ABB ReliOn 630 Series Engineering Manual

Protection and control

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Protection and Control

630 series

Engineering Manual

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Summary of Contents for ABB ReliOn 630 Series

Page 1 ® Relion Protection and Control 630 series Engineering Manual...
Page 4: Warranty
Copyright This document and parts thereof must not be reproduced or copied without written permission from ABB, and the contents thereof must not be imparted to a third party, nor used for any unauthorized purpose. The software or hardware described in this document is furnished under a license and may be used, copied, or disclosed only in accordance with the terms of such license.
Page 5 In case any errors are detected, the reader is kindly requested to notify the manufacturer. Other than under explicit contractual commitments, in no event shall ABB be responsible or liable for any loss or damage resulting from the use of this manual or the application of the equipment.
Page 6 (EMC Directive 2004/108/EC) and concerning electrical equipment for use within specified voltage limits (Low-voltage directive 2006/95/EC). This conformity is the result of tests conducted by ABB in accordance with the product standards EN 50263 and EN 60255-26 for the EMC directive, and with the product standards EN 60255-6 and EN 60255-27 for the low voltage directive.
Page 7: Table Of Contents
Table of contents Table of contents Section 1 Introduction...............5 This manual..................5 Intended audience................5 Product documentation...............6 Product documentation set............6 Document revision history.............7 Related documentation..............8 Symbols and conventions..............8 Safety indication symbols..............8 Manual conventions...............8 Functions, codes and symbols............9 Section 2 Engineering tool set............13 Introduction..................13 IED engineering process..............14 Section 3 Engineering process............17...
Page 8 Table of contents Connections and variables............58 Hardware channels..............59 Validation..................60 Setting configuration and setting parameters in PST.......62 Connecting signals in SMT...............63 Engineering control functions............64 Introduction..................64 Remote/Local switch..............66 Bay control...................67 Switch control................71 Circuit breaker/Circuit switch............74 Section 6 Local HMI engineering...........77 LED and function key engineering............77 Local HMI engineering process...........77 LED operation modes..............82 Single line diagram engineering............87...
Page 9 Table of contents Horizontal communication engineering........117 Writing communication configuration to IED........118 Section 8 DNP3 communication engineering.......121 Signal configuration user information..........121 Configuring DNP3 protocol signals..........121 Setting DNP3 signal parameters............123 Configuring DNP3 class............125 Section 9 Glossary...............127 630 series Engineering Manual...
Page 11: Section 1 Introduction
Section 1 1MRS756800 A Introduction Section 1 Introduction This manual The engineering manual contains instructions on how to engineer the IEDs using the different tools in PCM600. The manual provides instructions on how to set up a PCM600 project and insert IEDs to the project structure. The manual also recommends a sequence for engineering of protection and control functions, LHMI functions as well as communication engineering for IEC 61850 and DNP3.
Page 12: Product Documentation
Section 1 1MRS756800 A Introduction Product documentation 1.3.1 Product documentation set Engineering manual Engineering manual Engineering manual Installation manual Installation manual Installation manual Commissioning manual Commissioning manual Commissioning manual Operation manual Operation manual Operation manual Service manual Service manual Service manual Application manual Application manual Application manual...
Page 13: Document Revision History
IED. The manual should be used in conjunction with the corresponding communication protocol manual. The service manual is not available yet. 1.3.2 Document revision history Document revision/date Product series version History A/2009.09.15 First release Download the latest documents from the ABB web site http:// www.abb.com/substationautomation. 630 series Engineering Manual...
Page 14: Related Documentation
Section 1 1MRS756800 A Introduction 1.3.3 Related documentation Product series- and product-specific manuals can be downloaded from the ABB web site http://www.abb.com/substationautomation Symbols and conventions 1.4.1 Safety indication symbols The caution icon indicates important information or warning related to the concept discussed in the text. It might indicate the presence of a hazard which could result in corruption of software or damage to equipment or property.
Page 15: Functions, Codes And Symbols
Section 1 1MRS756800 A Introduction The function can be enabled and disabled with the Operation setting. • The ^ character in front of an input or output signal name in the function block symbol given for a function, indicates that the user can set an own signal name in PCM600.
Page 16 Section 1 1MRS756800 A Introduction Functionality IEC 61850 IEC 60617 ANSI Negative phase-sequence time MNSPTOC >M overcurrent protection Three-phase overvoltage PHPTOV 3U> Three-phase undervoltage PHPTUV 3U< Positive-sequence overvoltage PSPTOV > 47O+ Positive-sequence undervoltage PSPTUV < 47U+ Negative-sequence overvoltage NSPTOV > 47O- Residual overvoltage ROVPTOV...
Page 17 Section 1 1MRS756800 A Introduction Functionality IEC 61850 IEC 60617 ANSI Fuse failure supervision SEQRFUF FUSEF Current-circuit supervision CCRDIF MCS 3I MCS 3I Trip-circuit supervision TCSSCBR Generic measured values MVGGIO Measured value limit supervision MVEXP Station battery supervision SPVNZBAT U<> U<>...
Page 19: Section 2 Engineering Tool Set
Section 2 1MRS756800 A Engineering tool set Section 2 Engineering tool set Introduction The structure of a monitoring and control system for electrical substations has a principle structure as shown in Figure 2. It contains a number of IEDs for the various purposes.
