltage for the protected line for an optional directional earth fault protection Phase voltage for an optional synchronism and energizing check 3 2 Technical data Table 211 TRM Energizing quantities rated values and limits Quantity Rated value Nominal range Current Ir 1 or 5 A ...

Page 215: ...le between 1 40 Hz Binary input voltage RL 24 30 VDC 20 48 60 VDC 20 110 125 VDC 20 220 250 VDC 20 Power dissipation max 0 05 W input 0 1 W input 0 2 W input 0 4 W input Only available for BIM Function or quantity Trip and Signal relays Fast signal relays Binary outputs BOM 24 PSM 4 Max system voltage 250 V AC DC 250 V AC DC Test voltage across open contact 1 min 1000 V rms 800 V DC Current carryi...

Page 216: ...204 Binary I O capabilities Chapter 13 Hardware modules Table 214 Power consumption Module Power consumption Binary input module BIM 0 5 W Binary output module BOM 1 0 W ...

Page 217: ...et to release the input at a chosen frequency making it possible to use the input for pulse counting The blocking frequency may also be set 5 3 Function block Figure 80 Binary input module 5 4 Input and output signals Table 215 Input signals for binary input module BIM Path in local HMI ServiceReport IO Slotnn BIMn FuncOutputs BINAME01 BINAME02 BINAME03 BINAME04 BINAME05 BINAME06 BINAME07 BINAME08...

Page 218: ...206 Binary input module BIM Chapter 13 Hardware modules Table 216 Output signals for binary input module BIM Signal Description ERROR Binary module fail BI1 BI16 Binary input data ...

Page 219: ...urpose 6 2 Design The binary output module BOM has 24 software supervised output relays Two relays share a common power source input This should be considered when connecting the wiring to the con nection terminal on the back of the IED Figure 81 Relay pair example 1 Output connection from relay 1 2 Ootput signal power source connection 3 Output connection from relay 2 xx00000299 vsd 2 1 3 Output ...

Page 220: ...AME02 BONAME03 BONAME04 BONAME05 BONAME06 BONAME07 BONAME08 BONAME09 BONAME10 BONAME11 BONAME12 BONAME13 BONAME14 BONAME15 BONAME16 BONAME17 BONAME18 BONAME19 BONAME20 BONAME21 BONAME22 BONAME23 BONAME24 BO1 BO2 BO3 BO4 BO5 BO6 BO7 BO8 BO9 BO10 BO11 BO12 BO13 BO14 BO15 BO16 BO17 BO18 BO19 BO20 BO21 BO22 BO23 BO24 BLKOUT xx00000156 vsd Signal Description POSITION I O module slot position BO1 BO24 B...

Page 221: ...e power supply module PSM has four optically isolated binary inputs and four output relays 7 3 Function block Figure 83 Binary I O on the power supply module PSM 7 4 Input and output signals Table 219 Input signals for the I O module IO02 function block I O on PSM Path in local HMI ServiceReport I O slotnn PSMn FuncOutputs IO02 I O MODULE POSITION BLKOUT BO1 BO2 BO3 BO4 BONAME01 BONAME02 BONAME03 ...

Page 222: ...e 220 Output signals for the I O module IO02 function block I O on PSM 7 5 Technical data Table 221 PSM Power Supply Module Signal Description ERROR I O module fail BI1 BI4 Binary input data Quantity Rated value Nominal range Auxiliary dc voltage EL 48 250 V 20 ...

Page 223: ...rom you as an operator Use the terminals built in communication functionality to establish SMS communication with a PC with suitable software tool Connect the PC to the optical connector on the local HMI with the special front communication cable including an opto electrical converter for disturbance free and safe communication 8 2 Design Figure 84 The LCD HMI module 1 Status indication LEDs 2 LCD...

Page 224: ...D HMI Chapter 13 Hardware modules The number of buttons used on the HMI module is reduced to a minimum to allow a communi cation as simple as possible for the user The buttons normally have more than one function depending on actual dialogue ...

Page 225: ...213 Serial communication modules SCM Chapter 13 Hardware modules 9 Serial communication modules SCM 9 1 SPA IEC Refer to chapter Data communication 9 2 LON Refer to chapter Data communication ...

Page 226: ...214 Serial communication modules SCM Chapter 13 Hardware modules ...

Page 227: ...215 Chapter 14 Diagrams Chapter 14 Diagrams This chapter contains the terminal diagrams for the terminal ...

Page 228: ...216 Terminal diagrams Chapter 14 Diagrams 1 Terminal diagrams 1 1 Terminal diagram Rex5xx Figure 85 Hardware structure of the 1 2 of full width 19 case ...

Page 229: ...217 Terminal diagrams Chapter 14 Diagrams 1 2 Terminal diagram REL 501 C1 Figure 86 REL 501 C1 ...

Page 230: ...218 Terminal diagrams Chapter 14 Diagrams Figure 87 REL 501 C1 with DC switch ...

Page 231: ...219 Terminal diagrams Chapter 14 Diagrams Figure 88 REL 501 C1 transformer input module and A D conversion module 3 phase sys tem ...

Page 232: ...220 Terminal diagrams Chapter 14 Diagrams Figure 89 REL 501 C1 transformer input module and A D conversion module 3 phase sys tem with RTXP 24 internal earthing ...

Page 233: ...221 Terminal diagrams Chapter 14 Diagrams Figure 90 REL 501 C1 transformer input module and A D conversion module 3 phase sys tem with RTXP 24 external earthing ...

Page 234: ...222 Terminal diagrams Chapter 14 Diagrams ...

Page 235: ...223 About this chapter Chapter 15 Configuration Chapter 15 Configuration About this chapter This chapter refer to the configuration in CAP 540 ...

Page 236: ...224 Configuration Chapter 15 Configuration 1 Configuration Configuration of REL 501 C1 is available as templates in the latest version of CAP 540 ...

Page 237: ......

Page 238: ... AB Substation Automation Products SE 721 59 Västerås Sweden Telephone 46 0 21 34 20 00 Facsimile 46 0 21 14 69 18 www abb com substationautomation 1MRK 506 187 UEN Printed on recycled and ecolabelled paper at Elanders Novum ...

Reviews: