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RELION® 611 SERIES
Voltage Protection and Control
REU611
Application Manual
Document ID: 1MRS758335
Issued: 2019-04-10
Revision: D
Product version: 2.0
© Copyright 2019 ABB. All rights reserved
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.
Trademarks
ABB and Relion are registered trademarks of the ABB Group. All other brand or product names mentioned in this document may be trademarks or registered trademarks of their respective holders.
Warranty
Please inquire about the terms of warranty from your nearest ABB representative.
www.abb.com/relion
Disclaimer
The data, examples and diagrams in this manual are included solely for the concept or product description and are not to be deemed as a statement of guaranteed properties.
All persons responsible for applying the equipment addressed in this manual must satisfy themselves that each intended application is suitable and acceptable, including that any applicable safety or other operational requirements are complied with. In particular, any risks in applications where a system failure and/or product failure would create a risk for harm to property or persons (including but not limited to personal injuries or death) shall be the sole responsibility of the person or entity applying the equipment, and those so responsible are hereby requested to ensure that all measures are taken to exclude or mitigate such risks.
This product has been designed to be connected and communicate data and information via a network interface which should be connected to a secure network.
It is the sole responsibility of the person or entity responsible for network administration to ensure a secure connection to the network and to take the necessary measures (such as, but not limited to, installation of firewalls, application of authentication measures, encryption of data, installation of anti virus programs, etc.) to protect the product and the network, its system and interface included, against any kind of security breaches, unauthorized access, interference, intrusion, leakage and/or theft of data or information. ABB is not liable for any such damages and/or losses.
This document has been carefully checked by ABB but deviations cannot be completely ruled out. 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.
Conformity
This product complies with the directive of the Council of the European Communities on the approximation of the laws of the Member States relating to electromagnetic compatibility (EMC Directive 2014/30/EU) and concerning electrical equipment for use within specified voltage limits (Low-voltage directive 2014/35/EU). This conformity is the result of tests conducted by ABB in accordance with the product standard EN 60255-26 for the EMC directive, and with the product standards EN
60255-1 and EN 60255-27 for the low voltage directive. The product is designed in accordance with the international standards of the IEC 60255 series.
Table of contents
REU611
Application Manual
Table of contents
Section 1 Introduction.......................................................................3
Intended audience.............................................................................. 3
Product documentation.......................................................................4
Product documentation set............................................................4
Document revision history............................................................. 4
Related documentation..................................................................5
Symbols and conventions...................................................................5
Symbols.........................................................................................5
Document conventions..................................................................6
Functions, codes and symbols...................................................... 6
Section 2 REU611 overview.............................................................9
Product version history..................................................................9
PCM600 and relay connectivity package version..........................9
Operation functionality......................................................................10
Optional functions........................................................................10
Physical hardware............................................................................ 10
Display.........................................................................................12
LEDs............................................................................................13
Keypad........................................................................................ 13
Web HMI...........................................................................................14
Command buttons....................................................................... 15
Authorization.....................................................................................16
Audit trail......................................................................................17
Communication.................................................................................19
Self-healing Ethernet ring............................................................20
Ethernet redundancy................................................................... 21
Secure communication................................................................23
Section 3 REU611 standardized configuration ............................. 25
Standardized configuration...............................................................25
Switch groups................................................................................... 26
Input switch group ISWGAPC..................................................... 26
Output switch group OSWGAPC.................................................27
Selector switch group SELGAPC................................................ 27
Connection diagrams........................................................................29
Configuration A.................................................................................31
1
2
Table of contents
Applications................................................................................. 31
Functions.....................................................................................32
Default I/O connections.......................................................... 32
Predefined disturbance recorder connections........................33
Functional diagrams ................................................................... 33
Functional diagrams for protection......................................... 34
Functional diagrams for control ............................................. 41
Switch groups .............................................................................43
Binary inputs ..........................................................................44
Internal signal ........................................................................ 48
Binary outputs and LEDs .......................................................49
GOOSE.................................................................................. 67
Section 4 Protection relay's physical connections..........................69
Energizing inputs.........................................................................69
Phase voltage.........................................................................69
Residual voltage.....................................................................69
Auxiliary supply voltage input...................................................... 69
Binary inputs................................................................................70
Outputs for tripping and controlling..............................................70
Outputs for signalling...................................................................71
IRF...............................................................................................71
Section 5 Glossary......................................................................... 73
REU611
Application Manual
1MRS758335 D
Section 1 Introduction
1.1
1.2
Section 1
Introduction
This manual
The application manual contains application descriptions and setting guidelines sorted per function. The manual can be used to find out when and for what purpose a typical protection function can be used. The manual can also be used when calculating settings.
Intended audience
This manual addresses the protection and control engineer responsible for planning, pre-engineering and engineering.
The protection and control engineer must be experienced in electrical power engineering and have knowledge of related technology, such as protection schemes and principles.
REU611
Application Manual
3
Section 1
Introduction
1.3
1.3.1
Product documentation
Product documentation set
1MRS758335 D
4
1.3.2
Quick start guide
Quick installation guide
Brochure
Product guide
Operation manual
Installation manual
Connection diagram
Engineering manual
Technical manual
Application manual
Communication protocol manual
IEC 61850 engineering guide
Point list manual
Cyber security deployment guideline
GUID-0777AFDA-CADF-4AA9-946E-F6A856BDF75E V1 EN
Figure 1: The intended use of manuals in different lifecycles
Product series- and product-specific manuals can be downloaded from the ABB Web site http://www.abb.com/relion .
Document revision history
Document revision/date
A/2016-02-22
B/2016-10-11
C/2017-10-31
D/2019-04-10
Product version
2.0
2.0
2.0
2.0
History
First release
Content updated
Content updated
Content updated
Download the latest documents from the ABB Web site http://www.abb.com/substationautomation .
REU611
Application Manual
1MRS758335 D
1.3.3
1.4
1.4.1
REU611
Application Manual
Section 1
Introduction
Related documentation
Name of the document
Modbus Communication Protocol Manual
IEC 61850 Engineering Guide
Engineering Manual
Installation Manual
Operation Manual
Technical Manual
Cyber Security Deployment Guideline
Document ID
1MRS757461
1MRS757465
1MRS241255
1MRS757452
1MRS757453
1MRS757454
1MRS758337
Symbols and conventions
Symbols
The electrical warning icon indicates the presence of a hazard which could result in electrical shock.
The warning icon indicates the presence of a hazard which could result in personal injury.
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.
The information icon alerts the reader of important facts and conditions.
The tip icon indicates advice on, for example, how to design your project or how to use a certain function.
Although warning hazards are related to personal injury, it is necessary to understand that under certain operational conditions, operation of damaged equipment may result in degraded process performance leading to personal injury or death. Therefore, comply fully with all warning and caution notices.
5
6
Section 1
Introduction
1.4.2
1.4.3
1MRS758335 D
Document conventions
A particular convention may not be used in this manual.
• Abbreviations and acronyms are spelled out in the glossary. The glossary also contains definitions of important terms.
• Push button navigation in the LHMI menu structure is presented by using the push button icons.
To navigate between the options, use and .
• Menu paths are presented in bold.
Select Main menu/Settings .
• LHMI messages are shown in Courier font.
To save the changes in nonvolatile memory, select Yes and press .
• Parameter names are shown in italics.
The function can be enabled and disabled with the Operation setting.
• Parameter values are indicated with quotation marks.
The corresponding parameter values are "On" and "Off".
• Input/output messages and monitored data names are shown in Courier font.
When the function starts, the START output is set to TRUE.
• This document assumes that the parameter setting visibility is "Advanced".
Functions, codes and symbols
Table 1:
Function
Protection
Functions included in the relay
IEC 61850
Residual overvoltage protection, instance 1
Residual overvoltage protection, instance 2
Residual overvoltage protection, instance 3
Three-phase undervoltage protection, instance 1
Three-phase undervoltage protection, instance 2
Three-phase undervoltage protection, instance 3
Three-phase overvoltage protection, instance 1
Three-phase overvoltage protection, instance 2
Three-phase overvoltage protection, instance 3
Positive-sequence undervoltage protection, instance 1
Table continues on next page
ROVPTOV1
ROVPTOV2
ROVPTOV3
PHPTUV1
PHPTUV2
PHPTUV3
PHPTOV1
PHPTOV2
PHPTOV3
PSPTUV1
IEC 60617 IEC-ANSI
Uo> (1)
Uo> (2)
Uo> (3)
3U< (1)
3U< (2)
3U< (3)
3U> (1)
3U> (2)
3U> (3)
U1< (1)
59G (1)
59G (2)
59G (3)
27(1)
27(2)
27(3)
59(1)
59(2)
59(3)
47U+(1)
REU611
Application Manual
1MRS758335 D
Section 1
Introduction
Function
Positive-sequence undervoltage protection, instance 2
Negative-sequence overvoltage protection, instance 1
Negative-sequence overvoltage protection, instance 2
Frequency protection, instance 1
Frequency protection, instance 2
Master trip, instance 1
Master trip, instance 2
Other
Input switch group 1)
Output switch group 2)
IEC 61850
PSPTUV2
NSPTOV1
NSPTOV2
FRPFRQ1
FRPFRQ2
TRPPTRC1
TRPPTRC2
ISWGAPC
OSWGAPC
Selector 3)
Minimum pulse timer (2 pcs) 4)
Move (8 pcs), instance 1
Control
Circuit-breaker control
SELGAPC
TPGAPC
MVGAPC
CBXCBR1
Condition monitoring and supervision
Trip circuit supervision, instance 1
Trip circuit supervision, instance 2
TCSSCBR1
TCSSCBR2
Logging
Disturbance recorder
Fault recorder
RDRE1
FLTRFRC1
Measurement
Three-phase voltage measurement, instance 1
Three-phase voltage measurement, instance 2
Sequence voltage measurement, instance 1
Residual voltage measurement
VMMXU1
VMMXU2
VSMSQI1
RESVMMXU1
Frequency measurement, instance 1 FMMXU1
1) 10 instances
2) 20 instances
3) 6 instances
4) 10 instances
IEC 60617
U1< (2)
U2> (1)
IEC-ANSI
47U+(2)
47O-(1)
U2> (2) 47O-(2) f>/f<,df/dt (1) 81(1) f>/f<,df/dt (2) 81(2)
Master Trip (1) 94/86 (1)
Master Trip (2) 94/86 (2)
ISWGAPC
OSWGAPC
SELGAPC
TP
MV (1)
ISWGAPC
OSWGAPC
SELGAPC
TP
MV (1)
I <-> O CB
TCS (1)
TCS (2)
-
DR (1)
I <-> O CB
TCM (1)
TCM (2)
DFR(1)
FR
3U
3U(B)
U1, U2, U0 f
Uo
3U
3U(B)
U1, U2, U0 f
Vn
REU611
Application Manual
7
8
1MRS758335 D
Section 2 REU611 overview
2.1
2.1.1
2.1.2
REU611
Application Manual
Section 2
REU611 overview
Overview
REU611 is a voltage protection relay preconfigured for voltage and frequency-based protection in utility substations and industrial power systems. The relay is used for a wide variety of applications, including busbar, power transformer, motor and capacitor bank applications.
REU611 is a member of ABB’s Relion ® product family and part of the 611 protection and control product series. The 611 series relays are characterized by their compactness and withdrawable-unit design.
The 611 series offers simplified yet powerful functionality for most applications.