Page 20: Ied Engineering Process
Section 2 1MRS756800 A Engineering tool set PCM600 communicates with the bay IEDs via an Ethernet connection. The connection allows to read and write all configuration data needed for proper operation from or to the IED. The IEDs have communication interfaces for protocols and media used for station communication.
Page 21 Section 2 1MRS756800 A Engineering tool set • Organizing the bay IEDs in the structure of the substation by defining voltage levels and bays below the substation. PCM600 manages the project. • Configuring the IED functions (for example protection and control functions and LHMI functions) by using the Application configuration tool (ACT).
Page 22 Section 2 1MRS756800 A Engineering tool set IED Engineering Management Project Communication Management Operator Disturbance Record Management Service Management PCM600 IEC08000100.vsd IEC08000100 V1 EN Figure 3: Organization of PCM600 in different management tasks Additional functionality to manage the project and to organize the user rights: •...
Page 23: Section 3 Engineering Process
Section 3 1MRS756800 A Engineering process Section 3 Engineering process Workflow Start Create plant structure and insert IED objects Project ACT/ Configure IED functionality Save the work between the different steps Parametrization Create single line diagram for local HMI IEC 61850 Supported protocols Export SCL files from...
Page 24 Section 3 1MRS756800 A Engineering process available information at the time the project is started. This means that several iterations may be needed to finish the project. • Setting up the PCM600 project • Build the plant structure according to the substation structure. It is recommended to not exceed 60 IEDs in one PCM600 project.
Page 25 Section 3 1MRS756800 A Engineering process The IED restarts automatically when writing an IED configuration where changes have been made to, for example configuration parameters. It is not possible to communicate with the IED during the restart. 630 series Engineering Manual...
Page 27: Section 4 Setting Up A Project
The IED specific module is separate for each type of IED. Installing IED Connectivity package module Procedure Close PCM600 before running ABB IED Connectivity Package RE_6x0 Ver. n.msi installer. (n = version number) Follow the installation software guide through the steps required to install the connectivity package.
Page 28 The Connectivity package manager shows the IEDs that are compatible with the installed PCM600 version. Activate the ABB IED Connectivity Package RE_630 Ver. n to use 630 series products. (n = version number) Always use the latest version of a connectivity package, see Figure 6.
Page 29: Setting Up Communication Between Pcm600 And The Ied
Section 4 1MRS756800 A Setting up a project IEC09000393-1-en.vsd IEC09000393 V1 EN Figure 6: Connectivity package manager window PCM600 recognizes the installed Connectivity Package(s) during startup and corresponding IED types are available in PCM600 when starting a new project. Setting up communication between PCM600 and the IED The communication between the IED and PCM600 is independent of the used communication protocol within the substation or to the NCC.
Page 30 Section 4 1MRS756800 A Setting up a project factory IP address when the complete IED is delivered. This is not given when an additional Ethernet interface is installed or an interface is replaced. • The default IP address for the IED front port is 192.168.0.254 and the corresponding subnetwork mask is 255.255.255.0, which can be set via the LHMI path Main menu/Configuration/Communication/TCP-IP configuration/Front port...
Page 31 Section 4 1MRS756800 A Setting up a project The IEDs DHCP server for the front port assigns an IP address for the computer. The computer must be configured to obtain its IP address automatically as described in the following procedure. Select Network Connections in the PC, see Figure IEC09000355-1-en.vsd...
Page 32: Managing Projects In Pcm600
Section 4 1MRS756800 A Setting up a project IEC09000357-1-en.vsd IEC09000357 V1 EN Figure 10: Select the TCP/IP protocol and open Properties Select Obtain an IP address automatically, see Figure IEC09000358-1-en.vsd IEC09000358 V1 EN Figure 11: Select: Obtain an IP address automatically Close all open windows and start PCM600.
Page 33: Creating A New Project
Section 4 1MRS756800 A Setting up a project • open existing projects • import projects • create new projects • export projects • delete projects • rename projects • copy and paste projects Extensions of the exported project file is *.pcmp and those files are only used for exporting and importing the projects between PCM600s.
Page 34: Building A Plant Structure
Section 4 1MRS756800 A Setting up a project IEC09000375-1-en.vsd IEC09000375 V1 EN Figure 12: PCM600: Create a new project window Name the project and include a description (optional) and click Create. PCM600 sets up a new project that will be listed under Projects on my computer.
Page 35: Iec 61850 Naming Conventions To Identify An Ied
Section 4 1MRS756800 A Setting up a project IEC09000359-1-en.vsd IEC09000359 V1 EN Figure 13: PCM600: Set up a plant structure Once a plant structure is built the name of each level in the structure should be renamed by the names/identifications used in the grid. Use the right mouse button to build the plant structure by selecting the elements from the context menu.
Page 36 Section 4 1MRS756800 A Setting up a project value is used as reference to an object, it is contained in an attribute name starting with a string denoting the reference target object type, and ending with the string Name. The technical key is used within SCL for referencing other objects.
Page 37 Section 4 1MRS756800 A Setting up a project IEC09000360-1-en.vsd IEC09000360 V1 EN Figure 14: PCM600: IEC 61850 signal designation concept Figure 14 shows the IED named in the example TR_421 in the object properties with the two designations TR_421 and SB1. The created technical key for the full path name of the IED would be: •...
Page 38: Inserting An Ied
Section 4 1MRS756800 A Setting up a project Inserting an IED The context menu or the Object Types view shows the available 630 series IEDs possible to insert, on the bay level in the plant structure, according to the installed connectivity package.
Page 39 Section 4 1MRS756800 A Setting up a project Right-click the Bay and select New and Feeder IEDs. Select the IED type to insert. It is also possible to drag-and-drop an IED from the Object Types window to the Bay level. Select the Online Configuration mode, see Figure IEC09000363-1-en.vsd...
Page 40 Section 4 1MRS756800 A Setting up a project IEC09000364-1-en.vsd IEC09000364 V1 EN Figure 17: PCM600: Communication protocol selection wizard Select the port and insert the correct IP address of the physical IED to configure, see Figure IEC09000365-1-en.vsd IEC09000365 V1 EN Figure 18: PCM600: Communication port and IP address Cross check that the IED, whose IP address has been inserted, has been...
Page 41 Section 4 1MRS756800 A Setting up a project The user can not scan data from the IED or proceed further if the IED is not online or if the IP address is not correct. Click the Scan option to scan/read the IED Type and IED Version for the IED that is online, see Figure IEC09000366-1-en.vsd...
Page 42 Section 4 1MRS756800 A Setting up a project IEC09000367-1-en.vsd IEC09000367 V1 EN Figure 20: PCM600: IED Order code detection The Setup Complete Page dialog shows the summary of the IED Type, IED Version, IP Address of IED and Selected Order Code, Figure 21.
Page 43 Section 4 1MRS756800 A Setting up a project IEC09000368-1-en.vsd IEC09000368 V1 EN Figure 21: PCM600: IED Setup completion wizard Note that it is not possible to go back and do any modification if an error is found in the setup complete page. If an error is detected, the user has to cancel the insertion and insert the IED again.
Page 44 Section 4 1MRS756800 A Setting up a project IEC09000369-1-en.vsd IEC09000369 V1 EN Figure 22: PCM600: IED Version selection IEC09000370-1-en.vsd IEC09000370 V1 EN Figure 23: PCM600: IED Order code selection Inserting an IED from the template library An IED in the plant structure can be exported as a template (*.pcmt). The user can build up a template library with all the exported IED templates.
Page 45 Section 4 1MRS756800 A Setting up a project insert an IED from the template library to create a new IED in the plant structure. Change the IP address, the name and the technical key that corresponds to the physical IED after a template IED has been imported. A template IED can only be inserted when the bay is selected in the plant structure.
Page 46 Close. Inserting a pre-configuration Pre-configurations can be downloaded free of charge from the ABB website. Pre-configurations in PCM600 are available as *.pcmi files and include all information that is related to the IED object in PCM600. The pre-configuration is bound to a specific hardware configuration.
Page 47 Create an own configuration, export the configuration as *.pcmi file and use it to configure other IEDs. Procedure to insert a pre-configuration Right-click the bay and select Import ... to select the IED template file (*.pcmi) that was downloaded from the ABB website , see Figure IEC09000644-1-en.vsd...
Page 48: Setting Ied Ip Address In The Project
Section 4 1MRS756800 A Setting up a project the own configuration. The only requirement is that all needed hardware and software options are available. 4.6.1 Setting IED IP address in the project There are two alternatives to set IP address of the IED object in PCM600. The IED object in PCM600 must have the same IP address and subnetwork mask as the front or rear port on the physical IED to which the PC is connected.
Page 49: Setting Technical Key
Section 4 1MRS756800 A Setting up a project IEC09000362-1-en.vsd IEC09000362 V1 EN Figure 28: Alternative 2: IP address via IED Object Properties window Procedure Select the IED to enter the IP address. Open the Object Properties window. Place the cursor in the IP address row and enter the IP address. The used alternative depends on the time at which the IP address is available.
Page 50 Section 4 1MRS756800 A Setting up a project When writing a configuration to the IED, PCM600 checks the mismatch between the IED object and the physical IED technical key, if any. For communication between the IED and PCM600 the technical key must be the same. Users have the option to read the technical key from the IED and update it to PCM600 or write the PCM600 technical key to the IED.
Page 51 Section 4 1MRS756800 A Setting up a project IEC09000379-1-en.vsd IEC09000379 V1 EN Figure 30: PCM600: Set technical key menu at IED level A dialog window opens to inform about the technical key concept. Click OK in the dialog window. The technical key is read from the IED and the technical key editor window opens, see Figure IEC09000380-1-en.vsd...
Page 52: Using 630 Devices In Com600 Project
Section 4 1MRS756800 A Setting up a project Be sure to not use a technical key with more than 10 characters. Click OK to confirm the selection. It is not possible to set a user defined name or select the Technical key in IED if the value is the same as already given to another IED object in the PCM600 project.
Page 53 Section 4 1MRS756800 A Setting up a project IEC09000687-1-en.vsd IEC09000687 V1 EN Figure 33: Export SCD file from PCM600 and import it to SAB600 Select the correct IEC 61850 Client identification in the IEC 61850 OPC Server properties to enable the event reporting for imported IEDs. Create new generic device in SAB600 project, see Figure IEC09000394-1-en.vsd...
