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ABB REL670 Installation And Commissioning Manual

ABB REL670 Installation And Commissioning Manual

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Installation and commissioning manual
Line distance protection IED
REL670
About this manual
Document No: 1MRK 506 234-UEN
Issued: January 2006
Revision: A
© Copyright 2006 ABB. All rights reserved.

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Summary of Contents for ABB REL670

  • Page 1 Installation and commissioning manual Line distance protection IED REL670 About this manual Document No: 1MRK 506 234-UEN Issued: January 2006 Revision: A © Copyright 2006 ABB. All rights reserved.
  • Page 2 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 INFORMATION PRODUCT. Manufacturer: ABB Power Technologies AB Substation Automation Products SE-721 59 Västerås Sweden...
  • Page 3: Table Of Contents

    Contents Chapter Page Chapter 1 Introduction ..............1 Introduction to the installation and commissioning manual ....2 About the complete set of manuals for an IED ....... 2 About the installation and commissioning manual......2 Intended audience ................3 Related documents................. 3 Revision notes ................
  • Page 4 Contents Side-by-side flush mounting ............27 Side-by-side flush mounting details ......... 27 Making the electrical connection............29 Configuration for analog CT inputs ..........31 Connecting to CT and VT circuits ..........31 Connecting the auxiliary power and signal connectors....32 Connecting to protective earth............
  • Page 5 Contents Chapter 9 Establishing connection and verifying the LON communication ..........59 The LON Protocol ................. 61 Hardware and software modules ..........61 Chapter 10 Configuring the IED and changing settings ....65 Overview.................... 66 Entering settings through the local HMI..........67 Analog input data................
  • Page 6 Contents Two step overvoltage protection (POVM, 59)......118 Two step residual overvoltage protection (POVM, 59N)..... 118 Frequency protection ............... 120 Underfrequency protection (PTUF, 81)........120 Overfrequency protection (PTOF, 81) ........121 Rate-of-change frequency protection (PFRC, 81) ...... 122 Multipurpose protection ..............124 General current and voltage protection (GAPC)......
  • Page 7 Contents Using front-connected PC or SMS..........175 Repair instruction................178 Repair support ................. 180 Maintenance ..................181 Chapter 14 Glossary............... 183 Glossary................... 184...
  • Page 8 Contents...
  • Page 9: Chapter 1 Introduction

    About this chapter Chapter 1 Introduction Chapter 1 Introduction About this chapter This chapter introduces the user to the manual.
  • Page 10: Introduction To The Installation And Commissioning Manual

    Introduction to the installation and Chapter 1 commissioning manual Introduction Introduction to the installation and commissioning manual About the complete set of manuals for an IED The user’s manual (UM) is a complete set of four different manuals: Application Technical Installation and Operator´s manual...
  • Page 11: Intended Audience

    The commissioning and maintenance personnel must be well experienced in using protection equipment, test equipment, protection functions and the configured functional logics in the protection. Related documents Documents related to REL670 Identity number Operator’s manual 1MRK 505 233-UEN...
  • Page 12: Revision Notes

    Introduction to the installation and Chapter 1 commissioning manual Introduction Documents related to REL670 Identity number Connection diagram, Multi breaker arr. Single phase tripping arr. 1MRK 002 801-EA Configuration diagram A, Single breaker with single or double busbar 1MRK 004 500-86...
  • Page 13: Chapter 2 Safety Information

    About this chapter Chapter 2 Safety information Chapter 2 Safety information About this chapter This chapter contains safety information. Warning signs are presented which urge the user to be careful during certain operations in order to avoid injuries to humans or damage to equipment.
  • Page 14: Warning Signs

    Warning signs Chapter 2 Safety information Warning signs Warning! Strictly follow the company and country safety regulations. Working in a high voltage environ- ment requires serious approach to avoid human injuries and damage to equipment. Warning! Do not touch circuitry during operation. Potentially lethal voltages and currents are present. Warning! Always use suitable isolated test pins when measuring signals in open circuitry.
  • Page 15: Caution Signs

    Caution signs Chapter 2 Safety information Caution signs Caution! Always transport PCBs (modules) using certified conductive bags. Always handle modules us- ing a conductive wrist strap connected to protective ground and on a suitable antistatic surface. Electrostatic discharge (ESD) may cause damage to the module since electronic circuits are sensitive to this phenomena.
  • Page 16: Note Signs

    Note signs Chapter 2 Safety information Note signs Note! The protection assembly is designed for a maximum continuous current of four times rated val-...
  • Page 17: Chapter 3 Overview

    About this chapter Chapter 3 Overview Chapter 3 Overview About this chapter This chapter outlines the installation and commissioning of the IED.
  • Page 18: Commissioning And Installation Overview

    Commissioning and installation overview Chapter 3 Overview Commissioning and installation overview The settings for each function must be calculated before the commissioning task can start. A configuration, done in the configuration and programming tool, must also be available if the IED does not have a factory configuration downloaded.
  • Page 19: Chapter 4 Unpacking And Checking The Ied

    About this chapter Chapter 4 Unpacking and checking the IED Chapter 4 Unpacking and checking the IED About this chapter This chapter describes the delivery and the unpacking of the IED...
  • Page 20: Taking Delivery, Unpacking And Checking

    If transport damage is discovered appropriate action must be taken against the latest carrier and the nearest ABB office or representative should be informed. ABB should be notified immediately if there are any discrepancies in relation to the delivery documents.
  • Page 21: Chapter 5 Installing The Ied

    About this chapter Chapter 5 Installing the IED Chapter 5 Installing the IED About this chapter This chapter describes how to install the IED.
  • Page 22: Overview

    Overview Chapter 5 Installing the IED Overview The mechanical and electrical environmental conditions at the installation site must be within the limits described in the IED technical data. Dusty, damp places, places susceptible to rapid temperature variations, powerful vibrations and shocks, surge voltages of high amplitude and fast rise time, strong induced magnetic fields or similar extreme conditions should be avoided.
  • Page 23: Dimensions

    Dimensions Chapter 5 Installing the IED Dimensions Case without rear cover xx04000448.vsd xx04000464.vsd Figure 1: Case without rear cover Figure 2: Case without rear cover with 19” rack mounting kit Case size 6U, 1/2 x 19” 265.9 223.7 204.1 252.9 205.7 190.5 203.7...
  • Page 24: Case With Rear Cover

    Dimensions Chapter 5 Installing the IED Case with rear cover xx05000502.vsd xx05000501.vsd Figure 4: Case with rear cover and 19” rack mounting kit. Figure 3: Case with rear cover. xx05000503.vsd Figure 5: Rear cover case with details. Case size 6U, 1/2 x 19” 265.9 223.7 242.1...
  • Page 25: Mounting Dimensions

    Dimensions Chapter 5 Installing the IED Mounting dimensions Flush mounting xx04000465.vsd Cut-out dimensions (mm) Case size Tolerance +/-1 +/-1 6U, 1/2 x 19” 210.1 254.3 4-10 12.5 6U, 3/4 x 19” 322.4 254.3 4-10 12.5 6U, 1/1 x 19” 434.7 254.3 4-10 12.5...
  • Page 26: Side-By-Side Flush Mounting Dimensions

    Dimensions Chapter 5 Installing the IED Side-by-side flush mounting dimensions xx05000504.vsd Figure 6: A 3/4 size IED from the 600 series together with RHGS6 case in 19” rack.
  • Page 27 Dimensions Chapter 5 Installing the IED xx05000505.vsd Case size ±1 ±1 ±1 ±1 ±1 ±1 ±1 Tolerance 6U x 1/2 of 19” 214.0 259.3 240.4 190.5 34.4 13.4 6.4 diam 6U x 3/4 of 19” 326.7 259.3 352.8 190.5 34.4 13.4 6.4 diam 6U x 1/1 of 19”...
  • Page 28: Mounting Methods And Details

    Mounting methods and details Chapter 5 Installing the IED Mounting methods and details Mounting the IED Most of the REx670 IEDs can be rack, flush or wall mounted with the use of different mounting kits. An additional box of type RHGS can be mounted to one side of a 1/2 or 3/4 IED. A suitable mounting kit is available.
  • Page 29: Flush Mounting Details

    Mounting methods and details Chapter 5 Installing the IED 3.2.1 Flush mounting details panel en04000451.vsd PosNo Description Sealing strip, used to obtain IP54 class. The sealing strip is factory mounted between the case and front plate. Four side holders Groove Four locking screws Sealing strip Figure 8:...
  • Page 30: 19" Panel Rack Mounting

    Mounting methods and details Chapter 5 Installing the IED 19” panel rack mounting 3.3.1 19” panel mounting details xx04000452.vsd PosNo Description 1a, 1b Two rack flanges, which can be mounted, either to the left or right side of the case. Eight fastening screws.
  • Page 31: Wall Mounting

    Mounting methods and details Chapter 5 Installing the IED Wall mounting All case sizes, 1/2, 3/4 and 1/1, can be wall mounted. It is also possible to mount the IED on a panel or in a cubicle. 3.4.1 Wall mounting details xx04000453.vsd PosNo Description...
  • Page 32: Protection Cover

    Mounting methods and details Chapter 5 Installing the IED Depending on the wall different preparations may be needed like drilling and inserting plastic or expander plugs (concrete/plasterboard walls) or threading (metal sheet wall). Mount the DIN-rail(s) on the mounting bars. Mount the IED blocks on the DIN-rail(s).
  • Page 33: Side-By-Side Rack Mounting

    Mounting methods and details Chapter 5 Installing the IED View from above 80 mm en04000455.vsd PosNo Description Screws Fixing screws Figure 12: How to reach the connectors on the rear side of the IED. Procedure Remove the inner screws (PosNo 1), upper and lower on one side. Remove all three fixing screws (PosNo 2), on the opposite side, from wall support.
  • Page 34: Side-By-Side Rack Mounting Details

    Mounting methods and details Chapter 5 Installing the IED 3.5.1 Side-by-side rack mounting details xx04000456.vsd PosNo Description Two mounting plates Eight screws Eight fastening screws Two mounting angles Figure 13: Side-by-side rack mounting details. 3.5.2 Mounting procedure for side-by-side rack mounting Procedure Place the two IEDs next to each other on a flat surface.
  • Page 35: Side-By-Side Flush Mounting

    Mounting methods and details Chapter 5 Installing the IED Side-by-side flush mounting It is not recommended to flush mount side by side mounted cases. If your application demands this type of installation, use the side-by-side mounting details kit and the 19” panel mounting kit.
  • Page 36 Mounting methods and details Chapter 5 Installing the IED Fasten a side-by-side mounting plate (PosNo 1) Use four of the delivered screws (PosNo 2). Carefully turn the two IEDs up-side down Fasten the second side-by-side mounting plate Use the remaining four screws. Carefully fasten the mounting angles to the sides of the IED (PosNo 4) Use the fixing screws available in the mounting kit (PosNo 3).
  • Page 37: Making The Electrical Connection

    Making the electrical connection Chapter 5 Installing the IED Making the electrical connection Table 1: Designations for 1/2 x 19” casing with 1 TRM slot Module Rear Positions BIM, BOM or X31 and X32 etc. to X51 and X52 X301:A, B, C, D LDCM X302:A, B LDCM...
  • Page 38 Making the electrical connection Chapter 5 Installing the IED Table 3: Designations for 3/4 x 19” casing with 2TRM slot Module Rear Positions BIM, BOM, IOM or MIM X31 and X32 etc. to X71 and X72 X301:A, B, C, D LDCM X302:A, B LDCM...
  • Page 39: Configuration For Analog Ct Inputs

    Making the electrical connection Chapter 5 Installing the IED Table 5: Designations for 1/1 x 19” casing with 2 TRM slots Module Rear Positions BIM, BOM or X31 and X32 etc. to X131 and X132 X31, X41, etc. or X131 X131 X301:A, B, C, D LDCM...
  • Page 40: Connecting The Auxiliary Power And Signal Connectors

    Making the electrical connection Chapter 5 Installing the IED Connecting the auxiliary power and signal connectors 4.3.1 Connecting the auxiliary power and signal connectors Auxiliary power and signals are connected using voltage connectors. Signal wires are connected to female connector see figure 15, which is then plugged into the corresponding male connector figure...
  • Page 41: Connecting To Protective Earth

    Making the electrical connection Chapter 5 Installing the IED Figure 16: Board with male connectors xx01000050.vsd Where: is ferrule Figure 17: Connected cables with ferrules. Connecting to protective earth Connect the earthing screws on the rear of the IED unit to the closest possible earthing point in the cubicle.
  • Page 42: Making The Screen Connection

    Making the electrical connection Chapter 5 Installing the IED The cubicle must be properly connected to the station earthing system. Use a conductor with a core cross section area of at least 4 mm (AWG 12). en05000509.vsd where: is main protective earth to chassis is earthing screw to Power Supply Module is earthing screw to TRM.
  • Page 43 Making the electrical connection Chapter 5 Installing the IED External Equipment en03000087.vsd Figure 19: Communication cable installation.
  • Page 44: Installing The Optical Fibres

    Installing the optical fibres Chapter 5 Installing the IED Installing the optical fibres General Connectors are generally color coded; connect blue or dark grey cable connectors to blue or dark grey (receive) back-side connectors. Connect black or grey cable connectors to black or grey (transmit) back-side connectors.
  • Page 45: Installing The Gps Antenna

    Installing the GPS antenna Chapter 5 Installing the IED Installing the GPS antenna Antenna installation In order to receive GPS signals from the satellites orbiting the earth a GPS antenna must be used. 6.1.1 Mechanical installation The antenna is mounted on a console for mounting on a horizontal or vertical flat surface or on an antenna mast.
  • Page 46 Installing the GPS antenna Chapter 5 Installing the IED Always position the antenna and its console so that a continuous clear line-of-sight visibility to all directions is obtained, preferably more than 75%. A minimum of 50% clear line-of-sight vis- ibility is required for un-interrupted operation. 99001046.vsd Figure 20: Antenna line-of-sight...
  • Page 47: Checking The External Optical And Electrical Connections

    About this chapter Chapter 6 Checking the external optical and electrical connections Chapter 6 Checking the external optical and electrical connecti About this chapter This chapter describes what to check to ensure correct connection to the external circuitry, such as the auxiliary power supply, CT’s and VT’s. These checks must be made with the protection IED de-energized.
  • Page 48: Overview

    Overview Chapter 6 Checking the external optical and electrical connections Overview The user must check the installation which includes verifying that the IED is connected to the other parts of the protection system. This is done with the IED and all connected circuits de-en- ergized.
  • Page 49: Checking The Vt Circuits

    Checking the VT circuits Chapter 6 Checking the external optical and electrical connections Checking the VT circuits Check that the wiring is in strict accordance with the supplied connection diagram. Note! Do not continue before any errors are corrected. Test the circuitry. The following tests are recommended: •...
  • Page 50: Check Of Ct Circuits

    Check of CT circuits Chapter 6 Checking the external optical and electrical connections Check of CT circuits The CTs must be connected in accordance with the circuit diagram provided with the IED, both with regards to phases and polarity. The following tests shall be performed on every primary CT connected to the REx670 IED: •...
  • Page 51: Checking The Power Supply

    Checking the power supply Chapter 6 Checking the external optical and electrical connections Checking the power supply Check that the auxiliary supply voltage remains within the permissible input voltage range under all operating conditions. Check that the polarity is correct.
  • Page 52: Checking The Binary I/O Circuits

    Checking the binary I/O circuits Chapter 6 Checking the external optical and electrical connections Checking the binary I/O circuits Binary input circuits Preferably, disconnect the binary input connector from the binary input cards. Check all con- nected signals so that both input level and polarity are in accordance with the IEDs specifica- tions.
  • Page 53: Checking The Optical Connections

    Checking the optical connections Chapter 6 Checking the external optical and electrical connections Checking the optical connections Check that the Tx and Rx optical connections are correct.
  • Page 54 Checking the optical connections Chapter 6 Checking the external optical and electrical connections...
  • Page 55: Energizing The Ied

    About this chapter Chapter 7 Energizing the IED Chapter 7 Energizing the IED About this chapter This chapter describes the start up sequence and what to check once the IED has been energized.
  • Page 56: Overview

    Overview Chapter 7 Energizing the IED Overview Before the procedures in this chapter can be carried out the connection to external circuitry must have been checked which ensures that the installation was made correctly. The user must energize the power supply of the IED to start it up. This could be done in number of ways, from energizing a whole cubicle to energizing a single IED.
  • Page 57: Energizing The Ied

    Energizing the IED Chapter 7 Energizing the IED Energizing the IED When the IED is energized, the green LED instantly starts flashing. After approximately 55 sec- onds the window lights up and the window displays ‘IED Startup’. The main menu is displayed and the upper row should indicate ‘Ready’...
  • Page 58 Energizing the IED Chapter 7 Energizing the IED en05000055.eps Figure 22: Example of the local HMI. 1. Status indication LEDs 2. LCD 3. Indication LEDs 4. Label 5. Local/Remote LEDs 6. RJ 45 port 7. Communication indication LED 8. Keypad...
  • Page 59: Checking The Self Supervision Signals

    Checking the self supervision signals Chapter 7 Energizing the IED Checking the self supervision signals Reconfiguring the IED I/O modules configured as logical I/O modules (BIM, BOM or IOM) are supervised. I/O modules that are not configured are not supervised. Each logical I/O module has an error flag that indicates signal or module failure.
  • Page 60: Self Supervision Hmi Data

    No problem detected. None. NUM-modWarning There is a problem with: Set the clock. Warning • the real time clock. If the problem persists, contact your ABB repre- sentative for service. • the time synchroniza- tion. ADC-module OK No problem detected. None.
  • Page 61: Establishing Connection And Verifying The Spa/Iec-Communication

    About this chapter Chapter 8 Establishing connection and verifying the SPA/IEC-communication Chapter 8 Establishing connection and verifying the SPA/IEC-communi cation About this chapter This chapter contains instructions on how to establish connection and verify that the SPA/IEC-communication operates as intended, when the IED is connected to a monitoring or control system via the rear SPA/IEC port.
  • Page 62: Entering Settings

    Entering settings Chapter 8 Establishing connection and verifying the Entering settings If the IED is connected to a monitoring or control system via the rear SPA/IEC port, the SPA/IEC port has to be set either for SPA or IEC use. Entering SPA settings When using the SPA protocol, the rear SPA/IEC port must be set for SPA use.
  • Page 63 Entering settings Chapter 8 Establishing connection and verifying the SPA/IEC-communication Procedure Set the operation of the rear SPA/IEC port to “IEC”. The operation of the rear SPA/IEC port can be found on the local HMI at: Settings\General settings\Communication\SLM configuration\Rear optical SPA/IEC port\Protocol selection SPA or IEC 103 When the setting is entered the IED will automatically restart.
  • Page 64: Verifying The Communication

    Verifying the communication Chapter 8 Establishing connection and verifying the Verifying the communication To verify that the rear communication with the SMS/SCS system is working, there are some dif- ferent methods. Choose one of the following. Verifying SPA communication Procedure Use a SPA-emulator and send “RF”...
  • Page 65: Fibre Optic Loop

    Fibre optic loop Chapter 8 Establishing connection and verifying the SPA/IEC-communication Fibre optic loop The SPA communication is mainly used for SMS. It can include different numerical relays/ter- minals with remote communication possibilities. The fibre optic loop can contain < 20-30 ter- minals depending on requirements on response time.
  • Page 66: Optical Budget Calculation For Serial Communication With Spa/Iec

    Optical budget calculation for serial Chapter 8 communication with SPA/IEC Establishing connection and verifying the Optical budget calculation for serial communication with SPA/IEC Table 8: Example Distance 1 km Distance 25 m Glass Plastic Maximum attenuation for IED670 - 11 dB - 7 dB 4 dB/km multi mode: 820 nm - 62.5/125 um 4 dB...
  • Page 67: Chapter 9 Establishing Connection And Verifying The Lon Communication

    About this chapter Chapter 9 Establishing connection and verifying the LON communication Chapter 9 Establishing connection and verifying the LON communic ation About this chapter This chapter explains how to set up LON communication and how to verify that LON commu- nication is up and running.
  • Page 68 About this chapter Chapter 9 Establishing connection and verifying the LON communication Control Center Station HSI MicroSCADA Gateway Star coupler RER 111 IED670 IED670 IED670 en05000663.vsd Figure 24: Example of LON communication structure for a substation automation system. An optical network can be used within the Substation Automation system. This enables commu- nication with the 670IEDs through the LON bus from the operator’s workplace, from the control center and also from other IEDs via bay-to-bay horizontal communication.
  • Page 69: The Lon Protocol

    About this chapter Chapter 9 Establishing connection and verifying the LON communication The LON Protocol The LON protocol is specified in the LonTalkProtocol Specification Version 3 from Echelon Corporation. This protocol is designed for communication in control networks and is a peer-to-peer protocol where all the devices connected to the network can communicate with each other directly.
  • Page 70 There are a number of session timers which can be set via the local HMI. These settings are only for advanced use and should only be changed after recommendation from ABB. Path in local HMI:Settings\General settings\Communication\SLM configuration\Rear optical LON port These parameters can only be set with the LNT, LON Network Tool.
  • Page 71 Setting parameters for the session timers Parameter Range Default Unit Parameter description SessionTmo 1-60 Session timeout. Only to be changed after recommendation from ABB. RetryTmo 100-10000 2000 Retransmission timeout.Only to be changed after recommendation from ABB. IdleAckCycle 1-30 Keep active ack.Only to be changed after recommendation from ABB.
  • Page 72 About this chapter Chapter 9 Establishing connection and verifying the LON communication...
  • Page 73: Chapter 10 Configuring The Ied And Changing Settings

    About this chapter Chapter 10 Configuring the IED and changing settings Chapter 10 Configuring the IED and changing settings About this chapter This chapter describes how to change IED settings, either through a PC or the local HMI, and download a configuration to the IED in order to make commissioning possible. The chapter does not contain instructions on how to create a configuration or calculate settings.
  • Page 74: Overview

    Overview Chapter 10 Configuring the IED and changing settings Overview The customer specific values for each setting parameter and a configuration file have to be avail- able before the IED can be set and configured, if the IED is not delivered with a configuration. Use the PCM600 configuration tool to verify that the IED has the expected configuration.
  • Page 75: Entering Settings Through The Local Hmi

    Entering settings through the local HMI Chapter 10 Configuring the IED and changing settings Entering settings through the local HMI Each of the included functions in the IED has to be set and this can be performed through the local HMI. The user must browse to the desired function and enter the appropriate value. The parameters for each function can be found in the local HMI.
  • Page 76: Analog Input Data

    Analog input data Chapter 10 Configuring the IED and changing settings Analog input data In order to get correct measurement results as well as correct protection functionality, the analog input channels must be configured. Because all protection algorithms in the IED utilize the pri- mary system quantities it is extremely important to make sure that connected current transformer settings are done properly.
  • Page 77: Downloading Settings And Configuration From A Pc

    Downloading settings and configuration from Chapter 10 a PC Configuring the IED and changing settings Downloading settings and configuration from a PC Downloading the configuration and setting files When downloading a configuration to the REx670 IED with the CAP531 configuration tool, the IED is automatically set in configuration mode.
  • Page 78 Downloading settings and configuration from Chapter 10 a PC Configuring the IED and changing settings...
  • Page 79: Chapter 11 Verifying Settings By Secondary Injection

