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Summary

Module name: IEC 61850 Client Communication Protocol
Current Version: 9.2
DLL ImplementationP: T.ProtocolDriver.IEC61850.dll
ProtocolP: IEC 61850 Edition 2
InterfaceP: TCP/IP
Description: Action.NET implements the part of the IEC 61850 standard responsible for the ACSI service core, as defined in section 8-1 of that standard. It uses ISO/OSI transport layer encapsulated in TCP/IP transport layer. Performs communication with IEDs (intelligent Electronic Devices), RTUs (Remote Terminal Units,) and IO devices compatible with this protocol, acting as client station.
System Requirements: Use of the software Action.NET
Observation: Net software

Max number of nodes: User defined

Note

This communication module was re-written for version an-2016.2 and later versions, using a library other than the one previously used (IEC 61850v1), and changes were also made in the configuration procedures of channels, nodes and points. The

following item

migration section on this page provides notes to assist in the migration of projects that already used the module from the previous version.

TagProviders and Device Channels

There are 2 independent ways to use this protocol. Using a TagProvider configuration, or as a Device-Channel.

TagProvider allows you to connect with data in devices directly, without create creating local tags, using the name definition on the remote device.

DeviceChannel allows to map tags in the project to external data addresses, giving more flexibility on name conventions and managing data blocks.

This document has the describes specific information about the device configuration on both methods. For a Generic Explanation broader view on TagProviders, or about the Device Module, Channels, Nodes and Points, please refer to the reference product’s users guide.

Migration

Users of the Action.NET who use the communication module of edition 1, need to update the registration of channels, nodes and project points. The migration should be done by following the steps below:

  1. Copy all points for nodes from project Communication Module 61850 to an Excel spreadsheet.

  2. Delete all points for nodes from project Communication Module 61850.

  3. Copy the names of the project nodes and channels to the notebook.

  4. Erase all nodes.

  5. Delete all channels.

  6. Create the channels with the previously copied names in step 3. Setting each channel according to session CHANNEL CONFIGURATION

  7. Create the nodes with the previously copied names in step 3. Configuring each node according to session CONFIGURATION OF NODES

  8. Paste the previously copied points into step 1.

  9. When starting the Communication Module. Validations of registrations will be carried out. If there are inaccuracies in point definitions, they will be recorded in the Log (See session 7.1 - Records of operations and check how to fix them in the session CONFIGURATION OF POINTS.

IEC Standard 61850

This topic aims to briefly present some information of the IEC 61850 standard, which directly interferes in the definition and implementation of this communication module.
For more details and a formal description, refer to the standard texts or the documentation of the server IEDs.
The standard consists of ten parts, listed in the table below.

Chapter

Description

1

Introduction and overview

2

Glossary

3

General Requirements

4

System and project management

5

Communication requirements for device roles and models

6

Description language setting for communication in substations with IEDs

7.1

Basic communication structures for substations and feeders: Principles and models

7.2

Basic communication structures for substations and feeders: Service interface of

7.3

Basic communication structures for substations and feeders: Common data class

7.4

Basic communication structures for substations and feeders: Logical node classes and compatible data

8.1

Mapping for MMS (ISO/IEC 9506-1 and ISO/IEC 9506-2) and for ISO/IEC8802-3

9.1

Sampled values on point-to-point multidrop one-way link

9.2

Sampled values on ISO/IEC8802-3

10

Compliance tests

With regard to support for data communication, between computers and IEDs, standardized by the standard, the message types are defined, listed in the table below.

Message


Description

Goose 

Generic Object Oriented Substation Event

Multicast messages that carry information between IEDs. They are responsible only for the traffic of messages that inform about the performance of any protection or digital signal.

MMS 

Manufacturing Message Specification

Unicast messages that are used to exchange measurement (analog) or state (digital) data to indicate the state of equipment and process.

One of the great advantageous differentials introduced by the standard, in the definition of its data communication protocol, is the fact that the points internal to an FDI are not addressed by numbers, as in other protocols, but are considered "objects" and addressed by names that are standardized by the standard.
Internally to IEDs IEC61850 there is a map of objects, arranged in a hierarchical structure. In communication between a customer (e.g. Action.NET) and the server (for example a digital-IED shuttle) traffic in the protocol messages these object names (at least in the initial communication establishment).
To get a general idea about these object names, the structure of the hierarchy of iEC61850 address maps is presented here.

LD - Logical Devices – It is the logical devices within this physical server, which function as "containers" of functions (Logical Nodes) or even as "gateways" between LNs of different LDs. The internal Names of the IED are usually used in the initial part of the name (prefixes) and suffixes that indicate the main function of the LD. Examples of CTRL, MEAS, etc. suffixes.
LN - Logical Nodes – These are objects that implement the basic well-defined functions within logical device. Logical Nodes names are standardized. Each LN contains objects, datasets, definitions of Reports, Logs, parameter groups, and services that implement objects and functions. For example, a sectioning key, its state, its control, such as the one named "Q0CSWI1". The LN in this case is the CSWI - "Switch controller". Other examples of LNs would be those performing measurement functions (MMXU), voltage transformer (TVTR), overcurrent protection (PTOC), thermal protection (PTTR). A complete list of NLs for use in substations IEDs and the rules for the formation of their names are presented in IEC61850- Part 5.
FC - Functional Constraints The Function defined by LN will contain several objects that are distributed into categories defined as FC-Functional Constraints. For example "CO" that will contain command objects, "ST" that will contain digital signage objects, "RP", for objects of type Reports. Figure 4 shows measuring objects that fall into the "MX" category. The following list of CFs was obtained in iEC61850 Part 7-2- 2003 - Table 18 - In the original table there are more details about each item.
ST Status information
MX Measurands (analogue values)
CO Control Attribute shall be operated (control model) and read
SP Setpoint DataAttribute shall represent a set-point: value may be controlled and read.
SV Substitution DataAttribute shall represent a substitution
CF Configuration DataAttribute shall represent a configuration
ANNO DOMINI Description DataAttribute shall represent a description
SG Setting group Logical devices that implement the SGCB class
IF Setting group
EX Xtended definition
BR Buffered report
RP Unbuffered report
LG Logging Attribute shall represent a log control
GO Goose control Attribute shall represent a goose control
GS Gsse control Attribute shall represent a goose control
MS Multicast sampled value control
US Unicast sampled value control
DO - Data objects - Data Objects are objects, with standardized names, that contain the information itself. These objects can be simple, such as the "Pos" object, which provides the circuit breaker position information. There are more complex objects "A", which represents a three-phase current. It consists of four Data Attributes, each of which, with data attributes children current information of each phase and a neutral. In the latter case, multiple levels of Data Attributes are found in the hierarchy below a Data Object.
Examples of DataObjects are:
Beh - Behavior of LN
Health - state of the logical node related HW and SW.
Loc - switchover between local and remote operation
Mod - Mode and behavior: On, Blocked, Test, Test/Blocked, Off
Pos - Switch position
A - Current
neut - phase neutral
phsA, phsB,PhsC – phases A, B and C
Hz - Frequency
PPV - Phase to phase voltages.
PhV - Phase to ground voltages for Phases 1, 2, and 3, including Angle
DA - Data attributes -Each object hierarchically below a Data Object or other Data Attribute, in the case "ctlNum" or a current phase as "phsC". Examples:
In the case of "Pos" you can see four Data Attributes:
stVal - which contains the state of the circuit breaker
q – the quality of the data
t – sampling timestamp
ctlNum - number of data object status exchange sequence
In the case of the current "pshC", besides being a Data Attribute itself, it still contains 4 Data Attributes below you:
cVal - the measurement of the current
instCval - instantaneous measurement of current in last acquisition
q – the quality of the data
t – sampling timestamp.

Communication Module

The communication module (Communication Module) consists of two libraries that work together: Communication and Integration.

Communication Library

The communication library is developed in the C++ programming language and is responsible for communication between the Communication Module and equipment. It has been designed according to standard series 2 edition 2 IEC 61850.

Supported objects

The following table provides an overview of the supported IEC 61850 objects.

IEC 61850 Objects

MMS Object

SERVER class

Virtual Manufacturing Device (VMD)

LOGICAL DEVICE class

Domain

LOGICAL NODE class

Named Variable

DATA class

Named Variable

DATA-SET class

Named Variable List

SETTING-GROUP-CONTROL-BLOCK class

Named Variable

REPORT-CONTROL-BLOCK class

Named Variable

LOG class

Journal

LOG-CONTROL-BLOCK class

Named Variable

GOOSE-CONTROL-BLOCK class

Named Variable

GSSE-CONTROL-BLOCK class

Named Variable

CONTROL class

Named Variable

Files

Files

Supported services

The following table provides an overview of the Supported Abstract Communication Service Interface (ACSI) services.

IEC 61850 Model

IEC 61850 Services


AA: TP/MC

Client

Server

Server

S1

ServerDirectory

TP

Application association

S2

Associate

TP


S3

Abort

TP


S4

Release

TP

Logical device

S5

LogicalDeviceDirectory

TP

Logical node

S6

LogicalNodeDirectory

TP


S7

GetAllDataValues

TP

Date

S8

GetDataValues

TP


S9

SetDataValues

TP


S10

GetDataDirectory

TP


S11

GetDataDefinition

TP

Date set

S12

GetDataSetValues

TP


S13

SetDataSetValues

TP


S14

CreateDataSet

TP


S15

DeleteDataSet

TP


S16

GetDataSetDirectory

TP

Substitution

S17

SetDataValues

TP

Setting group control block

S18

SelectActiveSG

TP


S19

SelectEditSG

TP


S20

SetSGValues

TP


S21

ConfirmEditSGValues

TP


S22

GetSGValues

TP


S23

GetSGCBValues

TP

Buffered report control block (BRCB)

S24

Report

TP


S24-1

data-change (dchg)

TP


S24-2

qchg-change (qchg)

TP


S24-3

data-update (dupd)

TP


S25

GetBRCBValues

TP


S26

SetBRCBValues

TP

Unbuffered report control block (URCB)

S27

Report

TP


S27-1

data-change (dchg)

TP


S27-2

qchg-change (qchg)

TP


S27-3

data-update (dupd)

TP


S28

GetURCBValues

TP


S29

SetURCBValues

TP

Log control block

S30

GetLCBValues

TP


S31

SetLCBValues

TP


S32

QueryLogByTime

TP


S33

QueryLogAfter

TP


S34

GetLogStatusValues

TP

GOOSE control block

S35

SendGOOSEMessage

MC


S36

GetGoReference

TP




S37

GetGOOSEElementNumber

TP




S38

GetGoCBValues

TP


S39

SetGoCBValues

TP

GSSE control block

S40

SendGSSEMessage

MC




S41

GetGsReference

TP




S42

GetGSSEElementNumber

TP




S43

GetGsCBValues

TP




S44

SetGsCBValues

TP



Multicast SVC

S45

SendMSVMessage

MC



S46

GetMSVCBValues

TP


S47

SetMSVCBValues

TP

Unicast SVC

S48

SendUSVMessage

TP



S49

GetUSVCBValues

TP


S50

SetUSVCBValues

TP

Control

S51

Select

TP


S52

SelectWithValue

TP


S53

Cancel

TP


S54

Operate

TP


S55

Command-termination

TP


S56

TimeActivated-Operate

TP

File transfer

S57

GetFile

TP


S58

SetFile

TP


S59

DeleteFile

TP


S60

GetFileAttributeValues

TP

Team

T1 

Time resolution of internal clock


1ms

1ms


T2

Time accuracy of internal clock





T3

Supported Timestamp resolution


1ms

1ms

AA - Application association
TP – Two-party application association (MMS over TCP/IP or Unicast Sampled Value on top of Ethernet)
MC – Multicast application association (GOOSE or SV using multicast messages on top of Ethernet)
✓ - Supported








Integration Library

The integration library is developed in the C# programming language and the library is responsible for the integration between the Communication Module and SCADA. It aims to transpose the information read and written between the equipment and the Action.NET.

Implemented objects

The following table provides an overview of the Implemented IEC 61850 objects. The fields marked (✓) indicate the implementation of the service.