Once the application-specific parameter set has been entered, the installed protection relay is ready to be put into service. The further addition of communication functionality and interoperability between substation automation devices offered by the IEC 61850 standard adds flexibility and value to end users as well as electrical system manufacturers.
The 611 series relays fully support the IEC 61850 standard for communication and interoperability of substation automation devices, including fast GOOSE (Generic
Object Oriented Substation Event) messaging, and can now also benefit from the extended interoperability provided by Edition 2 of the standard. The relays further support the parallel redundancy protocol (PRP) and the high-availability seamless redundancy (HSR) protocol. The 611 series relays are able to use IEC 61850 and
Modbus® communication protocols simultaneously.
Product version history
Product version
2.0
Product history
Product released
PCM600 and relay connectivity package version
• Protection and Control IED Manager PCM600 Ver.2.7 or later
• REU611 Connectivity Package Ver.2.0 or later
•
•
•
•
•
Communication Management
Configuration Wizard
Disturbance Handling
Event Viewer
Fault Record tool
9
Section 2
REU611 overview
2.2
2.2.1
2.3
1MRS758335 D
•
•
•
•
•
•
•
•
•
•
•
Firmware Update
HMI Event Filtering
IEC 61850 Configuration
IED Compare
IED Configuration Migration
IED User Management
Label Printing
Lifecycle Traceability
Parameter Setting
Signal Matrix
Signal Monitoring
Download connectivity packages from the ABB Web site http://www.abb.com/substationautomation or directly with Update
Manager in PCM600.
Operation functionality
Optional functions
• IEEE 1588 time v2 synchronization
• High-availability seamless redundancy protocol (HSR)
• Parallel redundancy protocol (PRP)
Physical hardware
The protection relay consists of two main parts: plug-in unit and case. The content depends on the ordered functionality.
10 REU611
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2.4
Section 2
REU611 overview
Table 2:
Main unit Slot ID
Plug-in unit
-
X100
Plug-in unit and case
Content options
HMI
Auxiliary power/BO module
Case X130
X000
AI/BI module
Optional communication module
Small (4 lines, 16 characters)
48...250 V DC/100...240 V AC; or 24...60 V DC
2 normally-open PO contacts
1 change-over SO contact
1 normally-open SO contact
2 double-pole PO contacts with TCS
1 dedicated internal fault output contact
3 phase voltage inputs (60...210 V)
1 residual voltage input (60...210 V)
1 voltage measurement input (60...210 V)
4 binary inputs
See technical manual for details about different type of communication modules.
Rated values of the current and voltage inputs are basic setting parameters of the protection relay. The binary input thresholds are selectable within the range 16…176
V DC by adjusting the binary input setting parameters.
See the installation manual for more information about the case and the plug-in unit.
The connection diagrams of different hardware modules are presented in this manual.
Table 3:
Conf.
A
Number of physical connections in configuration
CT
Analog channels
-
VT
5
BI
4
Binary channels
BO
6
Local HMI
The LHMI is used for setting, monitoring and controlling the protection relay. The
LHMI comprises the display, buttons, LED indicators and communication port.
REU611
Application Manual
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Section 2
REU611 overview
1MRS758335 D
REF611
Overcurrent
Earth-fault
Phase unbalance
Thermal overload
AR sequence in progress
Disturb.rec.trigged
Trip circuit failure
Breaker failure
2.4.1
12
GUID-E15422BF-B3E6-4D02-8D43-D912D5EF0360 V1 EN
Figure 2: Example of the LHMI
Display
The LHMI includes a graphical display that supports two character sizes. The character size depends on the selected language. The amount of characters and rows fitting the view depends on the character size.
Table 4: Small display
Character size 1)
Small, mono-spaced (6 × 12 pixels)
Large, variable width (13 × 14 pixels)
1) Depending on the selected language
Rows in the view
5
3
Characters per row
20
8 or more
The display view is divided into four basic areas.
REU611
Application Manual
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Section 2
REU611 overview
1 2
2.4.2
2.4.3
3
GUID-24ADB995-439A-4563-AACE-1FAA193A8EF9 V1 EN
Figure 3: Display layout
1 Header
2 Icon
3 Content
4 Scroll bar (displayed when needed)
4
LEDs
The LHMI includes three protection indicators above the display: Ready, Start and
Trip.
There are also 8 programmable LEDs on front of the LHMI. The LEDs can be configured with the LHMI, WHMI or PCM600.
Keypad
The LHMI keypad contains push buttons which are used to navigate in different views or menus. With the push buttons you can give open or close commands to one object in the primary circuit, for example, a circuit breaker, a contactor or a disconnector. The push buttons are also used to acknowledge alarms, reset indications, provide help and switch between local and remote control mode.
REU611
Application Manual
13
Section 2
REU611 overview
1MRS758335 D
2.5
GUID-B681763E-EC56-4515-AC57-1FD5349715F7 V1 EN
Figure 4: LHMI keypad with object control, navigation and command push buttons and RJ-45 communication port
Web HMI
The WHMI allows secure access to the protection relay via a Web browser. When the
Secure Communication parameter in the protection relay is activated, the Web server is forced to take a secured (HTTPS) connection to WHMI using TLS encryption.The
WHMI is verified with Internet Explorer 8.0, 9.0, 10.0 and 11.0.
WHMI is enabled by default.
WHMI offers several functions.
• Programmable LEDs and event lists
• System supervision
• Parameter settings
• Measurement display
• Disturbance records
• Fault records
• Phasor diagram
• Signal configuration
• Importing/Exporting parameters
• Report summary
The menu tree structure on the WHMI is almost identical to the one on the LHMI.
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Section 2
REU611 overview
2.5.1
REU611
Application Manual
GUID-CD531B61-6866-44E9-B0C1-925B48140F3F V2 EN
Figure 5: Example view of the WHMI
The WHMI can be accessed locally and remotely.
• Locally by connecting the laptop to the protection relay via the front communication port.
• Remotely over LAN/WAN.
Command buttons
Command buttons can be used to edit parameters and control information via the
WHMI.
Table 5:
Name
Command buttons
Description
Enabling parameter editing
Disabling parameter editing
Writing parameters to the protection relay
Refreshing parameter values
Printing out parameters
Committing changes to protection relay's nonvolatile flash memory
Table continues on next page
15
Section 2
REU611 overview
2.6
16
1MRS758335 D
Name Description
Rejecting changes
Showing context sensitive help messages
Error icon
Clearing events
Triggering the disturbance recorder manually
Saving values to TXT or CSV file format
Freezing the values so that updates are not displayed
Receiving continuous updates to the monitoring view
Deleting the disturbance record
Deleting all disturbance records
Saving the disturbance record files
Viewing all fault records
Clearing all fault records
Importing settings
Exporting settings
Selecting all
Clearing all selections
Refreshing the parameter list view
Authorization
Four user categories have been predefined for the LHMI and the WHMI, each with different rights and default passwords.
The default passwords in the protection relay delivered from the factory can be changed with Administrator user rights.
User authorization is disabled by default for LHMI but WHMI always uses authorization.
REU611
Application Manual
1MRS758335 D
2.6.1
REU611
Application Manual
Section 2
REU611 overview
Table 6:
Username
VIEWER
OPERATOR
ENGINEER
ADMINISTRATOR
Predefined user categories
•
•
•
•
User rights
Read only access
Selecting remote or local state with
Changing setting groups
Controlling
Clearing indications
(only locally)
•
•
•
•
•
•
•
•
•
Changing settings
Clearing event list
Clearing disturbance records
Changing system settings such as IP address, serial baud rate or disturbance recorder settings
Setting the protection relay to test mode
Selecting language
All listed above
Changing password
Factory default activation
For user authorization for PCM600, see PCM600 documentation.
Audit trail
The protection relay offers a large set of event-logging functions. Critical system and protection relay security-related events are logged to a separate nonvolatile audit trail for the administrator.
Audit trail is a chronological record of system activities that allows the reconstruction and examination of the sequence of system and security-related events and changes in the protection relay. Both audit trail events and process related events can be examined and analyzed in a consistent method with the help of Event List in LHMI and WHMI and Event Viewer in PCM600.
The protection relay stores 2048 audit trail events to the nonvolatile audit trail.
Additionally, 1024 process events are stored in a nonvolatile event list. Both the audit trail and event list work according to the FIFO principle. Nonvolatile memory is based on a memory type which does not need battery backup nor regular component change to maintain the memory storage.
Audit trail events related to user authorization (login, logout, violation remote and violation local) are defined according to the selected set of requirements from IEEE
1686. The logging is based on predefined user names or user categories. The user audit trail events are accessible with IEC 61850-8-1, PCM600, LHMI and WHMI.
17
Section 2
REU611 overview
1MRS758335 D
Table 7: Audit trail events
Audit trail event
Configuration change
Firmware change
Firmware change fail
Attached to retrofit test case
Removed from retrofit test case
Setting group remote
Setting group local
Control remote
Control local
Test on
Test off
Reset trips
Setting commit
Time change
View audit log
Login
Logout
Password change
Firmware reset
Audit overflow
Violation remote
Violation local
Description
Configuration files changed
Firmware changed
Firmware change failed
Unit has been attached to retrofit case
Removed from retrofit test case
User changed setting group remotely
User changed setting group locally
DPC object control remote
DPC object control local
Test mode on
Test mode off
Reset latched trips (TRPPTRC*)
Settings have been changed
Time changed directly by the user. Note that this is not used when the protection relay is synchronised properly by the appropriate protocol (SNTP, IRIG-B, IEEE 1588 v2).
Administrator accessed audit trail
Successful login from IEC 61850-8-1 (MMS), WHMI, FTP or
LHMI.
Successful logout from IEC 61850-8-1 (MMS), WHMI, FTP or
LHMI.
Password changed
Reset issued by user or tool
Too many audit events in the time period
Unsuccessful login attempt from IEC 61850-8-1 (MMS),
WHMI, FTP or LHMI.
Unsuccessful login attempt from IEC 61850-8-1 (MMS),
WHMI, FTP or LHMI.
PCM600 Event Viewer can be used to view the audit trail events and process related events. Audit trail events are visible through dedicated Security events view. Since only the administrator has the right to read audit trail, authorization must be used in
PCM600. The audit trail cannot be reset, but PCM600 Event Viewer can filter data.
Audit trail events can be configured to be visible also in LHMI/WHMI Event list together with process related events.
To expose the audit trail events through Event list, define the
Authority logging level parameter via Configuration/
Authorization/Security . This exposes audit trail events to all users.
18 REU611
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2.7
REU611
Application Manual
Section 2
REU611 overview
Table 8:
Audit trail event
Configuration change
Firmware change
Firmware change fail
Attached to retrofit test case
Removed from retrofit test case
Setting group remote
Setting group local
Control remote
Control local
Test on
Test off
Reset trips
Setting commit
Time change
View audit log
Login
Logout
Password change
Firmware reset
Violation local
Violation remote
Comparison of authority logging levels
None
Configurati on change
●
●
●
●
Authority logging level
Setting group
Setting group, control
●
●
●
●
●
●
●
●
● ●
●
●
●
●
●
●
●
●
●
●
Settings edit
●
●
●
●
●
●
●
●
●
●
●
●
●
All
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
●
Communication
The protection relay supports a range of communication protocols including IEC
61850 and Modbus ® . Operational information and controls are available through these protocols. However, some communication functionality, for example, horizontal communication between the protection relays, is only enabled by the IEC
61850 communication protocol.
The IEC 61850 communication implementation supports all monitoring and control functions. Additionally, parameter settings, disturbance recordings and fault records can be accessed using the IEC 61850 protocol. Disturbance recordings are available to any Ethernet-based application in the IEC 60255-24 standard COMTRADE file format. The protection relay can send and receive binary signals from other devices
(so-called horizontal communication) using the IEC 61850-8-1 GOOSE profile,
19
Section 2
REU611 overview
2.7.1
1MRS758335 D where the highest performance class with a total transmission time of 3 ms is supported. The protection relay meets the GOOSE performance requirements for tripping applications in distribution substations, as defined by the IEC 61850 standard.
The protection relay can support five simultaneous clients. If PCM600 reserves one client connection, only four client connections are left, for example, for IEC 61850 and Modbus.
All communication connectors, except for the front port connector, are placed on integrated optional communication modules. The protection relay can be connected to
Ethernet-based communication systems via the RJ-45 connector (100Base-TX) or the fiber-optic LC connector (100Base-FX). An optional serial interface is available for
RS-485 communication.
Self-healing Ethernet ring
For the correct operation of self-healing loop topology, it is essential that the external switches in the network support the RSTP protocol and that it is enabled in the switches. Otherwise, connecting the loop topology can cause problems to the network. The protection relay itself does not support link-down detection or RSTP.
The ring recovery process is based on the aging of the MAC addresses, and the linkup/link-down events can cause temporary breaks in communication. For a better performance of the self-healing loop, it is recommended that the external switch furthest from the protection relay loop is assigned as the root switch (bridge priority
= 0) and the bridge priority increases towards the protection relay loop. The end links of the protection relay loop can be attached to the same external switch or to two adjacent external switches. A self-healing Ethernet ring requires a communication module with at least two Ethernet interfaces for all protection relays.
20 REU611
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Client A
Manag ed Eth ernet switch with RSTP su pport
Section 2
REU611 overview
Client B
Manag ed Eth ernet switch with RSTP su pport
Network
Network
2.7.2
REU611
Application Manual
GUID-A19C6CFB-EEFD-4FB2-9671-E4C4137550A1 V2 EN
Figure 6: Self-healing Ethernet ring solution
The Ethernet ring solution supports the connection of up to 30 protection relays. If more than 30 protection relays are to be connected, it is recommended that the network is split into several rings with no more than 30 protection relays per ring. Each protection relay has a 50-μs store-and-forward delay, and to fulfil the performance requirements for fast horizontal communication, the ring size is limited to 30 protection relays.
Ethernet redundancy
IEC 61850 specifies a network redundancy scheme that improves the system availability for substation communication. It is based on two complementary protocols defined in the IEC 62439-3:2012 standard: parallel redundancy protocol
PRP and high-availability seamless redundancy HSR protocol. Both protocols rely on the duplication of all transmitted information via two Ethernet ports for one logical network connection. Therefore, both are able to overcome the failure of a link or switch with a zero-switchover time, thus fulfilling the stringent real-time requirements for the substation automation horizontal communication and time synchronization.
PRP specifies that each device is connected in parallel to two local area networks.
HSR applies the PRP principle to rings and to the rings of rings to achieve costeffective redundancy. Thus, each device incorporates a switch element that forwards frames from port to port. The HSR/PRP option is available for all 611 series protection relays.
21
Section 2
REU611 overview
1MRS758335 D
IEC 62439-3:2012 cancels and replaces the first edition published in
2010. These standard versions are also referred to as IEC 62439-3
Edition 1 and IEC 62439-3 Edition 2. The protection relay supports
IEC 62439-3:2012 and it is not compatible with IEC 62439-3:2010.
PRP
Each PRP node, called a double attached node with PRP (DAN), is attached to two independent LANs operated in parallel. These parallel networks in PRP are called
LAN A and LAN B. The networks are completely separated to ensure failure independence, and they can have different topologies. Both networks operate in parallel, thus providing zero-time recovery and continuous checking of redundancy to avoid communication failures. Non-PRP nodes, called single attached nodes (SANs), are either attached to one network only (and can therefore communicate only with
DANs and SANs attached to the same network), or are attached through a redundancy box, a device that behaves like a DAN.
Managed
Ethernet switch
IEC 61850 PRP
Managed
Ethernet switch
22
GUID-AA005F1B-A30B-48F6-84F4-A108F58615A2 V1 EN
Figure 7: PRP solution
In case a laptop or a PC workstation is connected as a non-PRP node to one of the PRP networks, LAN A or LAN B, it is recommended to use a redundancy box device or an
Ethernet switch with similar functionality between the PRP network and SAN to remove additional PRP information from the Ethernet frames. In some cases, default
PC workstation adapters are not able to handle the maximum-length Ethernet frames with the PRP trailer.
There are different alternative ways to connect a laptop or a workstation as SAN to a
PRP network.
REU611
Application Manual
1MRS758335 D
Section 2
REU611 overview
• Via an external redundancy box (RedBox) or a switch capable of connecting to
PRP and normal networks
• By connecting the node directly to LAN A or LAN B as SAN
• By connecting the node to the protection relay's interlink port
HSR
HSR applies the PRP principle of parallel operation to a single ring, treating the two directions as two virtual LANs. For each frame sent, a node, DAN, sends two frames, one over each port. Both frames circulate in opposite directions over the ring and each node forwards the frames it receives, from one port to the other. When the originating node receives a frame sent to itself, it discards that to avoid loops; therefore, no ring protocol is needed. Individually attached nodes, SANs, such as laptops and printers, must be attached through a “redundancy box” that acts as a ring element. For example, a 615 or 620 series protection relay with HSR support can be used as a redundancy box.
Devices not supporting HSR
Ethernet switch
Redundancy box
Redundancy box
Redundancy box
X
X
IEC 61850 HSR
X
Unicast traffic
Message is recognized as a duplicat e and is immediately forwarded
Sending device removes the message from t he ri ng
2.7.3
REU611
Application Manual
GUID-B24F8609-0E74-4318-8168-A6E7FCD0B313 V1 EN
Figure 8: HSR solution
Secure communication
The protection relay supports secure communication for WHMI and file transfer protocol. If the Secure Communication parameter is activated, protocols require TLS based encryption method support from the clients. In this case WHMI must be connected from a Web browser using the HTTPS protocol and in case of file transfer the client must use FTPS.
As a factory default, Secure Communication is “ON”.
23
24
1MRS758335 D
Section 3
REU611 standardized configuration
Section 3 REU611 standardized configuration
3.1
REU611
Application Manual
Standardized configuration
REU611 is available in one configuration.
To increase the user-friendliness of the configuration and to emphasize the simplicity of usage of the relay, only the application-specific parameters need setting within the relay's intended area of application.
The standard signal configuration can be altered by local HMI, Web HMI or optional application functionality of Protection and Control IED Manager PCM600.
Table 9: Standardized configuration
Description
Voltage and frequency protection
Conf.
A
Table 10: Supported functions
Function
Protection
Residual overvoltage protection
Three-phase undervoltage protection
Three-phase overvoltage protection
Positive-sequence undervoltage protection
Negative-sequence overvoltage protection
Frequency protection
Master trip
Control
Circuit-breaker control
Condition monitoring and supervision
Trip circuit supervision
Logging
Disturbance recorder
Fault recorder
Measurement
Three-phase voltage measurement
Sequence voltage measurement
Residual voltage measurement
Table continues on next page
IEC 61850
ROVPTOV
PHPTUV
PHPTOV
PSPTUV
NSPTOV
FRPFRQ
TRPPTRC
CBXCBR
TCSSCBR
RDRE
FLTRFRC
VMMXU
VSMSQI
RESVMMXU
A
3
2
2
2
2
3
3
2
1
1
1
1
1
2
25
Section 3
REU611 standardized configuration
3.2
3.2.1
1MRS758335 D
Function
Frequency measurement
Other
Input switch group
Output switch group
Selector
Minimum pulse timer (2 pcs)
IEC 61850
FMMXU
ISWGAPC
OSWGAPC
SELGAPC
TPGAPC
A
1
10
20
6
10
Move (8 pcs) MVGAPC 1
1, 2, ... = Number of included instances. The instances of a protection function represent the number of identical protection function blocks available in the standardized configuration.
() = optional
Switch groups
The default application configurations cover the most common application cases, however, changes can be made according to specific needs through LHMI, WHMI and PCM600.
Programming is easily implemented with three switch group functions including input switch group ISWGAPC, output switch group OSWGAPC and selector switch group
SELGAPC. Each switch group has several instances.
Connections of binary inputs to functions, GOOSE signals to functions, functions to functions, functions to binary outputs and functions to LEDs have been preconnected through corresponding switch groups.
The real connection logic and the application configuration can be modified by changing the parameter values of the switch groups. It is also possible to modify the real connection logic and the application configuration through the matrix view in the signal configuration menu in the WHMI.
Input switch group ISWGAPC
The input switch group ISWGAPC has one input and a number of outputs. Every input and output has a read-only description. ISWGAPC is used for connecting the input signal to one or several outputs of the switch group. Each output can be set to be connected or not connected with the input separately via the “OUT_x connection” setting.
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Section 3
REU611 standardized configuration
3.2.2
GUID-2D549B56-6CF7-4DCB-ACDE-E9EF601868A8 V1 EN
Figure 9: Input switch group ISWGAPC
Output switch group OSWGAPC
The output switch group OSWGAPC has a number of inputs and one output. Every input and output has a read-only description. OSWGAPC is used for connecting one or several inputs to the output of the switch group via OR logic. Each input can be set to be connected or not connected with the OR logic via the “IN_x connection” settings. The output of OR logic is routed to switch group output.
3.2.3
GUID-1EFA82D5-F9E7-4322-87C2-CDADD29823BD V1 EN
Figure 10: Output switch group OSWGAPC
Selector switch group SELGAPC
The selector switch group SELGAPC has a number of inputs and outputs. Every input and output has a read-only description. Each output can be set to be connected with one of the inputs via the OUT_x connection setting. An output can also be set to be not connected with any of the inputs. In SELGAPC, one output signal can only be connected to one input signal but the same input signal can be routed to several output signals.
REU611
Application Manual
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Section 3
REU611 standardized configuration
1MRS758335 D
GUID-E3AEC7AB-2978-402D-8A80-C5DE9FED67DF V1 EN
Figure 11: Selector switch group SELGAPC
28 REU611
Application Manual
1MRS758335 D
3.3
L1
L2
L3
Connection diagrams
Section 3
REU611 standardized configuration
A N n a n a
A
N da dn
X130
1
2
5
6
3
4
7
8
14
15
16
17
18
9
10
11
12
13
60 -
210V
N
60 -
210V
N
60 -
210V
N
60 -
210V
N
60 -
210V
N
BI 1
BI 2
BI 3
BI 4
U12B
U1
U2
U3
Uo
REU611
PO3
TCS1
PO4
TCS2
SO1
SO2
IRF
PO1
PO2
+
U aux
-
X100
1
2
3
4
5
6
7
14
16
17
15
19
18
20
22
21
23
24
8
9
10
11
12
13
REU611
Application Manual
GUID-45AA211F-CF77-4974-BBF6-4FC34B46EF3B V1 EN
Figure 12: Connection diagram for configuration A (voltage protection with phase-to-phase voltage measurement)
29
Section 3
REU611 standardized configuration
L1
L2
L3
1MRS758335 D
A N n a n a
A
N da dn
X130
1
2
5
6
3
4
7
8
13
14
15
16
9
10
11
12
17
18
60 -
210V
N
60 -
210V
N
60 -
210V
N
60 -
210V
N
60 -
210V
N
BI 1
BI 2
BI 3
BI 4
U2
U3
U12B
U1
Uo
REU611
30
GUID-90BD624C-28F1-4B93-8A2B-708E480A07A8 V1 EN
Figure 13: Connection diagram for configuration A (voltage protection with phase-to-earth voltage measurement)
REU611
Application Manual
1MRS758335 D
3.4
3.4.1
Section 3
REU611 standardized configuration
Configuration A
Applications
Configuration A for voltage and frequency-based protection is mainly intended for utility and industrial power systems and distribution systems including networks with distributed power generation. The configuration handles fault conditions originating from abnormal voltages in the power system.
The protection relay with a standardized configuration is delivered from the factory with default settings and parameters. The end-user flexibility for incoming, outgoing and internal signal designation within the protection relay enables this configuration to be further adapted to different primary circuit layouts and the related functionality needs by modifying the internal functionality using PCM600.
REU611
Application Manual
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Section 3
REU611 standardized configuration
3.4.2 Functions
1MRS758335 D
Uo
U
L1
U
L2
U
L3
U
12
REU611 VOLTAGE PROTECTION RELAY
PROTECTION
2×
Master Trip
Lockout relay
94/86
3×
3U<
27
2×
U2>
47O-
2×
U1<
47U+
3×
3U>
59
3×
Uo>
59G
2× f>/f<, df/dt
81
GUID-188F04CC-D6B0-4AB5-BDAB-BE4B993A605C V1 EN
Figure 14: Functionality overview for configuration A
3.4.2.1 Default I/O connections
Table 11:
Binary input
X130-BI1
X130-BI2
X130-BI3
X130-BI4
Default connections for binary inputs
Description
Blocking of overvoltage protection
Circuit breaker closed position indication
Circuit breaker open position indication
Bus voltage transformer MCB open
LOCAL HMI
I
ESC
O
Control
Events
Measurements
Disturbance records
A
R
L
STANDARD
CONFIGURATION
A
ALSO AVAILABLE
- Disturbance and fault recorders
- Event log and recorded data
- Local/Remote push button on LHMI
- Self-supervision
- Time synchronization: IEEE 1588 v2,
SNTP, IRIG-B
- User management
- Web-HMI
CONDITION MONITORING
AND SUPERVISION
2×
TCS
TCM
COMMUNICATION
Protocols:
IEC 61850-8-1
Modbus®
Interfaces:
Ethernet: TX (RJ-45), FX (LC)
Serial: RS-485
Redundant protocols:
HSR
PRP
RSTP
CONTROL AND INDICATION 1)
Object
CB
Ctrl 2)
1
Ind 3)
-
DC -
ES -
1) Check availability of binary inputs/outputs
from technical documentation
2) Control and indication function for
primary object
3) Status indication function for
primary object
MEASUREMENT
- U, Uo, f
- Limit value supervision
- Symmetrical components
Analog interface types
Current transformer
Voltage transformer
1)
Conventional transformer inputs
REMARKS
Optional function
3× No. of instances
Io/Uo
Calculated value
OR Alternative function to be defined when ordering
1)
-
5
Connector pins
X130:1-2
X130:3-4
X130:5-6
X130:7-8
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Application Manual
1MRS758335 D
3.4.2.2
3.4.3
REU611
Application Manual
Section 3
REU611 standardized configuration
Table 12:
Binary input
X100-PO1
X100-PO2
X100-SO1
X100-SO2
X100-PO3
X100-PO4
Default connections for binary outputs
Description
Close circuit breaker
General start indication
Overvoltage operate indication
Undervoltage operate indication
Open circuit breaker/trip coil 1
Open trip coil 2
Table 13:
6
7
8
3
4
5
LED
1
2
Default connections for LEDs
Description
Overvoltage protection operated
Undervoltage protection operated
Residual voltage protection operated
Sequence protection operated
Frequency protection operated
Disturbance recorder triggered
Trip circuit supervision alarm
Bus VT MCB failure
Predefined disturbance recorder connections
Table 14:
3
4
5
Channel
1
2
Predefined analog channel setup
Description
Uo
U1
U2
U3
U1B
Connector pins
X100:6-7
X100:8-9
X100:10-12
X100:13-14
X100:15-19
X100:20-24
Additionally, all the digital inputs that are connected by default are also enabled with the setting. Default triggering settings are selected depending on the connected input signal type. Typically all protection START signals are selected to trigger the disturbance recorded by default.
Functional diagrams
The functional diagrams describe the default input, output, programmable LED, switch group and function-to-function connections. The default connections can be viewed and changed with switch groups in PCM600, LHMI and WHMI according to the application requirements.
33
Section 3
REU611 standardized configuration
3.4.3.1
1MRS758335 D
The analog channels have fixed connections towards the different function blocks inside the protection relay’s configuration. Exceptions to this rule are the 12 analog channels available for the disturbance recorder function. These channels are freely selectable and a part of the disturbance recorder’s parameter settings.
The line and bus voltages to the protection relay are fed from voltage transformer. The residual voltage to the protection relay is fed from either residual connected VTs, an open delta connected VT or internally calculated.
Functional diagrams for protection
The functional diagrams describe the protection functionality of the protection relay in detail and picture the factory default connections.
OVERVOLTAGE PROTECTION INDICATION
3U
BLOCK
PHPTOV1
3U>(1)
59(1)
OPERATE
START
3U
BLOCK
PHPTOV2
3U>(2)
59(2)
OPERATE
START
IN_1
IN_2
OSWGAPC7
IN_3
OR
OUT
SELGAPC4
IN_8 OUT_1
3U
BLOCK
PHPTOV3
3U>(3)
59(3)
OPERATE
START
LED 1
GUID-A6031EA6-2B8B-41D9-BCA8-5EB5446B9594 V1 EN
Figure 15: Overvoltage protection
Three overvoltage protection stages PHPTOV1...3 offer protection against overvoltage conditions. All operate signals are connected to the master trip and to alarm LED 1.
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Section 3
REU611 standardized configuration
UNDERVOLTAGE PROTECTION INDICATION
3U
BLOCK
PHPTUV1
3U<(1)
27(1)
OPERATE
START
3U
BLOCK
PHPTUV2
3U<(2)
27(2)
OPERATE
START
IN_4
IN_5
OSWGAPC8
IN_6
OR
OUT
SELGAPC4
IN_9 OUT_2
3U
BLOCK
PHPTUV3
3U<(3)
27(3)
OPERATE
START
LED 2
GUID-0E0A1B18-45A8-4FDB-BCFB-9FFC175CD53B V1 EN
Figure 16: Undervoltage protection
Three undervoltage protection stages PHPTUV1...3 offer protection against undervoltage conditions. All operate signals are connected to the master trip and to alarm LED 2.
REU611
Application Manual
35
Section 3
REU611 standardized configuration
1MRS758335 D
U
0
BLOCK
ROVPTOV1
U
0
>(1)
59G(1)
OPERATE
START
RESIDUAL OVERVOLTAGE PROTECTION
U
0
BLOCK
ROVPTOV2
U
0
>(2)
59G(2)
OPERATE
START
IN_7
IN_8
IN_9
OSWGAPC9
OR
OUT
SELGAPC4
IN_10 OUT_3
LED 3
U
0
BLOCK
ROVPTOV3
U
0
>(3)
59G(3)
OPERATE
START
GUID-77BDA0D6-968E-4EF0-84E0-ED91580217A7 V1 EN
Figure 17: Residual overvoltage protection
The residual overvoltage protection ROVPTOV provides earth-fault protection by detecting abnormal level of residual voltage. It can be used, for example, as a nonselective backup protection for the selective directional earth-fault functionality.
All operate signals of these residual overvoltage protections are connected to the master trip and to alarm LED 3.
36 REU611
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Section 3
REU611 standardized configuration
POSITIVE AND NEGATIVE SEQUENCE PROTECTION INDICATION
3I
BLOCK
PSPTUV1
U1<(1)
47U+(1)
OPERATE
START
3I
BLOCK
PSPTUV2
U1<(2)
47U+(2)
OPERATE
START
OSWGAPC10
IN_12
IN_13
IN_14
IN_15
OR
OUT
SELGAPC4
IN_11 OUT_4
3I
BLOCK
NSPTOV1
U2>(1)
47O-(1)
OPERATE
START
LED 4
3I
BLOCK
NSPTOV2
U2>(2)
47O-(2)
OPERATE
START
GUID-1D8D400A-3ED1-4C24-BE3D-A93EB046013D V1 EN
Figure 18: Unbalance protection
Four unbalance voltage protection functions are available, two stages of positivesequence undervoltage protection PSPTUV and two stages of negative-sequence overvoltage protection NSPTOV.
The operate signals of these unbalance voltage protections are connected to the master trip and to alarm LED 4.
REU611
Application Manual
37
Section 3
REU611 standardized configuration
1MRS758335 D
FREQUENCY PROTECTION INDICATION
3U
BLOCK
FRPFRQ1 f>/f<,df/dt (1)
81(1)
OPERATE
START
OSWGAPC16
IN_12 OUT
OR
SELGAPC4
IN_17 OUT_5
3U
BLOCK
FRPFRQ2 f>/f<,df/dt (2)
81(2)
OPERATE
START
LED 5
GUID-8E6B38BF-E8C6-4346-9EA4-F6A3DB231343 V1 EN
Figure 19: Frequency protection
The selectable underfrequency or overfrequency protection FRPFRQ prevents damage to network components under unwanted frequency conditions. The function also contains a selectable rate of change of the frequency (gradient) protection to detect an increase or decrease in the rapid changing power system frequency at an early stage. This can be used as an early indication of a disturbance in the system.
The operate signals of these frequency protections are connected to the master trip and to alarm LED 5.
38 REU611
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3.4.3.2
REU611
Application Manual
Section 3
REU611 standardized configuration
Functional diagrams for disturbance recorder and trip circuit supervision
PHPTOV1_OPERATE
PHPTO V2_OPERATE
PHPTO V3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
NSPTOV1_OPERATE
NSPTO V2_OPERATE
OR
OR
OR
OR
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
OR
PHPTOV1_START
PHPTOV2_START
PHPTO V3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
PSPTUV1_START
PSPTUV2_START
NSPTOV1_START
NSPTOV2_START
ROVPTOV1_START
ROVPTOV2_START
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
SEL1_Blocking 1
SEL1_CB Closed
SEL1_CB_Open
SEL1_External_Trip
SG_1_ACT
SG_2_ACT
SG_3_ACT
SG_4_ACT
SG_5_ACT
SG_6_ACT
BUS_VT_MCB_OPEN
DISTURBANCE RECORDER
RDRE1
C22
C23
C24
C25
C26
C27
C28
C29
C30
C31
C15
C16
C17
C18
C19
C20
C21
C8
C9
C10
C11
C12
C13
C14
C1
C2
C3
C4
C5
C6
C7
TRIGGERED
OSWGAPC11
IN_1 OUT
SELGAPC4
IN_12 OUT_6
LED 6
GUID-E2B78222-723F-42A9-9F6C-1AE1E3BCDF9F V1 EN
Figure 20: Disturbance recorder
All start and operate signals from the protection stages are routed to trigger the disturbance recorder or alternatively only to be recorded by the disturbance recorder depending on the parameter settings. The active setting group is also to be recorded via
SG_1_ACT to SG_6_ACT. The disturbance recorder triggered signal indication is connected to LED 6.
Table 15: Disturbance recorder binary channel default value
Channel number
Binary channel 1
Binary channel 2
Binary channel 3
Binary channel 4
Binary channel 5
Binary channel 6
Binary channel 7
Channel ID text
PHPTOV1_START
PHPTOV2_START
PHPTOV3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
PSPTUV1_START
Binary channel 8
Binary channel 9
Binary channel 10
PSPTUV2_START
NSPTOV1_START
NSPTOV2_START
Binary channel 11
Binary channel 12
Table continues on next page
ROVPTOV1_START
ROVPTOV2_START
Level trigger mode
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
39
Section 3
REU611 standardized configuration
Channel number
Binary channel 13
Binary channel 14
Binary channel 15
Binary channel 16
Binary channel 17
Binary channel 18
Binary channel 19
Binary channel 20
Binary channel 21
Binary channel 22
Binary channel 23
Binary channel 24
Binary channel 25
Binary channel 26
Binary channel 27
Binary channel 28
Binary channel 29
Binary channel 30
Binary channel 31
Channel ID text
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
PHPTOV_OPERATE
PHPTUV_OPERATE
ROVPTOV_OPERATE
PSPTUV/NSPTOV_OPERATE
FRPFRQ_OPERATE
SELGAPC1_Blocking 1
SELGAPC1_CB_Closed
SELGAPC1_CB_Open
SELGAPC1_External Trip
SG_1_ACT
SG_2_ACT
SG_3_ACT
SG_4_ACT
SG_5_ACT
SG_6_ACT
BUS_VT_MCB_OPEN
1MRS758335 D
Level trigger mode
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
1=positive or rising
TRIP CIRCUIT SUPERVISION
X120-BI3
CB Open Position
IN_3
SELGAPC1
OUT_3
TRPPTRC1_TRIP
TRPPTRC2_TRIP
OR
IN_2
SELGAPC2
OUT_1
OUT_2
BLOCK
TCSSCBR1
ALARM
BLOCK
TCSSCBR2
ALARM
IN_2
IN_3
OSWGAPC12
OR
OUT
SELGAPC4
IN_13 OUT_7
LED 7
GUID-EC303A9E-DD21-4501-A0C9-82EBC49AA114 V1 EN
Figure 21: Trip circuit supervision
Two separate trip circuit supervision functions are included, TCSSCBR1 for PO3
(X100:15-19) and TCSSCBR2 for PO4 (X100:20-24). Both functions are blocked by the master trip (TRPPTRC1 and TRPPTRC2) and the circuit breaker open position.
The TCS alarm indication is connected to LED 7.
40 REU611
Application Manual
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3.4.3.3
REU611
Application Manual
Section 3
REU611 standardized configuration
Functional diagrams for control
MASTER TRIP #1
PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPETATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERTAE
FRPFRQ1_OPERTAE
FRPFRQ2_OPERTAE
NSPTOV1_OPERATE
NSPTOV2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
IN_1
IN_2
IN_3
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
OSWGAPC1
OR
OUT
OR
TRPPTRC1
BLOCK TRIP
OPERATE CL_LKOUT
RST_LKOUT
OR
SELGAPC3
IN_1 OUT_5
X100 PO3
SELGAPC1_External Trip
GOOSERCV_BIN 2_OUT
OR
GOOSERCV_BIN 3_OUT
BUS_VT_MCB_OPEN
IN1
IN2
IN3
MVGAPC1
Q1
Q2
Q3
SELGAPC1_RST_LKOUT
CBXCBR1_EXE_OP
MASTER TRIP #2
PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPETATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERTAE
FRPFRQ1_OPERTAE
FRPFRQ2_OPERTAE
NSPTOV1_OPERATE
NSPTOV2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
IN_1
IN_2
IN_3
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
OSWGAPC2
OR
OUT
OR
TRPPTRC2
BLOCK TRIP
OPERATE CL_LKOUT
RST_LKOUT
SELGAPC3
IN_2 OUT_6
X100 PO4
SELGAPC1_External Trip
GOOSERCV_BIN 2_OUT
OR
GOOSERCV_BIN 3_OUT
BUS_VT_MCB_OPEN
IN1
IN2
IN3
MVGAPC1
Q1
Q2
Q3
SELGAPC1_RST_LKOUT
GUID-FBD41DB4-5D20-46F7-9D09-04318A7EE553 V3 EN
Figure 22: Master trip
The operate signals from the protections and an external trip are connected to the two trip output contacts PO3 (X100:15-19) and PO4 (X100:20-24) via the corresponding master trips TRPPTRC1 and TRPPTRC2. Open control commands to the circuit
41
Section 3
REU611 standardized configuration
1MRS758335 D breaker from local or remote CBXCBR1_EXE_OP is connected directly to the output contact PO3 (X100:15-19).
TRPPTRC1 and TRPPTRC2 provide the lockout/latching function, event generation and the trip signal duration setting. One binary input through SELGAPC1 can be connected to the RST_LKOUT input of the master trip. If the lockout operation mode is selected, it is used to enable external reset.
CIRCUIT BREAKER CONTROL
X120-BI2
CB Closed Position
X120-BI3
CB Open Position
Always True
IN_2
SELGAPC1
OUT_2
IN_3
IN_5
OUT_3
OUT_5
TRPPTRC1_TRIP
TRPPTRC2_TRIP
AND
POSOPEN
POSCLOSE
ENA_OPEN
ENA_CLOSE
BLK_OPEN
BLK_CLOSE
AU_OPEN
AU_CLOSE
TRIP
SYNC_OK
SYNC_ITL_BYP
CBXCBR1
SELECTED
EXE_OP
EXE_CL
OP_REQ
CL_REQ
OPENPOS
CLOSEPOS
OKPOS
OPEN_ENAD
CLOSE_ENAD
CBXCBR1_EXE_OP
IN_3
SELGAPC3
OUT_1
X100 PO1
GUID-798F8D1E-A9AA-47A1-8A27-EAB36E989637 V2 EN
Figure 23: Circuit breaker control
The ENA_CLOSE input, which enables the closing of the circuit breaker, is interlocked by two master trip signals. Any trip blocks the breaker from closing. An always true signal is also connected to ENA_CLOSE via SELGAPC1 by default. The open operation is always enabled.
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3.4.4
Section 3
REU611 standardized configuration
PHPTOV1_START
PHPTOV2_START
PHPTOV3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
ROVPTOV1_START
ROVPTOV2_START
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
NSPTOV1_START
NSPTOV2_START
PSPTUV1_START
PSPTUV2_START
COMMON ALARM INDICATION 1 & 2
IN_1
IN_2
IN_3
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
OSWGAPC3
OR
OUT IN1
TPGAPC1
OUT1
SELGAPC3
IN_4 OUT_2
IN_8 OUT_3
PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
IN_1
IN_2
IN_3
OSWGAPC7
OR
OUT
IN1
TPGAPC3
OUT1
X100 PO2
X100 SO1
GUID-ABBA0E88-9D42-4D61-A3E9-DC321BA760B4 V2 EN
Figure 24: Common alarm indication
The signal outputs from the protection relay are connected to give dedicated information.
• Start of any protection function PO2 (X100:8-9)
• Operation (trip) of overvoltage protection function SO1 (X100:10-12)
TPGAPC functions are timers and they are used for setting the minimum pulse length for the outputs. There are seven generic timers (TPGAPC1…7) available in the protection relay.
Switch groups
In configuration A, the switch group function blocks are organized in four groups: binary inputs, internal signal, GOOSE and binary outputs and LEDs.
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Section 3
REU611 standardized configuration
1MRS758335 D
Binary Inputs
(1..4)
SELGAPC1
Binary Inputs
ISWGAPC2
ISWGAPC1
Blocking
Protection and Control
ROVPTOV1 ROVPTOV2
ROVPTOV3
PHPTUV2
PHPTOV1
PHPTOV3
PSPTUV2
PHPTUV1
PHPTUV3
PHPTOV2
PSPTUV1
NSPTOV1
NSPTOV2
FRPFRQ2
TCSSCBR1
FRPFRQ1
CBXCBR1
TCSSCBR2
Binary Input s
Received GOOSE
(0...19)
GOOSE
GOOSE
GOOSE
GOOSE
ISWGAPC9
GOOSE Blocking
ISWGAPC10
GOOSE Block CB
Internal Signal
SELGAPC2
TCS Blocking
GUID-DD46D20E-10C3-4190-988E-DB2C8E1E906E V1 EN
Figure 25: Configuration A switch group overview
3.4.4.1
Binary Outputs and LEDs
OSWGAPC2
OSWGAPC1 SELGAPC3
SELGAPC4
Master trip
OSWGAPC6
OSWGAPC5
OSWGAPC4
OSWGAPC3
St art
OSWGAPC10
OSWGAPC9
OSWGAPC8
OSWGAPC7
Trip
OSWGAPC16
OSWGAPC15
OSWGAPC14
OSWGAPC13
OSWGAPC12
OSWGAPC11
LEDs
Binary Outputs
Alarm
Binary Outputs
(1...6)
LEDs
(1 …8)
Binary inputs
The binary inputs group includes one SELGAPC and two ISWGAPCs. SELGAPC1 is used to route binary inputs to ISWGAPC or directly to protection relay functions.
ISWGAPC1 and ISWGAPC2 are used to configure the signal to block the protection functions.
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Section 3
REU611 standardized configuration
X130-BI1
X130-BI2
X130-BI3
X130-BI4
SELGAPC1
Blocking 1
ISWGAPC1
PHPTO V1_BLOCK
PHPTO V2_BLOCK
PHPTOV3_BLOCK
PHPTUV1_BLOCK
PHPTUV2_BLOCK
PHPTUV3_BLOCK
ROVPTOV1_BLOCK
ROVPTOV2_BLOCK
ROVPTOV3_BLOCK
NSPTO V1_BLOCK
NSPTOV2_BLOCK
PSPTUV1_BLOCK
PSPTUV2_BLOCK
FRPFRQ1_BLOCK
FRPFRQ2_BLOCK
Blocking 2
ISWGAPC2
PHPTO V1_BLOCK
PHPTO V2_BLOCK
PHPTO V3_BLOCK
PHPTUV1_BLOCK
PHPTUV2_BLOCK
PHPTUV3_BLOCK
ROVPTOV1_BLOCK
ROVPTOV2_BLOCK
ROVPTOV3_BLOCK
NSPTO V1_BLOCK
NSPTO V2_BLOCK
PSPTUV1_BLOCK
PSPTUV2_BLOCK
FRPFRQ1_BLOCK
FRPFRQ2_BLOCK
GUID-061E1E21-E166-4597-99F7-4770E336775A V1 EN
Figure 26: Binary inputs
SELGAPC1
SELGAPC1 has inputs from protection relay binary inputs. IN_1 ...
IN_4 are binary inputs from X130. An always true signal is connected to IN_5 . SELGAPC1 outputs are used to route inputs to different functions. Binary inputs can be configured for different purposes by setting SELGAPC1.
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Section 3
REU611 standardized configuration
X130-BI1
X130-BI2
X130-BI3
X130-BI4
Always True
X130/1-2 BI1
IN_1
SELGAPC1
OUT_1
Blocking 1
X130/3-4 BI2
IN_2
X130/5-6 BI3
IN_3
X130/7-8 BI4
IN_4
IN_5
ISWGAPC1_IN
OUT_2
CB Closed Position
CBXCBR1_POSCLOSE
SELGAPC2_IN_1
OUT_3
OUT_4
CB Open Position CBXCBR1_POSOPEN
SELGAPC2_IN_2
TRPPTRC1/2_RST
_LKOUT
TRPTTRC1_RST_LKOUT
TRPTTRC2_RST_LKOUT
OUT_5 CB Close Enable
CBXCBR1_ENA_CLOSE
OUT_6
External Trip
TRPTTRC1_OPERATE
OUT_7 Setting Group 2
OUT_8
Setting Group 3
OUT_9
Setting Group 4
PROTECTION_BI_SG_2
PROTECTION_BI_SG_3
PROTECTION_BI_SG_4
OUT_10 Blocking 2
OUT_11
BUS_VT_MCB_
OPEN
ISWGAPC2_IN
BUS_VT_MCB_OPEN_ALARM
1MRS758335 D
GUID-80A08942-C2E5-48CB-94C3-2A803058F830 V2 EN
Figure 27: SELGAPC1
ISWGAPC1
ISWGAPC1 is used to select the protection functions to be blocked by changing the
ISWGAPC1 parameters. ISWGAPC1 input is routed from SELGAPC1 output
OUT_1 Blocking 1 . ISWGAPC1 outputs are connected to the BLOCK inputs of the protection functions.
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Section 3
REU611 standardized configuration
Blocking 1
IN
ISWGAPC1
OUT_1
OUT_2
OUT_3
OUT_4
OUT_5
OUT_6
OUT_7
OUT_8
OUT_9
OUT_10
OUT_11
OUT_12
OUT_13
OUT_14
OUT_15
PHPTOV1_BLOCK
PHPTOV2_BLOCK
PHPTOV3_BLOCK
PHPTUV1_BLOCK
PHPTUV2_BLOCK
PHPTUV3_BLOCK
ROVPTOV1_BLOCK
ROVPTOV2_BLOCK
ROVPTOV3_BLOCK
NSPTOV1_BLOCK
NSPTO V2_BLOCK
PSPTUV1_BLOCK
PSPTUV2_BLOCK
FRPFRQ1_BLOCK
FRPFRQ2_BLOCK
GUID-65F2F3B6-3D6D-4126-891E-9C7AD6122367 V1 EN
Figure 28: ISWGAPC1
ISWGAPC2
ISWGAPC2 is used to select the protection functions to be blocked by changing
ISWGAPC2 parameters. ISWGAPC2 input is routed from SELGAPC1 output
OUT_13 Blocking 2 . ISWGAPC2 outputs are connected to the BLOCK inputs of the protection functions.
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Section 3
REU611 standardized configuration
3.4.4.2
48
1MRS758335 D
Blocking 2
IN
ISWGAPC2
OUT_1
OUT_2
OUT_3
OUT_4
OUT_5
OUT_6
OUT_7
OUT_8
OUT_9
OUT_10
OUT_11
OUT_12
OUT_13
OUT_14
OUT_15
PHPTOV1_BLOCK
PHPTOV2_BLOCK
PHPTOV3_BLOCK
PHPTUV1_BLOCK
PHPTUV2_BLOCK
PHPTUV3_BLOCK
ROVPTOV1_BLOCK
ROVPTOV2_BLOCK
ROVPTOV3_BLOCK
NSPTOV1_BLOCK
NSPTO V2_BLOCK
PSPTUV1_BLOCK
PSPTUV2_BLOCK
FRPFRQ1_BLOCK
FRPFRQ2_BLOCK
GUID-21043993-1044-4B8B-81E5-BF45A21D79CB V1 EN
Figure 29: ISWGAPC2
Internal signal
The internal signal group is used to configure logic connections between function blocks. There is one SELGAPC in the group. SELGAPC2 is used to configure TCS blocking from the circuit breaker open or close position.
SELGAPC1_OUT_2
SELGAPC1_OUT_3
CB Closed Position
CB Open Posit ion
GUID-F60A5ABF-7569-44D7-B5E4-CC60F9F87D9E V1 EN
Figure 30: Internal signal
SELGAPC2
TCSSCBR1_BLOCK
TCSSCBR2_BLOCK
SELGAPC2
SELGAPC2 inputs represent the circuit breaker closed and open positions from
SELGACP1. SELGAPC2 outputs are routed to the BLOCK input of the trip circuit supervision TCSSCBR1 and TCSSCBR2.
By default, X100 PO3 and PO4 are both used for opening the circuit breaker.
TCSSCBR1 and TCSSCBR2 are both blocked by the circuit breaker open position. If
X100-PO3 is used for closing the circuit breaker, TCSSCBR1 needs to be blocked by circuit breaker close position ( OUT_1 connection= IN_1 ). If X100-PO4 is used for closing the circuit breaker, TCSSCBR2 needs to be blocked by the circuit breaker close position ( OUT_2 connection= IN_1 ).
REU611
Application Manual
1MRS758335 D
3.4.4.3
Section 3
REU611 standardized configuration
SELGAPC1_OUT_2
SELGAPC1_OUT_3
CB Closed Position
IN_1
SELGAPC2
OUT_1
CB Open Posit ion
IN_2 OUT_2
GUID-BC1E889E-D80E-4561-A70B-9986BFB374F7 V1 EN
Figure 31: SELGAPC2
TCSSCBR1_BLOCK
TCSSCBR2_BLOCK
Binary outputs and LEDs
In the standard configuration A, the signals are routed to binary outputs and LEDs are configured by OSWGAPCs. There are 16 OSWGAPC instances in total. They are categorized in four groups, which include two master trip, four start, four trip and six alarm signals. The OSWGAPC output is connected with binary outputs and LEDs via
SELGAPC3 and SELGAPC4.
• SELGAPC3 is used to configure OSWGAPC signals to the protection relay's binary outputs. SELGAPC4 is used to configure OSWGAPC signals to LEDs.
• OSWGAPC1 and OSWGAPC2 are used for the master trip. The inputs are routed from the protection function's operate and the circuit breaker failure's re-trip.
• OSWGAPC3 to OSWGAPC6 are used for the start signal. The inputs are start signals routed from the protection functions.
• OSWGAPC7 to OSWGAPC10 are used for the trip signal. The inputs are operation signals routed from the protection functions.
• OSWGAPC11 to OSWGAPC16 are used for the alarm signal. The inputs are alarm signals routed from the protection and monitoring functions.
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Section 3
REU611 standardized configuration
1MRS758335 D
PHPTO V1_OPERATE
PHPTO V2_OPERATE
PHPTO V3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
OSWGAPC1
Master Trip 1
TRPPTRC1
OSWGAPC2
Master Trip 2
TRPPTRC2
PHPTO V1_START
PHPTO V2_START
PHPTO V3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
ROVPTOV1_START
ROVPTOV2_START
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
NSPTO V1_START
NSPTO V2_START
PSPTUV1_START
PSPTUV2_START
OSWGAPC3
OSWGAPC4
OSWGAPC5
OSWGAPC6
St art 1
IN1
TPGAPC1
OUT1
St art 2 IN2 OUT2
St art 3
IN1
TPGAPC2
OUT1
St art 4
IN2
OUT2
PHPTO V1_OPERATE
PHPTO V2_OPERATE
PHPTO V3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
OSWGAPC7
OSWGAPC8
OSWGAPC9
OSWGAPC10
Trip 1
IN1
TPGAPC3
OUT1
Trip 2
IN2
Trip 3
OUT2
IN1
TPGAPC4
OUT1
Trip 4
IN2 OUT2
OSWGAPC11
Alarm 1
IN1
TPGAPC5
OUT1
RDRE_TRIGGERED
TCSSCBR1_ALARM
TCSSCBR2_ALARM
SELGAPC1_EXT_Trip
TRPPTRC1_CL_LKOUT
TRPPTRC2_CL_LKOUT
BUS_VT_MCB_OPEN
OVERVOLTAGE_OPERATE
UNDERVOLTAGE_OPERATE
RES_VO LTAGE_OPERATE
SEQ_VO LTAGE_OPERATE
FREQUENCY_OPERATE
OSWGAPC12
OSWGAPC13
Alarm 2
IN2 OUT2
Alarm 3
IN1
TPGAPC6
OUT1
OSWGAPC14
OSWGAPC15
Alarm 4
IN2 OUT2
Alarm 5 IN1
TPGAPC7
OUT1
OSWGAPC16
GUID-71FC5116-1DD0-48DF-A650-2100F982CBE4 V1 EN
Figure 32: Binary outputs
Alarm 6
IN2 OUT2
SELGAPC3
X100 PO1
X100 PO2
X100 SO1
X100 SO2
X100 PO3
X100 PO4
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REU611
Application Manual
Section 3
REU611 standardized configuration
PHPTO V1_OPERATE
PHPTOV2_OPERATE
PHPTO V3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
OSWGAPC1
Master Trip 1
TRPPTRC1
OSWGAPC2
Master Trip 2
TRPPTRC2
PHPTO V1_START
PHPTOV2_START
PHPTO V3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
ROVPTOV1_START
ROVPTOV2_START
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
NSPTO V1_START
NSPTOV2_START
PSPTUV1_START
PSPTUV2_START
PHPTO V1_OPERATE
PHPTO V2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
NSPTOV1_OPERATE
NSPTO V2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
OSWGAPC3
St art 1
OSWGAPC4
St art 2
OSWGAPC5
St art 3
OSWGAPC6
St art 4
OSWGAPC7
Trip 1
OSWGAPC8
Trip 2
OSWGAPC9
Trip 3
OSWGAPC10
Trip 4
SELGAPC4
RDRE_TRIGGERED
TCSSCBR1_ALARM
TCSSCBR2_ALARM
SELGAPC1_EXT_Trip
TRPPTRC1_CL_LKOUT
TRPPTRC2_CL_LKOUT
BUS_VT_MCB_OPEN
OVERVOLTAGE_OPERATE
UNDERVOLTAGE_OPERATE
RES_VO LTAGE_OPERATE
SEQ_VOLTAGE_OPERATE
FREQUENCY_OPERATE
OSWGAPC11
Alarm 1
OSWGAPC12
Alarm 2
OSWGAPC13
Alarm 3
OSWGAPC14
Alarm 4
OSWGAPC15
Alarm 5
OSWGAPC16
Alarm 6
GUID-079B9E25-2261-4E6C-AF7C-DD32B3D084AD V1 EN
Figure 33: LEDs
SELGAPC3
SELGAPC3 is used to configure the OSWGAPC outputs to the protection relay binary outputs. Master trip signals are connected to SELGAPC3 via TRPPTRC. Start, trip and alarm signals are connected to SELGAPC3 via TPGAPC. TPGAPC functions are timers and used for setting the minimum pulse length for the outputs. SELGAPC3 outputs are connected to X100 binary outputs.