    About this chapter Chapter 11 Verifying settings by secondary injection Chapter 11 Verifying settings by secondary injection About this chapter This chapter describes how to verify that protection functions operate correctly and according to their settings. It is preferable that only the tested function is in operation.
  • Page 80: Overview

    Overview Chapter 11 Verifying settings by secondary injection Overview IED test requirements: • Calculated settings • Application configuration diagram • Signal matrix (SMT) configuration • Terminal diagram • Technical reference manual • Three-phase test equipment • PCM600 The setting and configuration of the IED must be completed before the testing can start. The terminal diagram, available in the Technical reference manual, is a general diagram of the IED.
  • Page 81 Overview Chapter 11 Verifying settings by secondary injection Note! Please observe the measuring accuracy of the IED, the test equipment and the angular accuracy for both of them. Note! Please consider the configured logic from the function block to the output contacts when mea- suring the operate time.
  • Page 82: Preparing For Test

    Preparing for test Chapter 11 Verifying settings by secondary injection Preparing for test Overview This section describes how to prepare the IED to verify settings. If a test switch is included, start preparation by making the necessary connections to the test switch.
  • Page 83: Putting The Ied Into Test Mode

    Preparing for test Chapter 11 Verifying settings by secondary injection Warning! Never disconnect the secondary connection of a current transformer circuit without short-cir- cuiting the transformer's secondary winding. Operating a current transformer with the second- ary winding open will cause a massive potential build up that may damage the transformer and injure humans.
  • Page 84: Verifying The Connections And The Analog Inputs

    Preparing for test Chapter 11 Verifying settings by secondary injection IN (I4,I5) UN (U4,U5) TRIP L1 TRIP L2 TRIP L3 IEC61850 en05000467.vsd Figure 25: Connection of the test set to the REx670 IED Verifying the connections and the analog inputs The user must verify that the connections are correct and that the analog signals are measured correctly.
  • Page 85: Releasing The Function(S) To Be Tested

    Preparing for test Chapter 11 Verifying settings by secondary injection Compare the frequency reading with the set frequency and the direc- tion of the power with the injected power. The frequency and active power are located in the local HMI under: Measurements\Monitoring\ServiceValues\SVR Inject an unsymmetrical three-phase current and voltage at rated val- ue in two phases.
  • Page 86: Disturbance Report

    Preparing for test Chapter 11 Verifying settings by secondary injection Test\Function test modes\function category\function instance Browse to the function instance that should be released. Use the left and right arrow buttons. Press ‘E’ when the desired function has been found. Select ‘Yes’.
  • Page 87: Identifying The Function To Test In The Technical Reference Manual

    Preparing for test Chapter 11 Verifying settings by secondary injection It could be useful to have a printer for hard copies. The behavior of the disturbance recording function can be checked when IED protective functions are tested. When the IED is set to oper- ate in test mode, there is a separate setting for operation of the disturbance report, which also affects the disturbance recorder.
  • Page 88: Basic Ied Functions

    Basic IED functions Chapter 11 Verifying settings by secondary injection Basic IED functions Parameter setting groups (ACGR) Prepare the IED for verification of settings as outlined in section 1 "Overview" section 2 "Preparing for test" in this chapter. 3.1.1 Verifying the settings Procedure Check the configuration of binary inputs that control the selection of the active setting group.
  • Page 89: Differential Protection

    Differential protection Chapter 11 Verifying settings by secondary injection Differential protection High impedance differential protection (PDIF, 87) Prepare the IED for verification of settings as outlined in section 1 "Overview" and section 2 "Preparing for test" in this chapter. Procedure Connect single phase or three phase test set to inject the operating voltage.
  • Page 90: Distance Protection

    Distance protection Chapter 11 Verifying settings by secondary injection Distance protection Distance protection zones (PDIS, 21) Prepare the IED for verification of settings as outlined in section 1 "Overview" section2 "Preparing for test" in this chapter. Consider releasing Zone 1, the PHS and the TR0n. If the au- torecloser is not released and in service, trip will always be three phase.
  • Page 91 Distance protection Chapter 11 Verifying settings by secondary injection (Ω / phase) 40% of RLdFw 80% of RLdFw 0.5 x RFPP en05000368.vsd Figure 26: Distance protection (ZM) characteristic with test points for phase to phase mea- surements Table 15 is used in conjunction with figure...
  • Page 92 Distance protection Chapter 11 Verifying settings by secondary injection X1+XN (Ω / loop) 40% of RLdFw 80% of RLdFw alt. 80% of RFPE RFPE (Load encroachment) en05000369.vsd Figure 27: Distance protection (ZM) characteristic with test points for phase to earth mea- surements Table 16 is used in conjunction with...
  • Page 93 Distance protection Chapter 11 Verifying settings by secondary injection Test point Reach Set value Comments –0.4 x RLdFw x tan(ArgDir) 0.4 x RLdFw 0.5 x X1 Exact –0.5 x R1 x tan(ArgNegRes-90) –0.23 x X1 0.8 x X1 Exact –0.5 x R1 x tan(ArgNegRes-90) –0.37 x X1 0.5 x X1...
  • Page 94 Distance protection Chapter 11 Verifying settings by secondary injection Test point Reach Value Comments 0.27 x (2 x X1 Exact: 0.8 x (2 x X1 + X0 –0.57 x (2 x X1 + X0 Exact: 0.8 x (2X1 + X0 )/(3 x tan(AngNegDir 90)) 0.5 x (2 x X1...
  • Page 95: Phase Selection With Load Enchroachment (Pdis, 21)

    Distance protection Chapter 11 Verifying settings by secondary injection Apply the fault condition to find the operating time for the phase-to-phase loop according to test point P10 in figure 26 table 15 for zone 1. Compare the result of the measurement with the setting t1PP.
  • Page 96 Distance protection Chapter 11 Verifying settings by secondary injection Default values: ArgNegRes=115 Earthfault loop ArgDir=15 ArgLd=30 X (Ohm/phase) ArgLd ⋅ ArgNegDir 60 deg R (Ohm/phase) ArgDir 20% of RLdFw 80% of RLdFw en05000496.vsd RFFwPE Figure 28: Operate characteristic for phase selection element, forward direction single phase faults.
  • Page 97 Distance protection Chapter 11 Verifying settings by secondary injection (Ω / phase) ArgLd 60° ArgNegRes (Ω / phase) ArgDir 0.2• RLdFw 0.8•RLdFw en05000497.vsd 0.5•RFFwPP Figure 29: Phase selection characteristic for phase to phase faults.
  • Page 98 Distance protection Chapter 11 Verifying settings by secondary injection (Ohm/phase) 90 deg ⋅ ArgLd ArgNegRes ArgDir 0.2•RLdFw 0.8•RLdFw 0.5•RFFwPE en05000498.vsd Figure 30: Phase selection characteristic for three phase faults.
  • Page 99 Distance protection Chapter 11 Verifying settings by secondary injection Table 17: Test points for phase-earth loop L3-E (Ohm/loop) Test point Value Comments ⋅ 1 XN ⋅ 1 XN R=RIPE ≈ ⋅ 0.981 1 XN ⋅ ⋅ 0.85 ≈ ⋅ 0.567 ( 1 XNL) RFFwPE ⋅...
  • Page 100 Distance protection Chapter 11 Verifying settings by secondary injection Test point Value Comments ⋅ ⋅ ≈ ⋅ RLdFw tan( ArgLd 0.346 RLdFw ⋅ 0.2 RLdFw ≈ ⋅ 0.231 X set ⋅ ⋅ 1 XN ≈ ⋅ 0.108 1 XN ⋅ ⋅...
  • Page 101 Distance protection Chapter 11 Verifying settings by secondary injection Table 18: Test points for phase-phase loops L1–L2 Test point Value Comments X= X1 R= 0 X= X1 R= RIPP X=0.85· X1set ⋅ 0.85 RFFwPP ≈ ⋅ 0.433 RFFwPP ⋅ RFFwPP ⋅...
  • Page 102 Distance protection Chapter 11 Verifying settings by secondary injection Test point Value Comments X=0.2· RLdFw ·tan( ArgDir ) ≈ − ⋅ R=0.2· RLdFw 0.054 RLdFw X=0.2· X1 ≈ ⋅ 0.432 ⋅ − tan( ArgNegDir X=0.85· X1set ≈ ⋅ 1,727 ⋅ −...
  • Page 103 Distance protection Chapter 11 Verifying settings by secondary injection Table 19: Test points for three-phase faults Test point Value Comments ≈ ⋅ X 1.33 X set ⋅ ≈ ⋅ ⋅ ⎡ 1.067 1 0.231 RFFwPP ⋅ ⋅ 0.85 RFFwPP ⎢ ⎣ ⋅...
  • Page 104 Distance protection Chapter 11 Verifying settings by secondary injection Test point Value Comments ≈ − ⋅ 0.214 RLdFw = − ⋅ − ⋅ 0.8 (2 3) RLdFw R=0.8· RLdFw ≈ − ⋅ 0.054 RLdFw = − ⋅ − ⋅ 0.2 (2 3) RLdFw R=0.8·...
  • Page 105: Power Swing Detection (Rpsb, 78)

    Distance protection Chapter 11 Verifying settings by secondary injection Measurements/Monitoring/Voltage phasors Repeat steps 1to 2to find the operate values for the remaining test points according to figures 28, and 30and to table Note, that if the shaped load encroachment characteristic is not activated OperationLdCh=Off then the test points 4, 5, 6 and 7 can be replaced by number 12.
  • Page 106 Distance protection Chapter 11 Verifying settings by secondary injection ⋅ 1 KX X IN X IN Impedance locus at power swing − ⋅ KR R IN − R IN ⋅ 1 KR R IN − X IN − ⋅ KX X IN 99000159.vsd Figure 31: Operating principle and characteristic of the PSD function...
  • Page 107 Distance protection Chapter 11 Verifying settings by secondary injection Increase the measured voltages to their rated values. 5.3.2 Testing the one-of-three-phase operation Procedure Check the existing (default) configuration of the following function input signals: REL1PH, BLK1PH, REL2PH, BLK2PH and record the connections. Reconfigure the IED according to the following list: •...
  • Page 108 Distance protection Chapter 11 Verifying settings by secondary injection 5.3.4 Testing the tEF timer and functionality Procedure Check and record the default configuration for the TRSP, I0CHECK, BLKI01, BLKI02, and BLOCK functional inputs. Re-configure the functional inputs TRSP and I0CHECK to connect them to two unused binary inputs of a terminal.
  • Page 109 Distance protection Chapter 11 Verifying settings by secondary injection Close the switch towards the I0CHECK binary input and observe the START signal. It must reset with the time delay set on the tR1 timer. It is also possible to measure this time delay with the timer, which starts with the closing of a switch and stops with the resetting of a START signal on the corre- sponding binary output.
  • Page 110: Automatic Switch Onto Fault Logic (Psof)

    Distance protection Chapter 11 Verifying settings by secondary injection 5.3.8 Completing the test Continue to test another function or end the test by changing the test mode setting to off. Automatic switch onto fault logic (PSOF) Prepare the IED for verification of settings as outlined in section 1 "Overview"...
  • Page 111: Current Protection

    Current protection Chapter 11 Verifying settings by secondary injection Current protection Instantaneous phase overcurrent protection (PIOC, 50) Prepare the IED for verification of settings as outlined in section 1 "Overview" and section 2 "Preparing for test" in this chapter. To verify the settings the following fault type should be tested: •...
  • Page 112 Current protection Chapter 11 Verifying settings by secondary injection If 2 of 3 currents for operation is chosen: Connect the injection current into terminal L1 and out from terminal L2. If 3 of 3 currents for operation is chosen: Connect the symmetrical 3 phase injection current into terminals L1, L2 and L3.
  • Page 113: Instantaneous Residual Overcurrent Protection (Pioc, 50N)

    Current protection Chapter 11 Verifying settings by secondary injection 12. Reverse the direction of the injected current and check that the pro- tection does not operate. 13. If 2 of 3 or 3 of 3 currents for operation is chosen: Check that the function will not operate with current in one phase only.
  • Page 114: Four Step Residual Overcurrent Function

    Current protection Chapter 11 Verifying settings by secondary injection Procedure Connect the test set for single current injection to the appropriate IED terminals. Connect the injection current to terminals L1 and neutral, or to terminals N and neutral. Set the injected polarizing voltage slightly larger than the set mini- mum polarizing voltage (default 5 % of Ur) and set the injection cur- rent to lag the voltage by an angle equal to the set reference characteristic angle ( AngleRCA ) if the forward directional function is...
  • Page 115: Thermal Overload Protection, One Time Constant (Pttr, 26)

    Current protection Chapter 11 Verifying settings by secondary injection Thermal overload protection, one time constant (PTTR, 26) Prepare the IED for verification of settings as outlined in section 1 "Overview" section 2 "Preparing for test" in this chapter. Check that the input logical signal BLOCK is logical zero and that on the local HMI, the logical signal TRIP, START and ALARM are equal to logical 0.
  • Page 116: Breaker Failure Protection (Rbrf, 50Bf)

    Current protection Chapter 11 Verifying settings by secondary injection 13. Continue to test another function or end the test by changing the test mode setting to off. Breaker failure protection (RBRF, 50BF) Prepare the IED for verification of settings as outlined in section 1 "Overview"...
  • Page 117 Current protection Chapter 11 Verifying settings by secondary injection 6.7.1 Checking the phase current operate value, IP> The check of the IP> current level is best made in FunctionMode=Current and BuTripMode= “1 out of 3” or “2 out of 4”. Procedure Apply the fault condition, including start of BFP, with a current below set IP>...
  • Page 118 Current protection Chapter 11 Verifying settings by secondary injection Checking the case without re-trip, RetripMode = Off Procedure Set RetripMode = Off . Apply the fault condition, including start of BFP, well above the set current value. Verify that no re-trip, but back-up trip is achieved after set time. Disconnect AC and start input signals.
  • Page 119 Current protection Chapter 11 Verifying settings by secondary injection Procedure Apply the fault condition, including start of BFP, with phase current well above set value “IP” Arrange switching the current off, with a margin before back-up trip time, t2 . It may be made at issue of re-trip command. Check that re-trip is achieved, if selected, but no back-up trip.
  • Page 120 Current protection Chapter 11 Verifying settings by secondary injection 6.7.6 Verifying instantaneous back-up trip at “CB faulty” condition Applies in a case where signal “CB faulty and unable to trip” is connected to input CBFLT. Procedure Repeat the check of back-up trip time. Disconnect current and start input signals.
  • Page 121: Stub Protection (Ptoc, 50Stb)

    Current protection Chapter 11 Verifying settings by secondary injection Apply the fault condition, including start of BFP, with current above the set IP> value. Check that the re-trip, if selected, and back-up trip commands are achieved. Disconnect injected AC and start input signals. Checking the case with fault current below set value I>BlkCont The case shall simulate a case where the fault current is very low and operation will depend on CB position signal from CB auxiliary contact.
  • Page 122 Current protection Chapter 11 Verifying settings by secondary injection 6.8.1 Measuring the operate limit of set values Procedure Check that the input logical signals BLOCK and RELEASE are logi- cal zero and note on the local HMI that the TRIP logical signal is equal to the logical 0.
  • Page 123: Pole Discordance Protection (Rpld, 52Pd)

    Current protection Chapter 11 Verifying settings by secondary injection 14. Continue to test another function or end the test by changing the test mode setting to off. Pole discordance protection (RPLD, 52PD) Prepare the terminal for verification of settings as outlined in section 2 "Preparing for test"...
  • Page 124 Current protection Chapter 11 Verifying settings by secondary injection 13. Repeat point 11 and 12 using OPENCMD instead of CLOSECMD. Un- symmetry current detection with CB monitoring: Set all three cur- rents to 110% of Current Release level. Activate CLOSECMD. NO TRIP signal should appear due to symmetrical condition.
  • Page 125: Voltage Protection

    Voltage protection Chapter 11 Verifying settings by secondary injection Voltage protection Two step undervoltage protection (PUVM, 27) Prepare the IED for verification of settings as outlined in section 1 "Overview" section 2 "Preparing for test" in this chapter. 7.1.1 Verifying the settings Verification of Start-value and time delay to operate for Step1 Procedure Make sure that the IED settings are appropriate, especially the...
  • Page 126: Two Step Overvoltage Protection (Povm, 59)

    Voltage protection Chapter 11 Verifying settings by secondary injection Two step overvoltage protection (POVM, 59) Prepare the IED for verification of settings as outlined in section 1 "Overview" section 2 "Preparing for test" in this chapter. 7.2.1 Verifying the settings Procedure Apply single phase voltage below the set value U1>...
  • Page 127 Voltage protection Chapter 11 Verifying settings by secondary injection 7.3.2 Completing the test Continue to test another function or end the test by changing the test mode setting to off. Restore connections and settings to their original values, if they were changed for testing purposes.
  • Page 128: Frequency Protection

    Frequency protection Chapter 11 Verifying settings by secondary injection Frequency protection Underfrequency protection (PTUF, 81) Prepare the terminal for verification of settings as outlined in section 2 "Preparing for test" this chapter. 8.1.1 Verifying the settings Verification of Start-value and time delay to operate Procedure Make sure that the IED settings are appropriate, especially the Start-value and the definite time delay.
  • Page 129: Overfrequency Protection (Ptof, 81)

    Frequency protection Chapter 11 Verifying settings by secondary injection Slowly decrease the frequency of the applied voltage, to a value be- low StartFrequency . Make sure that the START signal not appears. Wait for a time corresponding to tTrip , and make sure that the TRIP signal not appears.
  • Page 130: Rate-Of-Change Frequency Protection (Pfrc, 81)

    Frequency protection Chapter 11 Verifying settings by secondary injection Slowly decrease the magnitude of the applied voltage, until the BLKDMAGN signal appears. Note the voltage magnitude value and compare it with the set value, IntBlkStVal . Slowly increase the frequency of the applied voltage, to a value above StartFrequency .
  • Page 131 Frequency protection Chapter 11 Verifying settings by secondary injection Extended testing Procedure The test above can be repeated to check a positive setting of Start- FreqGrad . The tests above can be repeated to check the time to reset. The tests above can be repeated to test the RESTORE signal, when the frequency recovers from a low value.
  • Page 132: Multipurpose Protection

    Multipurpose protection Chapter 11 Verifying settings by secondary injection Multipurpose protection General current and voltage protection (GAPC) One of the new facilities within the GF function is that the value which is processed and used for evaluation in the function can be chosen in many different ways by the setting parameters CurrentInput and VoltageInput.
  • Page 133 Multipurpose protection Chapter 11 Verifying settings by secondary injection 10. Finally check that start and trip information is stored in the Event menu. Information on how to use the event menu is found in the IED670 oper- ators manual. 9.1.2 Overcurrent feature with current restraint The current restraining value has also to be measured or calculated and the influence on the op- eration has to be calculated when the testing of the operate value is done.
  • Page 134 Multipurpose protection Chapter 11 Verifying settings by secondary injection Procedure Connect the test set for injection of 3-phase currents and 3-phase voltages to the appropriate current and voltage terminals of IED670. Inject current(s) and voltage(s) in a way that relevant measured (ac- cording to setting parameter CurrentInput and VoltageInput ) cur- rents and voltages are created from the test set.
  • Page 135: Secondary System Supervision

    Secondary system supervision Chapter 11 Verifying settings by secondary injection Secondary system supervision 10.1 Current circuit supervision (RDIF) Prepare the IED for verification of settings as outlined in section 1 "Overview" and section 2 "Preparing for test" in this chapter. The current circuit supervision function is conveniently tested with the same 3-phase test set as used when testing the measuring functions in the REx670.
  • Page 136 Secondary system supervision Chapter 11 Verifying settings by secondary injection Connect the nominal dc voltage to the DISCPOS binary input. • The signal BLKU should appear with almost no time delay. • No signals BLKZ and 3PH should appear on the IED. •...
  • Page 137 Secondary system supervision Chapter 11 Verifying settings by secondary injection ⋅ ⋅ ⋅ (Equation 1) Where: = the measured phase voltages 2 π ⋅ ---------- - ⋅ ------ - – Compare the result with the set value (consider that the set value 3U2>...
  • Page 138 Secondary system supervision Chapter 11 Verifying settings by secondary injection 10.2.4 Checking the operation of the du/dt and di/dt based function Check the operation of the du/dt and di/dt based function, if included in the IED. Procedure Simulate normal operating conditions with the three-phase currents in phase with their corresponding phase voltages and with all of them equal to their rated values.
  • Page 139: Control

    Control Chapter 11 Verifying settings by secondary injection Control 11.1 Synchrocheck and energizing check (RSYN, 25) This section contains instructions on how to test the synchronism and energizing check for sin- gle and double CB with or without the synchronizing function and for 1 breaker arrange- ments.
  • Page 140 Control Chapter 11 Verifying settings by secondary injection REx670 Test U-Bus U-Bus equipment UMeasure Ph/N U-Line Ph/Ph Input Phase L1,L2,L3 L12,L23,L31 en05000480.vsd Figure 32: General test connection with three-phase voltage connected to the line side...
  • Page 141 Control Chapter 11 Verifying settings by secondary injection REx670 Test U-Bus1 U3PBB1 equipment U-Bus2 U3PBB2 U-Line2 U3PLN2 U-Line1 U3PLN1 UMeasure Ph/N Ph/Ph en05000481.vsd Figure 33: General test connection for a 1 CB diameter with one-phase voltage connected to the line side 11.1.1 Testing the synchronizing function This section is applicable only if the synchronizing function is included.
  • Page 142 Control Chapter 11 Verifying settings by secondary injection Table 20: Test settings for synchronizing Parameter Setting Operation UBase System voltage level SelPhaseBus1 SelPhaseBus2 SelPhaseLine1 SelPhaseLine2 PhaseShift 0 degrees URatio 1.00 CBConfig SingleBus AutoEnerg ManEnerg ManEnergDBDL UHighBusEnerg 80% UBase UHighineEnerg 80% UBase ULowBusEnerg 30% UBase ULowLineEnerg...
  • Page 143 Control Chapter 11 Verifying settings by secondary injection Parameter Setting tBreaker 0.08 s VTConnection Line tSyncM tSyncA FreqDiffBlock Testing the frequency difference The frequency difference is in the example set at 0.20 Hz on the local HMI, and the test should verify that operation is achieved when the FreqDiffSynch frequency difference is lower than 0.20 Hz.
  • Page 144 Control Chapter 11 Verifying settings by secondary injection SYN1 U-line Activate SYN1_FD1CLD Activate SYN1_CB2CLD Activate SYN1_CB2CLD and CB3CLD U-bus No activation of inputs necessary SYN2 U-line Activate SYN2_FD2CLD Activate SYN2_CB3CLD U-bus Activate SYN2_FD1CLD Activate SYN2_CB1CLD SYN3 U-line Activate SYN3_CB2CLD Activate SYN3_FD2CLD Activate SYN3_CB1CLD and CB2CLD U-bus No activation of inputs necessary...
  • Page 145 Control Chapter 11 Verifying settings by secondary injection Check that the AUTOOK and MANOK outputs are activated. The test can be repeated with other PhaseDiff values to verify that the function operates for values lower than the set ones. By changing the phase angle on U1 connected to U-bus, between ±...
  • Page 146 Control Chapter 11 Verifying settings by secondary injection Check that the two outputs are not activated. The test can be repeated with different frequency values to verify that the function operates for values lower than the set ones. If a modern test set is used, the frequency can be changed continuously.
  • Page 147 Control Chapter 11 Verifying settings by secondary injection Increase the U-Line to 60% UBase and U-Bus to be equal to 100% UBase . The outputs should not be activated. The test can be repeated with different values on the U-Bus and the U-Line.
  • Page 148 Control Chapter 11 Verifying settings by secondary injection Apply a single-phase voltage of 30% UBase to the U-bus and a sin- gle-phase voltage of 30% UBase to the U-line. Check that the MANENOK output is activated. Increase the U-bus to 80% UBase and keep the U-line equal to 30% UBase .
  • Page 149: Autorecloser (Rrec, 79)