IEC 61850 Objects


SERVER class


LOGICAL DEVICE class

LOGICAL NODE class

DATA class

DATA-SET class

SETTING-GROUP-CONTROL-BLOCK class


REPORT-CONTROL-BLOCK class

LOG class


LOG-CONTROL-BLOCK class


GOOSE-CONTROL-BLOCK class


GSSE-CONTROL-BLOCK class


CONTROL class

Files


Implemented services

The following table provides an overview of the IEC 61850 (Abstract Communication Service Interface) (ACSI) services implemented. The fields marked (✓) indicate the implementation of the service.

IEC 61850 Model

IEC 61850 Services



Server

S1

ServerDirectory

Application association

S2

Associate


S3

Abort


S4

Release

Logical device

S5

LogicalDeviceDirectory

Logical node

S6

LogicalNodeDirectory


S7

GetAllDataValues

Date

S8

GetDataValues


S9

SetDataValues


S10

GetDataDirectory


S11

GetDataDefinition

Date set

S12

GetDataSetValues


S13

SetDataSetValues



S14

CreateDataSet



S15

DeleteDataSet



S16

GetDataSetDirectory

Substitution

S17

SetDataValues


Setting group control block

S18

SelectActiveSG



S19

SelectEditSG



S20

SetSGValues



S21

ConfirmEditSGValues



S22

GetSGValues



S23

GetSGCBValues


Buffered report control block (BRCB)

S24

Report


S24-1

data-change (dchg)


S24-2

qchg-change (qchg)


S24-3

data-update (dupd)


S25

GetBRCBValues


S26

SetBRCBValues

Unbuffered report control block (URCB)

S27

Report


S27-1

data-change (dchg)


S27-2

qchg-change (qchg)


S27-3

data-update (dupd)


S28

GetURCBValues


S29

SetURCBValues

Log control block

S30

GetLCBValues



S31

SetLCBValues



S32

QueryLogByTime



S33

QueryLogAfter



S34

GetLogStatusValues


GOOSE control block

S35

SendGOOSEMessage



S36

GetGoReference



S37

GetGOOSEElementNumber



S38

GetGoCBValues



S39

SetGoCBValues


GSSE control block

S40

SendGSSEMessage



S41

GetGsReference



S42

GetGSSEElementNumber



S43

GetGsCBValues



S44

SetGsCBValues


Multicast SVC

S45

SendMSVMessage



S46

GetMSVCBValues



S47

SetMSVCBValues


Unicast SVC

S48

SendUSVMessage



S49

GetUSVCBValues



S50

SetUSVCBValues


Control

S51

Select


S52

SelectWithValue


S53

Cancel



S54

Operate


S55

Command-termination



S56

TimeActivated-Operate


File transfer

S57

GetFile



S58

SetFile



S59

DeleteFile



S60

GetFileAttributeValues


Team

T1 

Time resolution of internal clock



T2

Time accuracy of internal clock



T3

Supported Timestamp resolution


Functional Constraints implemented

The following table provides an overview of the Functional Constraint property found in each attribute of a logical node. The marked fields (✓) indicate the implementation of reading or writing.

Functional Constraint


Read

Write

BL

Blocking



BR

Buffered report

CF

Configuration

CO

Control


ANNO DOMINI

Description

EX

Extended definition

LG

Log control blocks



MS

Multicast SV



MX

Measurands (analog values)


OR

Operate received



RP

Unbuffered report

IF

Editable setting group



SG

Setting group



SP

Setpoint

MR

Service response / Service tracking



ST

Status information


SV

Substitution



US

Unicast SV



Operation

The communication module works briefly with the following sequence of steps.

Stage

Goal

Description

1

Channel startup

The channel settings are read.
The settings are read in the IEC61850 .xml is performed.
The validation of the information is performed.

2

Booting the node(s)

A communication and reading of the equipment's data structure is established. This reading is essential for the operation of the Communication Module. This step is recursive, that is, only when it is successfully completed that the Communication Module will proceed to the next step.

3

Start-up of the dot(s)

The reading of the registered points is performed.
The validation of the registration of the points is performed. It is also evaluated whether the point exists and whether the Communication Module has implementation to read or write on the point.

4

Starts reading and writing tasks

The task of reading COMTRADE files and points starts according to the node settings.
The writing task starts and triggered when a point of the writing type changes value.
The task of reading received reports starts and the report points are signed.

5

Runs tasks cyclically

Read and write tasks run as configured. If connection is lost, go back to step 2.

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