Page 54: Enabling Web Server
Section 4 1MRS756800 A Setting up a project IEC09000395-1-en.vsd IEC09000395 V1 EN Figure 35: Import exported CID file for created generic device Using 630 series device as a generic 61850 device supports the following functionality: • Controlling switch gear • Monitoring measured values •...
Page 55: Using The Web Hmi
Section 4 1MRS756800 A Setting up a project IEC09000397-1-en.vsd IEC09000397 V1 EN Figure 37: WEB Server available in COM600 substation view Using the Web HMI WHMI is disabled by default. To enable the WHMI, select Main menu/Configuration/HMI/Web HMI/ Operation via the LHMI. To open the WHMI, write the IED IP address to the address bar of the browser.
Page 57: Section 5 Protection And Control Engineering
Section 5 1MRS756800 A Protection and control engineering Section 5 Protection and control engineering Creating an application configuration with ACT 5.1.1 Overview ACT is used to create the application configuration for an IED. The application configuration is built up with function blocks. Function blocks are dedicated for different functionality, for example: •...
Page 58: Function Blocks
Section 5 1MRS756800 A Protection and control engineering SMT is not supporting signals of integer type or group signals. So, even if these types of signals are set as visible for SMT, they will not be shown in SMT. • Document the application configuration, for example to make printouts.
Page 59: Signals And Signal Management
Section 5 1MRS756800 A Protection and control engineering IEC08000258.vsd IEC08000258 V1 EN Figure 38: ACT: Function block overview Connection(s) User defined function block name Function block, selected (red) Mandatory signal (indicated by a red triangle if not connected) Function block name Function block, locked (red) ANSI symbol Inverted output...
Page 60: Function Block Execution Parameters
Section 5 1MRS756800 A Protection and control engineering Signals are located on both sides of the middle position up and down. When there is space left, move some signals up or down for a better visibility and connection routing. Boolean input and output signals may need to be inverted to fulfill the logic. ACT supports to add the inversion logic to a binary signal.
Page 61 Section 5 1MRS756800 A Protection and control engineering IEC08000269.vsd IEC08000269 V1 EN Figure 39: ACT: function block organization parameters The Cycle Time can be selected to 3, 5, 10, 100 or 200 ms. Depending on function block type and the 630 series product only one or more possibilities may be available. •...
Page 62 The task is started periodically by the clock and the end trigger of the 20 ms task The combination Execution Order, Instance Number is predefined by ABB. Mainly for basic logic function blocks like for example AND, OR, a set of combinations spread over the full range of execution orders is available.
Page 63 Section 5 1MRS756800 A Protection and control engineering IEC09000688-1-en.vsd IEC09000688 V1 EN Figure 41: Cycle time and execution order A function block type can be defined to be a member of one or several cycle times. A function block instance can be set only to one cycle time. See examples for 630 series: In order to have full advantage of the fast 5 ms and 3 ms cycle times all function blocks in the signal chain need to have the same cycle time.
Page 64: Configuration Parameters
Section 5 1MRS756800 A Protection and control engineering Execution Flow Execution order Execution order Execution order group 1 group 2 group 3 IEC08000271.vsd IEC08000271 V1 EN Figure 42: ACT: Concept of Execution order sequence In the conceptual MainApplication example in Figure 42, the execution order of the main function block in the execution order group 2 defines the execution orders...
Page 65: Hardware Channels
Section 5 1MRS756800 A Protection and control engineering IEC08000304.vsd IEC08000304 V1 EN Figure 43: ACT: Warning message by signal mismatch for a connection 5.1.7 Hardware channels Hardware channels can only be connected to a function block input or output. A hardware connection can be established in ACT or SMT.
Page 66: Validation
Section 5 1MRS756800 A Protection and control engineering IEC09000613-1-en.vsd IEC09000613 V1 EN Figure 44: ACT: HW signal channels 5.1.8 Validation Validation checks the application configuration on errors about the rules and restrictions defined for doing a MainApplication on three levels. •...
Page 67 Section 5 1MRS756800 A Protection and control engineering • Example: A variable connected to an output signal that is not connected. • Example: If the user connects output from higher execution order function to inputs of lower execution order function. •...
Page 68: Setting Configuration And Setting Parameters In Pst
Section 5 1MRS756800 A Protection and control engineering Validation when writing to the IED When writing the application configuration to the IED an automatic validation is performed. The validation is the same as the manually demanded validation. Errors will abort the writing. Setting configuration and setting parameters in PST Configuration parameters and settings parameters are changeable either from LHMI or from PST in PCM600.
Page 69: Connecting Signals In Smt
Section 5 1MRS756800 A Protection and control engineering Connecting signals in SMT SMT is used to do cross references, see Figure • between physical IO signals and function blocks. • for the GOOSE engineering. Binary Input Binary Output Analog SMAI Input GOOSE IEC 61850...
Page 70: Engineering Control Functions
Section 5 1MRS756800 A Protection and control engineering Connections made in SMT will automatically also be shown in ACT. IEC08000150.vsd IEC08000150 V1 EN Figure 47: SMT Connection between binary input channels to binary input signals Depending on the IED capability, SMT has a separate sheet for each possible combination.
Page 71 Section 5 1MRS756800 A Protection and control engineering Station HMI Station bus Local Local Local RE_630 RE_630 RE_630 Apparatus Apparatus Apparatus Control Control Control Breakers, Disconnectors & Earthing switches IEC09000603-1-en.vsd IEC09000603 V1 EN Figure 48: Overview of the apparatus control function The apparatus control function has the following features: •...