LED5
LED6
LED7
LED8
LED1
LED2
LED3
LED4
51
Section 3
REU611 standardized configuration
1MRS758335 D
CBXCBR_EXE_OP
TRPPTRC1_TRIP
CB Open 1
IN_1
SELGAPC3
OUT_1
CB Open 2
IN_2 OUT_2
CB Close
IN_3
OUT_3
IN1 OUT1
TPGAPC1
IN2 OUT2
St art 1
St art 2
IN_4
IN_5
OUT_4
OUT_5
IN1 OUT1
TPGAPC2
IN2 OUT2
St art 3
St art 4
IN_6
IN_7
OUT_6
IN1 OUT1
TPGAPC3
IN2 OUT2
Trip 1
Trip 2
IN_8
IN_9
IN1 OUT1
TPGAPC4
IN2 OUT2
Trip 3
Trip 4
IN_10
IN_11
IN1 OUT1
TPGAPC5
IN2 OUT2
Alarm 1
Alarm 2
IN_12
IN_13
IN1 OUT1
TPGAPC6
IN2 OUT2
Alarm 3
Alarm 4
IN_14
IN_15
IN1 OUT1
TPGAPC7
IN2 OUT2
Alarm 5
Alarm 6
IN_16
IN_17
X100 PO1
X100 PO2
X100 SO1
X100 SO2
X100 PO3
X100 PO4
GUID-EE736EA4-3EF1-4581-BB5A-FE060E1483B9 V1 EN
Figure 34: SELGAPC3
SELGAPC4
SELGAPC4 is used to configure the OSWGAPC outputs to LEDs. Master trip signals are connected to SELGAPC4 via TRPPTRC. Start, trip and alarm signals are connected to SELGAPC4 directly. SELGAPC4 outputs are connected to programmable LEDs: LED1...LED8.
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Section 3
REU611 standardized configuration
CBXCBR_EXE_OP
TRPPTRC1_TRIP
CB O pen 1
IN_1
CB O pen 2
IN_2
CB Close
IN_3
St art 1
IN_4
St art 2
IN_5
St art 3
IN_6
St art 4
IN_7
Trip 1
IN_8
Trip 2
IN_9
Trip 3
IN_10
Trip 4
IN_11
Alarm 1
IN_12
Alarm 2
IN_13
SELGAPC4
OUT_1
OUT_2
OUT_3
OUT_4
OUT_5
OUT_6
OUT_7
OUT_8
Alarm 3
IN_14
Alarm 4
IN_15
Alarm 5
IN_16
Alarm 6
IN_17
LED1
LED2
LED3
LED4
LED5
LED6
LED7
LED8
GUID-80F9A51C-77DC-4BCF-BE66-EAAD07B014BB V1 EN
Figure 35: SELGAPC4
Master trip OSWGAPCs
OSWGAPC1 and OSWGAPC2 are used to route the protection function operate signals to master trip. OSWGAPC1 and OSWGAPC2 have the same inputs from the protection function's operate signals. The output is connected to TRPPTRC function.
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Section 3
REU611 standardized configuration
PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
IN_3
IN_4
OSWGAPC1
OUT
Master trip 1
TRPPTRC 1_OPERATE
GUID-3808B480-39FF-4E00-8340-BBD1497AF4E2 V1 EN
Figure 36: OSWGAPC1
1MRS758335 D
54 REU611
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Section 3
REU611 standardized configuration
PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
IN_3
IN_4
OSWGAPC2
OUT
Master trip 2
TRPPTRC 2_OPERATE
GUID-9D1302AD-C7CF-4081-83E4-CC1BB38775AE V1 EN
Figure 37: OSWGAPC2
Start OSWGAPCs
OSWGAPC instances 3...6 are used to configure the protection start signals. These four OSWGAPCs have the same inputs from the protection function start signals. The output is routed to SELGAPC3 via TPGAPC timer, and routed to SELGAPC4 directly.
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PHPTOV1_START
PHPTOV2_START
PHPTOV3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
ROVPTOV1_START
ROVPTOV2_START
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
NSPTO V1_START
NSPTO V2_START
PSPTUV1_START
PSPTUV2_START
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
IN_3
IN_4
OSWGAPC3
OUT
St art 1 TPGAPC1_IN1
SELGAPC4_IN_4
GUID-1CEEF190-B5CB-40C0-8D3B-B85233DB3BDF V1 EN
Figure 38: OSWGAPC3
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PHPTOV1_START
PHPTOV2_START
PHPTOV3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
ROVPTOV1_START
ROVPTOV2_START
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
NSPTO V1_START
NSPTO V2_START
PSPTUV1_START
PSPTUV2_START
GUID-BBEFEA55-AEDB-44D2-943B-C0151C9C7D3C V1 EN
Figure 39: OSWGAPC4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
IN_3
IN_4
OSWGAPC4
OUT
St art 2 TPGAPC1_IN2
SELGAPC4_IN_5
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PHPTOV1_START
PHPTOV2_START
PHPTOV3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
ROVPTOV1_START
ROVPTOV2_START
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
NSPTO V1_START
NSPTO V2_START
PSPTUV1_START
PSPTUV2_START
GUID-37731A72-0467-4010-8A5F-29834699000A V1 EN
Figure 40: OSWGAPC5
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
IN_3
IN_4
OSWGAPC5
OUT
St art 3 TPGAPC2_IN1
SELGAPC4_IN_6
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PHPTOV1_START
PHPTOV2_START
PHPTOV3_START
PHPTUV1_START
PHPTUV2_START
PHPTUV3_START
ROVPTOV1_START
ROVPTOV2_START
ROVPTOV3_START
FRPFRQ1_START
FRPFRQ2_START
NSPTO V1_START
NSPTO V2_START
PSPTUV1_START
PSPTUV2_START
IN_1
IN_2
IN_3
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
OSWGAPC6
OUT
St art 4
TPGAPC2_IN2
SELGAPC4_IN_7
GUID-21366E41-D912-47F4-8E79-0A1897838DE8 V1 EN
Figure 41: OSWGAPC6
Trip OSWGAPCs
OSWGAPC instances 7...10 are used to configure the protection operate signals which belong to the trip group. These four OSWGAPCs have same inputs from the operate signals of the protection functions. The output is routed to SELGAPC3 via
TPGAPC timer, and routed to SELGAPC4 directly.
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PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
IN_3
IN_4
OSWGAPC7
OUT
Trip 1 TPGAPC3_IN1
SELGAPC4_IN_8
GUID-4C59046E-A106-47B2-9278-872145522C9A V1 EN
Figure 42: OSWGAPC7
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PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
IN_3
IN_4
OSWGAPC8
OUT
Trip 2 TPGAPC3_IN2
SELGAPC4_IN_9
GUID-89D0D99C-9A90-4F63-9E25-251108BFA4B3 V1 EN
Figure 43: OSWGAPC8
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PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
IN_3
IN_4
OSWGAPC9
OUT
Trip 3
TPGAPC4_IN1
SELGAPC4_IN_10
GUID-689B84B6-25A0-4CB7-A374-ED2E73A41A91 V1 EN
Figure 44: OSWGAPC9
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REU611 standardized configuration
PHPTOV1_OPERATE
PHPTOV2_OPERATE
PHPTOV3_OPERATE
PHPTUV1_OPERATE
PHPTUV2_OPERATE
PHPTUV3_OPERATE
ROVPTOV1_OPERATE
ROVPTOV2_OPERATE
ROVPTOV3_OPERATE
FRPFRQ1_OPERATE
FRPFRQ2_OPERATE
PSPTUV1_OPERATE
PSPTUV2_OPERATE
NSPTO V1_OPERATE
NSPTO V2_OPERATE
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
IN_13
IN_14
IN_15
IN_1
IN_2
OSWGAPC10
IN_3
IN_4
OUT
Trip 4 TPGAPC4_IN2
SELGAPC4_IN_11
GUID-BA32398F-8C21-4566-9C0F-A7874307413C V1 EN
Figure 45: OSWGAPC10
Alarm OSWGAPCs
OSWGAPC instances 11...16 are used to configure the alarm signals which belong to the alarm group. These six OSWGAPCs have same inputs from the alarm signals. The output is routed to SELGAPC3 via TPGAPC timer, and routed to SELGAPC4 directly.
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1MRS758335 D
RDRE_TRIGGERED
TCSSCBR1_ALARM
IN_1
IN_2
TCSSCBR2_ALARM
SELGAPC1_OUT_6
TRPPTRC1_CL_LKOUT
TRPPTRC2_CL_LKOUT
BUS_VT_MCB_OPEN
OVERVOLTAGE_OPERATE
UNDERVOLTAGE_OPERATE
IN_3
Ext ernal Trip
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
OSWGAPC11
OUT
Alarm 1
TPGAPC5_IN1
SELGAPC4_IN_12
GUID-53D8F638-3D65-4A83-BD3A-CCCF5C4F9CFC V1 EN
Figure 46: OSWGAPC11
RDRE_TRIGGERED IN_1
IN_2 TCSSCBR1_ALARM
TCSSCBR2_ALARM
SELGAPC1_OUT_6
TRPPTRC1_CL_LKOUT
TRPPTRC2_CL_LKOUT
BUS_VT_MCB_OPEN
OVERVOLTAGE_OPERATE
UNDERVOLTAGE_OPERATE
IN_3
Ext ernal Trip
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
OSWGAPC12
OUT
Alarm 2
TPGAPC5_IN2
SELGAPC4_IN_13
GUID-D3C08406-962B-44DB-B830-B53093100311 V1 EN
Figure 47: OSWGAPC12
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RDRE_TRIGGERED
TCSSCBR1_ALARM
IN_1
IN_2
TCSSCBR2_ALARM
SELGAPC1_OUT_6
TRPPTRC1_CL_LKOUT
TRPPTRC2_CL_LKOUT
BUS_VT_MCB_OPEN
OVERVOLTAGE_OPERATE
UNDERVOLTAGE_OPERATE
IN_3
Ext ernal Trip
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
OSWGAPC13
OUT
Alarm 3 TPGAPC6_IN1
SELGAPC4_IN_14
GUID-150A454F-3B7B-4CE0-8295-B7F038A2D45B V1 EN
Figure 48: OSWGAPC13
RDRE_TRIGGERED IN_1
IN_2 TCSSCBR1_ALARM
TCSSCBR2_ALARM
SELGAPC1_OUT_6
TRPPTRC1_CL_LKOUT
TRPPTRC2_CL_LKOUT
BUS_VT_MCB_OPEN
OVERVOLTAGE_OPERATE
UNDERVOLTAGE_OPERATE
IN_3
Ext ernal Trip
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
OSWGAPC14
OUT
Alarm 4
TPGAPC6_IN2
SELGAPC4_IN_15
GUID-57BA3BF3-AEFD-4BEF-9B1E-DEE4C88F635B V1 EN
Figure 49: OSWGAPC14
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1MRS758335 D
RDRE_TRIGGERED
TCSSCBR1_ALARM
IN_1
IN_2
TCSSCBR2_ALARM
SELGAPC1_OUT_6
TRPPTRC1_CL_LKOUT
TRPPTRC2_CL_LKOUT
BUS_VT_MCB_OPEN
OVERVOLTAGE_OPERATE
UNDERVOLTAGE_OPERATE
IN_3
Ext ernal Trip
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
OSWGAPC15
OUT
Alarm 5
TPGAPC7_IN1
SELGAPC4_IN_16
GUID-945CCB97-C5D5-419E-8A17-E70CF2D1AB2D V1 EN
Figure 50: OSWGAPC15
RDRE_TRIGGERED IN_1
IN_2 TCSSCBR1_ALARM
TCSSCBR2_ALARM
SELGAPC1_OUT_6
TRPPTRC1_CL_LKOUT
TRPPTRC2_CL_LKOUT
BUS_VT_MCB_OPEN
OVERVOLTAGE_OPERATE
UNDERVOLTAGE_OPERATE
IN_3
Ext ernal Trip
IN_4
IN_5
IN_6
IN_7
IN_8
IN_9
IN_10
IN_11
IN_12
OSWGAPC16
OUT
Alarm 6 TPGAPC7_IN2
SELGAPC4_IN_17
GUID-34F936D2-922C-4805-8350-25028A79223D V1 EN
Figure 51: OSWGAPC16
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REU611 standardized configuration
GOOSE
There are 20 GOOSERCV_BIN functions in the configuration. Each
GOOSERVC_BIN function can be connected to one received binary GOOSE signal.