    Control Chapter 11 Verifying settings by secondary injection 11.1.5 Completing the test Continue to test another function or complete the test by setting the test mode to off. 11.2 Autorecloser (RREC, 79) Verification of the automatic reclosing function can be considered to consist of two parts; one part to verify the internal logic and timing of the function and one part to verify its interaction with the protection system.
  • Page 150 Control Chapter 11 Verifying settings by secondary injection Information and material for the verification: • Protection or control unit, Intelligent electronic device (IED), configured and with settings entered. • Configuration diagram for the IED • Terminal diagram for the IED, or plant circuit diagram including the IED •...
  • Page 151 Control Chapter 11 Verifying settings by secondary injection 11.2.1 Preparation of the verification Procedure Check the function settings. In the HMI tree they are found under: Settings\Setting Group N\Control\Autorecloser(RREC,79) If any timer settings are reduced to speed-up or facilitate the testing, they shall be set to normal after testing.
  • Page 152 Control Chapter 11 Verifying settings by secondary injection 11.2.3 Verifying the auto-reclosing function Select the test cases to be run according to what is applicable to the particular application. It may for instance be a) three-phase single-shot reclosing, b) two-shot reclosing or c) single-phase and three-phase single shot reclosing.
  • Page 153 Control Chapter 11 Verifying settings by secondary injection 11.2.4 Checking the reclosing conditions When checking the influence of a releasing condition it is suggested to first run a sequence with the condition fulfilled. When the condition signal is removed, and a new sequence is run, it in- dicates that the result was due to the changed condition.
  • Page 154 Control Chapter 11 Verifying settings by secondary injection Checking the influence of synchronism check (at three-phase reclosing) Procedure Check that the auto-reclosing function is operative, e.g. by making a three-phase reclosing shot with the synchronism check condition. Remove the SYNC signal. Apply a fault causing three-phase trip and thereby a START and a TR3P signal.
  • Page 155: Apparatus Control (Apc)

    Control Chapter 11 Verifying settings by secondary injection Reset\Reset counters\AutoRecloser(RREC,79)\ARnn Restore settings that may have been modified for the tests back to normal. Disconnect the test switch, CB simulating arrangement and test cir- cuits. Reconnect any links or connection terminals, which may have been opened for the tests.
  • Page 156: Scheme Communication

    Scheme communication Chapter 11 Verifying settings by secondary injection Scheme communication 12.1 Scheme communication logic for distance protection (PSCH, 85) Prepare the IED for verification of settings as outlined in section 1 "Overview" section 2 "Preparing for test" in this chapter. Check the scheme logic during the secondary injection test of the impedance or overcurrent pro- tection functions.
  • Page 157 Scheme communication Chapter 11 Verifying settings by secondary injection Check that the other zones operate according to their zone timer and that the carrier send (CS) signal is obtained only for the zones that are configured to give the actual signal. Deactivate the IED carrier receive (CR) signal.
  • Page 158: Current Reversal And Weak End Infeed Logic For Distance Protection (Psch, 85)

    Scheme communication Chapter 11 Verifying settings by secondary injection 12.1.5 Completing the test Continue to test another function or end the test by changing the test mode setting to off. 12.2 Current reversal and weak end infeed logic for distance protection (PSCH, 85) Prepare the IED for verification of settings as outlined in section 1 "Overview"...
  • Page 159 Scheme communication Chapter 11 Verifying settings by secondary injection 12.2.2 Weak end infeed logic WEI logic at permissive schemes Procedure Check the blocking of the echo with the injection of a CR signal >40 ms after a reverse fault is applied. Measure the duration of the echoed signal by applying a CR carrier receive signal.
  • Page 160: Local Acceleration Logic (Plal)

    Scheme communication Chapter 11 Verifying settings by secondary injection 12.3 Local acceleration logic (PLAL) Prepare the IED for verification of settings as outlined in section 1 "Overview" section 2 "Preparing for test" in this chapter. The logic is checked during the secondary injection test of the impedance measuring zones. Procedure Provide the terminal with conditions equivalent to normal load for at least two seconds.
  • Page 161 Scheme communication Chapter 11 Verifying settings by secondary injection Inject current (65 ° lagging the voltage) in one phase at about 110% of the set operating current, and switch the current off with the switch. Switch the fault current on and measure the operating time of the EFC logic.
  • Page 162: Current Reversal And Weak End Infeed Logic For Residual Overcurrent Protection (Psch, 85)

    Scheme communication Chapter 11 Verifying settings by secondary injection Switch the fault current on (110% of the setting) and measure the op- erating time of the EFC logic. Use the TRIP signal from the configured binary output to stop the timer. Compare the measured time with the setting for tCoord .
  • Page 163 Scheme communication Chapter 11 Verifying settings by secondary injection 12.5.2 Testing the weak-end-infeed logic If setting parameter WEI=Echo Procedure Inject the polarizing voltage 3U0 to 5% of UBase and the phase angle between voltage and current to 155 ° , the current leading the voltage. Inject current (155 °...
  • Page 164 Scheme communication Chapter 11 Verifying settings by secondary injection Activate the CRL binary input. No ECHO, CS and TRWEI outputs should appear. Reset the CRL and BLOCK binary input. 10. Inject the polarizing voltage 3U0 to about 110% of the setting ( 3UO ) and adjust the phase angle between the voltage and current to 155 °...
  • Page 165: Logic

    Logic Chapter 11 Verifying settings by secondary injection Logic 13.1 Tripping logic (PTRC, 94) Prepare the IED for verification of settings as outlined in section 1 "Overview" section 2 "Preparing for test" in this chapter. This function is functionality tested together with other pro- tection functions (line differential protection, earth-fault overcurrent protection, etc.) within the IED.
  • Page 166 Logic Chapter 11 Verifying settings by secondary injection Initiate different phase-to-phase and three-phase faults. Consider using an adequate time interval between faults, to overcome a reclaim time which is activated by the autoreclosing function. A three-phase trip should occur for each separate fault and all of the trips. Functional outputs TRIP, all TRLn and TR3P should be active at each fault.
  • Page 167 Logic Chapter 11 Verifying settings by secondary injection responding two trip outputs (TRLn) should be activated at a time. Func- tional outputs TRIP and TR2P should be active at each fault. No other outputs should be active. Initiate a three-phase fault Take into consideration an adequate time interval between faults, to over- come a reclaim time which may be activated by the autoreclosing func- tion.
  • Page 168 Logic Chapter 11 Verifying settings by secondary injection Activate shortly the set lockout (SETLOCKOUT) signal in the IED. Check that the circuit breaker lockout (CLLKOUT) signal is set. Activate shortly thereafter, the reset lockout (RSTLKOUT) signal in the IED. Check that the circuit breaker lockout (CLLKOUT) signal is reset. Initiate a three-phase fault A three-phase trip should occur and all trip outputs (TRLn) should be ac- tivated.
  • Page 169: Monitoring

    Monitoring Chapter 11 Verifying settings by secondary injection Monitoring 14.1 Event counter (GGIO) The function can be tested by connecting a binary input to the counter under test and from out- side apply pulses to the counter. The speed of pulses must not exceed 10 per second. Normally the counter will be tested in connection with tests on the function that the counter is connected to, such as trip logic.
  • Page 170 Monitoring Chapter 11 Verifying settings by secondary injection Table 22: Test settings Parameter: Condition: Higher than 30% I U = 63,5 V, I = 0 A & ZF = 0 ° Healthy conditions Impedance |Z| Test point Note: ≤ (X0 + 2 · X1)/3For single-phase faults •...
  • Page 171 Monitoring Chapter 11 Verifying settings by secondary injection 14.3.2 Completing the test Continue to test another function or end the test by changing the test mode setting to off. Restore connections and settings to the original values, if they were changed for testing purpose.
  • Page 172: Metering