Page 72: Remote/Local Switch
Section 5 1MRS756800 A Protection and control engineering interlocking (SCILO) in Figure 49 is the logical node for interlocking. Control operation can be performed from the local HMI. IEC 61850 -QB1 -QA1 QCCBAY DAXCBR GNRLCSWI SCILO -QB9 DAXSWI SCILO GNRLCSWI IEC09000601-1-en.vsd IEC09000601 V1 EN Figure 49:...
Page 73: Bay Control
Section 5 1MRS756800 A Protection and control engineering (ACT). It is also required that the setting Control mode of LOCREM function is set to External LR-switch switch. Connecting External R/L Binary to LOCREM Switch Inputs Card function LOCREM CTRLOFF Local LOCCTRL REMCTRL Remote...
Page 74 Section 5 1MRS756800 A Protection and control engineering command is activated, it will not allow to perform any close or open operation on the apparatus. The message that is displayed on the Display page when any operation is tried to perform with blocking of command connected to TRUE is as shown in Figure IEC09000604-1-en.vsd...
Page 75 Section 5 1MRS756800 A Protection and control engineering IEC09000605-1-en.vsd IEC09000605 V1 EN Figure 52: Typical Power system topology The interlocking logic for earth switch for the topology is shown in Figure IEC09000606-1-en.vsd IEC09000606 V1 EN Figure 53: Interlocking condition for earth switch for power system topology The output of this interlocking condition ES_EN, is connected to functional input of SCILO at OPEN_EN and CLOSE_EN as shown in Figure...
Page 76 Section 5 1MRS756800 A Protection and control engineering logical TRUE may be connected to OPEN_EN and CLOSE_EN may be connected with condition obtained from the logic prepared. The POSOPEN and POSCLOSE inputs of SCILO require the information about the current status of the apparatus for which the SCILO is used. For example, in the earth switch, the binary input indicating the information about the earth switch in open position and closed position is connected to POSOPEN and POSCLOSE inputs of the SCILO respectively.
Page 77: Switch Control
Section 5 1MRS756800 A Protection and control engineering IEC09000609-1-en.vsd IEC09000609 V1 EN Figure 56: Connection of enable open and close connection between SCILO nd GNRLCSWI 5.4.4 Switch control The Switch controller, GNRLCSWI, initializes all operations for one apparatus and performs the actual switching and is more or less the interface to the drive of one apparatus.
Page 78 Section 5 1MRS756800 A Protection and control engineering • By using local automation function that is, AU_OPEN, and AU_CLOSE inputs • From the Local panel L_SEL, L_OPEN and L_CLOSE inputs • Directly by selecting the apparatus from the Display page and using Open/ Close button available on local HMI.
Page 79 Section 5 1MRS756800 A Protection and control engineering GNRLCSWI DAXCBR EXE_CL CLOSE SYNC_OK START_SYN SYN_INPRO SYNCRSYN CLOSE CB Synchro Synchronizing Check function IEC09000602-1-en.vsd IEC09000602 V1 EN Figure 57: Example of interaction between GNRLCSWI, SYNCRSYN (synchrocheck and synchronizing function) and DAXCBR functions RES_EXT input deals with the reservation functionality.
Page 80: Circuit Breaker/Circuit Switch
Section 5 1MRS756800 A Protection and control engineering The present status information of the apparatus, that is, open or closed or intermediate stage is available to GNRLCSWI function from the switch function DAXCBR/DAXSWI via XPOS input. The XPOS input of GNRLCSWI is connected to XPOS output of DAXCBR/DAXSWI.
Page 81 Section 5 1MRS756800 A Protection and control engineering If the function is blocked to perform opening or closing operation, the same will be indicated as OP_BLKD and CL_BLKD outputs. The blocking of execution of position updates if any by QCCBAY function is reflected at UPD_BLKD output. CNT_VAL indicates the number of closing and opening operation performed by the apparatus, the same can be reset via RS_OPR_CNT input.
Page 83: Section 6 Local Hmi Engineering
Section 6 1MRS756800 A Local HMI engineering Section 6 Local HMI engineering LED and function key engineering 6.1.1 Local HMI engineering process The engineering process of the LEDLHMI involves several steps. Figure 60 presents the pre-engineering step, the main steps in the engineering process and the required sequences.
Page 84 Section 6 1MRS756800 A Local HMI engineering • To use the function keys and LEDs on LHMI it is needed to insert the corresponding special function blocks for these operation element groups. • The function blocks for the LEDs are organized as single function block per LED but indexed to the group identification, for example GRP1_LED3 (indication LED 3 in virtual LED group 1).
Page 85 Section 6 1MRS756800 A Local HMI engineering IEC08000375 V1 EN Figure 61: Local HMI: Placement of local HMI operation elements Function block LEDGEN • Handles an external acknowledge signal as source to acknowledge the LEDs. • Generates an additional pulse for general purposes whenever the LEDs are acknowledged by the operator.
Page 86 Section 6 1MRS756800 A Local HMI engineering 'Multifunction' key [a] to toggle between the three groups or the 'Clear' key [b] to acknowledge or reset the LEDs. • Only the programming of the signals is needed for the LEDs. • The operation mode of the LEDs is defined in PST.