The signal connection can be configured in PCM600.
• GOOSERCV_BIN instances 0 and 1 are used for blocking protection functions.
Signals from these two GOOSERCV_BINs are connected to ISWGAPC9.
ISWGAPC9 is used to configure which protection function block is blocked.
• GOOSERCV_BIN instances 2 and 3 are used for tripping from GOOSE. Signals from these two GOOSERCV_BINs are connected to TRPPTRC1 and
TRPPTRC2 trip.
• GOOSERCV_BIN instances 4 to 19 are used for blocking circuit breaker operation. Signals from these 16 GOOSERCV_BINs are connected to
ISWGAPC10. ISWGAPC10 is used to configure the GOOSE input signal to block the circuit breaker open or close operation.
GOOSERCV_BIN:0
GOOSERCV_BIN:1
OR
GOOSE Blcoking
ISWGAPC9
PHPTOV1_BLOCK
PHPTOV2_BLOCK
PHPTO V3_BLOCK
PHPTUV1_BLOCK
PHPTUV2_BLOCK
PHPTUV3_BLOCK
ROVPTOV1_BLOCK
ROVPTOV2_BLOCK
ROVPTOV3_BLOCK
FRPFRQ1_BLOCK
FRPFRQ2_BLOCK
NSPTO V1_BLOCK
NSPTOV2_BLOCK
PSPTUV1_BLOCK
PSPTUV2_BLOCK
GOOSERCV_BIN:2
OR
GOOSE
Ext ernal Trip
GOOSERCV_BIN:3
GOOSERCV_BIN:4
GOOSERCV_BIN:5 OR
GOOSE Block CB
ISWGAPC10
CBXCBR1_BLK_CLOSE
CBXCBR1_BLK_OPEN
GOOSERCV_BIN:19
GUID-4388A3EC-3534-4618-A0CD-47147FD0591E V1 EN
Figure 52: GOOSE overview
ISWGAPC9
ISWGAPC9 is used to configure which protection functions can be blocked by the received GOOSE signals. ISWGAPC9 inputs are received GOOSE signals from
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Section 3
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1MRS758335 D
GOOSERCV_BIN:0 and GOOSERCV_BIN:1. The outputs are connected to block inputs of the protection functions.
ISWGAPC9
GOO SE Blocking
IN
OUT_7
OUT_8
OUT_9
OUT_10
OUT_11
OUT_12
OUT_13
OUT_14
OUT_15
OUT_1
OUT_2
OUT_3
OUT_4
OUT_5
OUT_6
PHPTOV1_BLOCK
PHPTOV2_BLOCK
PHPTO V3_BLOCK
PHPTUV1_BLOCK
PHPTUV2_BLOCK
PHPTUV3_BLOCK
ROVPTOV1_BLOCK
ROVPTOV2_BLOCK
ROVPTOV3_BLOCK
FRPFRQ1_BLOCK
FRPFRQ2_BLOCK
NSPTOV1_BLOCK
NSPTOV2_BLOCK
PSPTUV1_BLOCK
PSPTUV2_BLOCK
GUID-0FCCA7F3-9413-49E1-8DF9-A46703C2DBAF V1 EN
Figure 53: ISWGAPC9
ISWGAPC10
ISWGAPC10 is used to block the circuit breaker operation from the received GOOSE signals. ISWGAPC10 inputs are received GOOSE signals from GOOSERCV_BIN:
4 to GOOSERCV_BIN:19. The outputs are connected to block the circuit breaker's close and open operation.
GOOSE Block CB
IN
ISWGAPC10
OUT_1
OUT_2
GUID-7DC47FBA-D2C9-4696-B947-0A2C9F67C05E V1 EN
Figure 54: ISWGAPC10
CBXCBR1_BLK_CLOSE
CBXCBR1_BLK_OPEN
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Section 4
Protection relay's physical connections
Section 4 Protection relay's physical connections
4.1
4.1.1
4.1.1.1
4.1.1.2
4.1.2
Inputs
Energizing inputs
Phase voltage
Phase voltage inputs Table 16:
Terminal
X130:11-12
X130:13-14
X130:15-16
Description
U1
U2
U3
Table 17:
Terminal
X130:9-10
Reference voltage measurement
Description
U12B
Residual voltage
Residual voltage Table 18:
Terminal
X130:17-18
Description
Uo
Auxiliary supply voltage input
The auxiliary voltage of the protection relay is connected to terminals X100:1-2. At
DC supply, the positive lead is connected to terminal X100:1. The permitted auxiliary voltage range (AC/DC or DC) is marked on the top of the LHMI of the protection relay.
Auxiliary voltage supply Table 19:
Terminal
X100:1
X100:2
Description
+ Input
- Input
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Protection relay's physical connections
4.1.3
4.2
4.2.1
70
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Binary inputs
The binary inputs can be used, for example, to generate a blocking signal, to unlatch output contacts, to trigger the disturbance recorder or for remote control of protection relay settings.
Binary inputs of slot X130 are available with AIM0006 module.
Table 20:
Terminal
X130:1
X130:2
X130:3
X130:4
X130:5
X130:6
X130:7
X130:8
Binary input terminals X130:1-8 with AIM0006 module
Description
BI1, +
BI1, -
BI2, +
BI2, -
BI3, +
BI3, -
BI4, +
BI4, -
Outputs
Outputs for tripping and controlling
Output contacts PO1, PO2, PO3 and PO4 are heavy-duty trip contacts capable of controlling most circuit breakers. In the factory default configuration, the trip signals from all the protection stages are routed to PO3 and PO4.
Output contacts Table 21:
Terminal
X100:6
X100:7
X100:8
X100:9
X100:15
X100:16
X100:17
X100:18
X100:19
X100:20
X100:21
X100:22
X100:23
X100:24
Description
PO1, NO
PO1, NO
PO2, NO
PO2, NO
PO3, NO (TCS resistor)
PO3, NO
PO3, NO
PO3 (TCS1 input), NO
PO3 (TCS1 input), NO
PO4, NO (TCS resistor)
PO4, NO
PO4, NO
PO4 (TCS2 input), NO
PO4 (TCS2 input), NO
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4.2.2
4.2.3
Section 4
Protection relay's physical connections
Outputs for signalling
Output contacts SO1 and SO2 in slot X100 can be used for signalling on start and tripping of the protection relay. On delivery from the factory, the start and alarm signals from all the protection stages are routed to signalling outputs.
Output contacts X100:10...14
Table 22:
Terminal
X100:10
X100:11
X100:12
X100:13
X100:14
Description
SO1, common
SO1, NC
SO1, NO
SO2, NO
SO2, NO
IRF
The IRF contact functions as an output contact for the self-supervision system of the protection relay. Under normal operating conditions, the protection relay is energized and the contact is closed (X100:3-5). When a fault is detected by the self-supervision system or the auxiliary voltage is disconnected, the contact X100:3-5 drops off and the contact X100:3-4 closes.
IRF contact Table 23:
Terminal
X100:3
X100:4
X100:5
Description
IRF, common
Closed; IRF, or U aux
disconnected
Closed; no IRF, and U aux
connected
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Section 5 Glossary
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Section 5
Glossary
100BASE-FX A physical medium defined in the IEEE 802.3 Ethernet standard for local area networks (LANs) that uses fiber optic cabling
100BASE-TX A physical medium defined in the IEEE 802.3 Ethernet standard for local area networks (LANs) that uses twistedpair cabling category 5 or higher with RJ-45 connectors
611 series Series of numerical protection and control relays for low-end protection and supervision applications of utility substations, and industrial switchgear and equipment
CB
CSV
Circuit breaker
Comma-separated values
DAN
DC
DPC
EMC
Ethernet
Doubly attached node
1. Direct current
2. Disconnector
3. Double command
Double-point control
Electromagnetic compatibility
A standard for connecting a family of frame-based computer networking technologies into a LAN
First in, first out FIFO
FTP
FTPS
GOOSE
HSR
File transfer protocol
FTP Secure
Generic Object-Oriented Substation Event
High-availability seamless redundancy
HTTPS
IEC
Hypertext Transfer Protocol Secure
International Electrotechnical Commission
IEC 61850 International standard for substation communication and modeling
IEC 61850-8-1 A communication protocol based on the IEC 61850 standard series
IED
IEEE 1686
Intelligent electronic device
Standard for Substation Intelligent Electronic Devices'
(IEDs') Cyber Security Capabilities
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Section 5
Glossary
1MRS758335 D
RSTP
SAN
SNTP
SO
WAN
WHMI
PCM600
PO
PRP
REU611
RJ-45
RS-485
IRIG-B
LAN
LC
LCD
LED
LHMI
MAC
MCB
MMS
Modbus
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.
Inter-Range Instrumentation Group's time code format B
Local area network
Connector type for glass fiber cable, IEC 61754-20
Liquid crystal display
Light-emitting diode
Local human-machine interface
Media access control
Miniature circuit breaker
1. Manufacturing message specification
2. Metering management system
A serial communication protocol developed by the Modicon company in 1979. Originally used for communication in PLCs and RTU devices.
Protection and Control IED Manager
Power output
Parallel redundancy protocol
Voltage protection and control relay
Galvanic connector type
Serial link according to EIA standard RS485
Rapid spanning tree protocol
Single attached node
Simple Network Time Protocol
Signal output
Wide area network
Web human-machine interface
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—
ABB Distribution Solutions
Distribution Automation
P.O. Box 699
FI-65101 VAASA, Finland
Phone +358 10 22 11 www.abb.com/mediumvoltage www.abb.com/relion
© Copyright 2019 ABB. All rights reserved.
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Table of contents
- 9 This manual
- 9 Intended audience
- 10 Product documentation
- 10 Product documentation set
- 10 Document revision history
- 11 Related documentation
- 11 Symbols and conventions
- 11 Symbols
- 12 Document conventions
- 12 Functions, codes and symbols
- 15 Overview
- 15 Product version history
- 15 PCM600 and relay connectivity package version
- 16 Operation functionality
- 16 Optional functions
- 16 Physical hardware
- 17 Local HMI
- 18 Display
- 19 LEDs
- 19 Keypad
- 20 Web HMI
- 21 Command buttons
- 22 Authorization
- 23 Audit trail
- 25 Communication
- 26 Self-healing Ethernet ring
- 27 Ethernet redundancy
- 29 Secure communication
- 31 Standardized configuration
- 32 Switch groups
- 32 Input switch group ISWGAPC
- 33 Output switch group OSWGAPC
- 33 Selector switch group SELGAPC
- 35 Connection diagrams
- 37 Configuration A
- 37 Applications
- 38 Functions
- 38 Default I/O connections
- 39 Predefined disturbance recorder connections
- 39 Functional diagrams
- 40 Functional diagrams for protection
- 45 Functional diagrams for disturbance recorder and trip circuit supervision
- 47 Functional diagrams for control
- 49 Switch groups
- 50 Binary inputs
- 54 Internal signal
- 55 Binary outputs and LEDs
- 73 GOOSE
- 75 Inputs
- 75 Energizing inputs
- 75 Phase voltage
- 75 Residual voltage
- 75 Auxiliary supply voltage input
- 76 Binary inputs
- 76 Outputs
- 76 Outputs for tripping and controlling
- 77 Outputs for signalling
- 77 IRF