    Metering Chapter 11 Verifying settings by secondary injection Metering 15.1 Pulse counter logic (GGIO) The test of the pulse counter function requires the Parameter Setting Tool in the PCM or an ap- propriate connection to a local HMI with the necessary functionality. A known number of pulses with different frequencies are connected to the pulse counter input.
  • Page 173: Remote Communication

    Remote communication Chapter 11 Verifying settings by secondary injection Remote communication 16.1 Binary signal transfer to remote end Prepare the IED for verification of settings as outlined in section 1 "Overview" section 2 "Preparing for test" in this chapter. There are two types of internal self-supervision of the RTC. The I/O-circuit board is supervised as an I/O module.
  • Page 174 Remote communication Chapter 11 Verifying settings by secondary injection...
  • Page 175: Chapter 12 Commissioning And Maintenance Of The Fault Clearing System

    About this chapter Chapter 12 Commissioning and maintenance of the fault clearing system Chapter 12 Commissioning and maintenance of the fault clearing system About this chapter This chapter discusses maintenance tests and other periodic maintenance measures.
  • Page 176: Installation And Commissioning

    AC or DC transients, high ambient temperatures, and high air humidity always have a certain likelihood of causing damages. Delivered equipment undergoes extensive testing and quality control in the ABB manufacturing program. All types of IEDs and their integral components have been subject to extensive labo- ratory testing during the development and design work.
  • Page 177: Commissioning Tests

    Commissioning tests Chapter 12 Commissioning and maintenance of the fault clearing system Commissioning tests During commissioning all protection functions shall be verified with the setting values used at each plant. The commissioning tests must include verification of all circuits by green-lining the circuit diagrams and the configuration diagrams for the used functions.
  • Page 178: Periodic Maintenance Tests

    The periodicity of all tests depends on several factors, for example the importance of the instal- lation, environment conditions, simple or complex equipment, static or electromechanical relays etc. The normal maintenance praxis of the user should be followed. However ABB proposal is to test: Every second to third year: •...
  • Page 179 ABB protection relays are preferable tested by aid of components from the COMBITEST testing system described in information B03-9510 E. Main components are RTXP 8/18/24 test switch located to the left in each protection relay and RTXH 8/18/24 test handle which is inserted in test switch at secondary testing.
  • Page 180 Periodic maintenance tests Chapter 12 Commissioning and maintenance of the fault clearing system 3.2.6 Trip circuit check When the protection IED undergoes an operational check, a tripping pulse is normally obtained on one or more of the output contacts and preferably on the test switch. The healthy circuit is of utmost importance for the protection operation.
  • Page 181: Chapter 13 Fault Tracing And Repair

    About this chapter Chapter 13 Fault tracing and repair Chapter 13 Fault tracing and repair About this chapter This chapter describes how to carry out fault tracing and if necessary, a change of circuit board.
  • Page 182: Fault Tracing

    Fault tracing Chapter 13 Fault tracing and repair Fault tracing Information on the local HMI If an internal fault has occurred, the local HMI displays information under: Diagnostics\IED status\General Under the Diagnostics menus, indications of a possible internal failure (serious fault) or internal warning (minor problem) are listed.
  • Page 183: Using Front-Connected Pc Or Sms

    Fault tracing Chapter 13 Fault tracing and repair HMI Signal Name: Status Description Application READY / FAIL This signal will be active if one or more of the application threads are not in the state that Runtime Engine expects. The states can be CREATED, INITIALIZED, RUN- NING, etc.
  • Page 184 Fault tracing Chapter 13 Fault tracing and repair The internal events are time tagged with a resolution of 1 ms and stored in a list. The list can store up to 40 events. The list is based on the FIFO principle, when it is full, the oldest event is overwritten.
  • Page 185 Fault tracing Chapter 13 Fault tracing and repair • Sequence of faults, if more than one unit is faulty. • Exact time when the fault occurred.
  • Page 186: Repair Instruction

    IED and measuring circuitry may be damaged. An alternative is to open the IED and send only the faulty circuit board to ABB for repair. When a printed circuit board is sent to ABB, it must always be placed in a metallic, ESD-proof, pro- tection bag.
  • Page 187 Repair instruction Chapter 13 Fault tracing and repair If the REx670 IED has the increased measuring accuracy feature (Optional), a file with unique calibration data for that particular transformer module is stored in the Main processor module. Therefore it is not possible to freely change only one of these modules with maintained accuracy. To maintain the accuracy feature the calibration file stored in the NUM must match the TRM and ADM used together with the NUM.
  • Page 188: Repair Support

    Fault tracing and repair Repair support If a REx670 IED needs to be repaired, the whole IED must be removed and sent to an ABB Lo- gistic Center. Before returning the material, an inquiry must be sent to the ABB Logistic Center.
  • Page 189: Maintenance

    Maintenance Chapter 13 Fault tracing and repair Maintenance The REx670 IED is self-supervised. No special maintenance is required. Instructions from the power network company and other maintenance directives valid for main- tenance of the power system must be followed.
  • Page 190 Maintenance Chapter 13 Fault tracing and repair...
  • Page 191: Chapter 14 Glossary

    About this chapter Chapter 14 Glossary Chapter 14 Glossary About this chapter This chapter contains a glossary with terms, acronyms and abbreviations used in ABB technical documentation.
  • Page 192: Glossary

    Glossary Chapter 14 Glossary Glossary Alternating Current A/D converter Analog to digital converter ADBS Amplitude dead -band supervision Analog input module ANSI American National Standards Institute ArgNegRes Setting parameter/ZD/ ArgDir Setting parameter/ZD/ ASCT Auxiliary summation current transformer Adaptive Signal Detection American Wire Gauge standard Binary input module Binary output module...
  • Page 193 Glossary Chapter 14 Glossary 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 directions, and two pairs for transmitting clock signals Central Processor Unit Carrier Receive Cyclic Redundancy Check Carrier send Current transformer...
  • Page 194 Glossary Chapter 14 Glossary General interrogation command Gas insulated switchgear GOOSE Generic Object Oriented Substation Event Global positioning system GPS time Synchronization Module HDLC protocol High level data link control, protocol based on the HDLC standard HFBR connector type Plastic fibre connector Human Machine Interface HSAR High Speed Auto Reclosing...
  • Page 195 Glossary Chapter 14 Glossary IP 40 Ingression Protection, According to IEC standard, level 40 IP 54 Ingression Protection, According to IEC standard, level 54 International Telecommunications Union Local Area Network LIB 520 High voltage software module Liquid Crystal Display LDCM Line Differential Communication Module Local detection device Light Emitting Diode...
  • Page 196 Glossary Chapter 14 Glossary RASC Synchrocheck relay, COMBIFLEX Relay characteristic angle REVAL Evaluation software RFPP Resistance for phase-to-phase faults RFPE Resistance for phase-to-earth faults RISC Reduced instruction set computer RMS value Root mean square value RS422 A balanced serial interface for the transmission of digital data in point-to-point connections RS485 Serial link according to EIA standard RS485...
  • Page 197 Glossary Chapter 14 Glossary TCP/IP Transmission Control Protocol over Internet Protocol. The de facto stan- dard Ethernet protocols incorporated into 4.2BSD Unix. TCP/IP was developed by DARPA for internet working and encompasses both net- work layer and transport layer protocols. While TCP and IP specify two protocols at specific protocol layers, TCP/IP is often used to refer to the entire US Department of Defense protocol suite based upon these, including Telnet, FTP, UDP and RDP.
  • Page 198 Glossary Chapter 14 Glossary...

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