Page 87 Section 6 1MRS756800 A Local HMI engineering IEC09000656-1-en.vsd IEC09000656 V1 EN Figure 62: LHMI: Function key operation mode The LEDs have a number of different operation modes, see Figure • General definitions • Each LED can illuminate in one of three colors: RED, YELLOW, GREEN. •...
Page 88: Led Operation Modes
Section 6 1MRS756800 A Local HMI engineering • The same as LatchedAck-F-S but the LED starts with steady state and flashes after acknowledgment. • LatchedColl-S • The LED illuminates in all cases in steady mode only • The LED latches a signal change from OFF-ON until it is acknowledged by the operator.
Page 89 Section 6 1MRS756800 A Local HMI engineering General operation definitions for the LEDs: • Each LED can illuminate in one of three colors: RED, YELLOW, GREEN • Only one color is illuminated at a time • The priority for illumination and the color is linked •...
Page 90 Section 6 1MRS756800 A Local HMI engineering This is the same mode as Follow-S but the LED illuminates flashing, see Figure This mode may be used to indicate that a tap changer or Petersen coil is moving. LED operation mode LatchedAck-F-S Illumination =>...
Page 91 Section 6 1MRS756800 A Local HMI engineering • All colors (signals) are acknowledged and they will illuminate in steady state. • Incoming additional signals with lower priority will illuminate when they become the highest priority in steady mode. • One or more signals with higher priority are changing to ON after an acknowledgement.
Page 92 Section 6 1MRS756800 A Local HMI engineering This mode catches a signal change to ON and the LED stays ON until the operator resets the LEDs for this group. If the signal is still ON when a reset LED is done, the LED will illuminated again. This occurs when the application configuration accesses the signal again in the next cycle after reset.
Page 93: Single Line Diagram Engineering
Section 6 1MRS756800 A Local HMI engineering tMax tRestart Auto- Reset Man- Reset S1LED S2LED S3LED S4LED Illumination => = Steady = Flash IEC08000401.vsd IEC08000401 V1 EN Figure 71: LHMI LED operation mode LatchedReset-S / 2 Single line diagram engineering Phase angles are shown as radians in single line diagram (GDE measurand) symbols but in degrees in other views on the LHMI.
Page 94 Section 6 1MRS756800 A Local HMI engineering HMI display Regard the window pages squence of pages Symbol library IED HMI window display window IEC08000123.vsd IEC08000123 V1 EN Figure 72: GDE: Screen image with active GDE Procedure Start GDE to open a presentation of the tool. GDE has a fixed symbol library window on the left side of the display.
Page 95: Symbol Library
Section 6 1MRS756800 A Local HMI engineering • Several single line diagrams can be created for one bay. • The IED supports one bay. • The sequence order of the HMI pages in the graphical display editor starts from left to right. •...
Page 96 Section 6 1MRS756800 A Local HMI engineering IEC08000127.vsd IEC08000127 V1 EN Figure 73: GDE: Dynamic Text symbols The standard (IEC or ANSI) for the symbols and the selection of the font size for the text elements can be changed using the two selector boxes on top of the page window.
Page 97: Bay Configuration Engineering
Section 6 1MRS756800 A Local HMI engineering Doing Link to draw lines The line width has to fit to the line width used for the symbols. The standard size is 2. Choose the line width in a selection box placed in the upper area above the page. A line that is not connected to a symbol may be done in any line width in the range 1 - 5.
Page 98 Section 6 1MRS756800 A Local HMI engineering Make a sketch how to present the single line diagram. Place the apparatus, transformer and other symbols that are needed for the single line diagram into the raster boxes. Add connection points where needed. Link the apparatus symbols with line elements.
Page 99 Section 6 1MRS756800 A Local HMI engineering • ACT to program the application function block for apparatus and/or measurements. • PST to adapt the settings and/or configuration parameter of the application function block. • GDE to establish the link for updating the selected data attribute in the HMI of the application function block.
Page 100 Section 6 1MRS756800 A Local HMI engineering IEC08000125.vsd IEC08000125 V1 EN Figure 76: GDE: Input signal selection The ordering number in the selection window of the process objects corresponds to the number given in the PST tree and to the application function block in ACT. Only those apparatus and measurements are shown that are configured in the application configuration program.
Page 101: Events And Indications
Section 6 1MRS756800 A Local HMI engineering Events and indications To get IED events to the LHMI event list and indications for Ready, Start and Trip indication LEDs, disturbance report needs to be engineered. Detailed information about disturbance report subfunctions is found in the technical manual.
Page 103: Section 7 Iec 61850 Communication Engineering
Section 7 1MRS756800 A IEC 61850 communication engineering Section 7 IEC 61850 communication engineering IEC 61850 interface in the IED and tools More information about the implementation of IEC 61850 in IEDs is available in the IEC 61850 communication protocol manual. 7.1.1 Function view for IEC 61850 in PCM600 The IED function blocks have a design based on the demands and advantages of...
Page 104: Goose Data Exchange
Section 7 1MRS756800 A IEC 61850 communication engineering GOOSE GOOSE GOOSE Receive Receive Receive GOOSE GOOSE GOOSE Send Send Send with monitoring only part Commands with part Event monitoring handler commands Event queue part IEC08000364.vsd IEC08000364 V1 EN Figure 78: IEC 61850: Communication interface principle IEC 61850 has as a concept for the identification of all signals for communication that belong to a function by a logical node as a placeholder.
Page 105: Station Configuration Description File Types
• An IED is already extended by default data sets. They are predefined by ABB. Changes or additional data sets, for example, have to be done with CCT600. • SCD = Station Configuration Description...
Page 106: Iec 61850 Engineering Procedure
Section 7 1MRS756800 A IEC 61850 communication engineering • Complete configuration description of all IEDs in a station and the full engineering of process signals and communication structure is included. This includes all needed data sets and all control blocks. •...
Page 107: Exporting Scl Files From Pcm600
Section 7 1MRS756800 A IEC 61850 communication engineering Export SCL files from PCM600. In the scenario in Figure 80 it is a SCD file. Other SCL file types are possible to export. Configure horizontal and vertical communication in the station configuration tool, for example CCT600.
Page 108: Exporting Icd Or Cid Files
Section 7 1MRS756800 A IEC 61850 communication engineering Station IEC08000415.vsd IEC08000415 V1 EN Figure 81: IEC 61850: Export SCD step 1 Right-click the station and select Export ..Select a location from the open standard Windows menu to store the file and name it.
Page 109: Engineering Of Vertical And Horizontal Communication In Cct600
Section 7 1MRS756800 A IEC 61850 communication engineering IEC08000416.vsd IEC08000416 V1 EN Figure 83: IEC 61850: Export IED file type selection The SCL Export Options window opens. Select Export Private Sections, Export As SCL Template or Include Goose Sending IEDs and click Export, see Figure IEC08000418.vsd IEC08000418 V1 EN...
Page 110 Section 7 1MRS756800 A IEC 61850 communication engineering IEC09000628-1-en.vsd IEC09000628 V1 EN Figure 85: CCT600 Import SCL file Do vertical communication engineering (monitoring direction). 3.1. Check the default data sets, see Figure IEC09000630-1-en.vsd IEC09000630 V1 EN Figure 86: CCT600 data sets default content 3.2.
Page 111 Section 7 1MRS756800 A IEC 61850 communication engineering The data set for GOOSE may contain signals on data attribute level or on FCDA level. The latter is also called structured GOOSE. 3.3. Configure additional Report Control Blocks when needed for each data set used for vertical communication.
Page 112: Importing Scl Files To Pcm600
Section 7 1MRS756800 A IEC 61850 communication engineering Importing SCL files to PCM600 The IED engineering tool must be able to receive a SCD file or an ICD file as import to receive the engineered communication extensions, for example for the different IEDs.
Page 113 Section 7 1MRS756800 A IEC 61850 communication engineering 5.1. Make connections between the signals that the server is sending and the GOOSE receive interface function blocks (GOOSEBINRCV and GOOSEINTLKRCV) on the client’s side. If a client is defined for GOOSE receive then at least one cross in SMT is required to be able to write the configuration to the IED.
Page 114: Importing Icd Or Cid Files
Section 7 1MRS756800 A IEC 61850 communication engineering IEC09000616-1-en.vsd IEC09000616 V1 EN Figure 88: Common write menu 7.5.2 Importing ICD or CID files Procedure to import a complete ICD file or CID file: Select an existing IED to import IEC 61850 files. Select the file type of IEC 61850 to import from the Files of type drop down list (ICD or CID) The SCL Import Option menu opens, which queries how the file should be...
Page 115: Communication Configuration Tool Engineering
Section 7 1MRS756800 A IEC 61850 communication engineering 3.1. Ignore Substation Section will not import the "SSD-file" part of the SCD- file. 3.2. Don't import ... protects the existing IEDs in case the SCD file does not match the original configuration in PCM600. 3.3.
Page 116 Section 7 1MRS756800 A IEC 61850 communication engineering Click View and select Unhide Panel to open the Project Navigator window. Expand the Substation Section in the Project Navigator window. Right-click Q1 and select Create new Conducting Equipment, see Figure IEC09000693-1-en.vsd IEC09000693 V1 EN Figure 90: CCT600: Creating new conducting equipment...
Page 117: Iec61850 Object Mapping
Section 7 1MRS756800 A IEC 61850 communication engineering IEC09000694-1-en.vsd IEC09000694 V1 EN Figure 91: CCT600: Property window for conducting equipment Expand the Type Information section and select the properties for Equipment Type, that is CBR for circuit breaker and DIS for disconnector and earthswitch, for example. Select False for Virtual.
Page 118 Section 7 1MRS756800 A IEC 61850 communication engineering IEC09000696-1-en.vsd IEC09000696 V1 EN Figure 92: CCT600: IEC61850 object mapping With the IEC61850 Object Mapping window open, go to the Project Navigator window and select IED Section. Expand the IED Section to see all the Logical Nodes (LN) names of the functions available in the configuration as shown in Figure 630 series...
Page 119 Section 7 1MRS756800 A IEC 61850 communication engineering IEC09000697-1-en.vsd IEC09000697 V1 EN Figure 93: CCT600: Expanded IED section window Drag and drop all logical nodes into the IEC61850 Object Mapping under Conduction equipment or Bay. For example: Conduction equipment Q0 is a circuit breaker. The functions associated with Q0 in the configuration are interlocking function (SCILO1), Switch control (GNRLCSWI1) and Circuit breaker (DAXCBR1).
Page 120 Section 7 1MRS756800 A IEC 61850 communication engineering IEC09000698-1-en.vsd IEC09000698 V1 EN Figure 94: CCT600: Logical nodes for conduction equipment Q0 configured as circuit breaker Normally the logical nodes associated with circuit breakers are SCILO, GNRLCSWI and DAXCBR whereas the logical nodes associated with disconnector or earthswitch are SCILO, GNRLCSWI and DAXSWI.
Page 121: Report Control Engineering
Section 7 1MRS756800 A IEC 61850 communication engineering 7.6.3 Report control engineering Procedure Open the Report Control Engineering option in the main window in CCT600. Go to the Project Navigator window and select IED Section. Expand the IED Section to see all the logical nodes available in the configuration. Select LLNO, the logical node that has 4 vertical dots, from the list as shown in Figure 96 IEC09000700-1-en.vsd...
Page 122 Section 7 1MRS756800 A IEC 61850 communication engineering The number of report control blocks to be added depends on the data set available in the project (configuration). IEC09000702-1-en.vsd IEC09000702 V1 EN Figure 98: CCT600: Drop down menu indicating DataSet available in the configuration Right-click the report control block to rename it for each data set, for example rcb‘DataSet'.
Page 123: Horizontal Communication Engineering
Section 7 1MRS756800 A IEC 61850 communication engineering 7.6.4 Horizontal communication engineering Configure GOOSE Control Blocks for each data set configured for GOOSE messages. Procedure Select first LD0->LLN0 in the project navigator window and then select the Goose Control Engineering tab. Click Add->GSE Control and select the proper data set from the DataSet drop down list.
Page 124: Writing Communication Configuration To Ied
Section 7 1MRS756800 A IEC 61850 communication engineering GOOSE transmission fails. Be sure to configure the data sets to not include any analog data. Be sure to set the same GoID for sending and receiving GOOSE messages. Note that one data must only be included in a Goose data set once. Define client IEDs for each GOOSE Control Block.
Page 125 Section 7 1MRS756800 A IEC 61850 communication engineering Click Yes in the Update Communication window to update the communication configuration part in the IED. Click No in the Update Communication window to keep the communication configuration part in the IED. Other parts of the configuration will be updated. If no change has been done to the communication configuration part, select No in the Update Communication window.
Page 127: Section 8 Dnp3 Communication Engineering
Section 8 1MRS756800 A DNP3 communication engineering Section 8 DNP3 communication engineering Signal configuration user information Basic knowledge about DNP3 and the used definitions are required to use CMT. See the DNP3 communication protocol manual for information on the DNP3 implementation in the IED. CMT allows to configure the signals that are used to communicate with clients or master units for DNP3 protocols.
Page 128 Section 8 1MRS756800 A DNP3 communication engineering Save the actual project configuration in PCM600 to make all signals visible for CMT. Right-click the IED in the plant structure and select Communication Management to start the Communication management tool. Select the DNP3 protocol from the new window and click OK. Figure 105 presents the design of the two container windows, which open after the selection of DNP3.
Page 129: Setting Dnp3 Signal Parameters
Section 8 1MRS756800 A DNP3 communication engineering IEC08000361.vsd IEC08000361 V1 EN Figure 106: CMT: Move buttons Click the drop down list Signal Type: to select the other signal types for this channel. Repeat to move signals for all signal types and save the selection. Content changes in the DNP3 container are marked with a star at the end of the name, see Figure...
Page 130 Section 8 1MRS756800 A DNP3 communication engineering IEC08000336.vsd IEC08000336 V1 EN Figure 108: CMT: Context menu in DNP3 window The selection window shows the number of signals selected, see Figure 109. IEC08000363.vsd IEC08000363 V1 EN Figure 109: CMT: Set Index menu Define the Starting index for this group and click OK.
Page 131: Configuring Dnp3 Class
Section 8 1MRS756800 A DNP3 communication engineering 8.3.1 Configuring DNP3 class In DNP3 the user classifies the signals and defines those signals that are not member of any class. CMT has a default predefined organization of classes per signal type. In the master station the classes can be polled in sequences according to the demands in the project.
Page 133: Section 9 Glossary
Section 9 1MRS756800 A Glossary Section 9 Glossary Alternating current Application Configuration Tool in PCM600; Trip status ANSI American National Standards Institute CCT600 Communication Configuration Tool Configured IED description Communication Management Tool in PCM600 COM600 An all-in-one communication gateway, automation platform and user interface solution for utility and industrial distribution substations Connectivity package A collection of software and information related to a...
Page 134 Section 9 1MRS756800 A Glossary Input/output IED capability description International Electrotechnical Commission IEC 61850 International standard for substation communication and modelling Intelligent electronic device Internet protocol IP address A set of four numbers between 0 and 255, separated by periods. Each server connected to the Internet is assigned a unique IP address that specifies the location for the TCP/IP protocol.
Page 135 1MRS756800 A Glossary Signal Matrix Tool in PCM600 SOTF Switch on to fault Strömberg protection acquisition. ABB proprietary serial master-slave protocol used in substation automation for point-to-point communication. Structured query language Station Network node or a device connected to a network...
Page 140 Contact us ABB Oy Distribution Automation P.O. Box 699 FI-65101 VAASA, Finland Phone +358 10 22 11 +358 10 22 41094 www.abb.com/substationautomation...

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