Post on 23-Mar-2021
UNIVERSIDAD NACIONAL DE INGENIERÍA
FACULTAD DE INGENIERÍA ELÉCTRICA Y ELECTRÓNICA
NUEVAS TENDENCIAS EN LA AUTOMA TIZACION DE
SUBESTACIONES DE POTENCIA
INFORME DE SUFICIENCIA
PARA OPTAR EL TÍTULO PROFESIONAL DE:
INGENIERO ELECTRICISTA
PRESENTADO POR:
DIOGENES NEMESIO GONZALES DE LA CRUZ
PROMOCIÓN. 1996 -11
LIMA-PERÚ 2008
NUEVAS TENDENCIAS EN LA AUTOMATIZACION DE SUBESTACIONES DE ,
POTENCIA
Dedico este trabajo a:
La memoria de mi padre, Teofanes
A mi madre, Cristina por inculcarme los deseos de superación,
A Karen , por su amor y apoyo constante, y
A mi hija Alejandra por la felicidad que me brinda aun antes de nacer
SUMARIO
Desde hace 02 décadas las empresas eléctricas alrededor del mundo han experimentado
cambios dramáticos. La tendencia en el ámbito mundial hacia la desregulación y
privatización de los servicios de generación, transmisión y distribución de la Energía
Eléctrica se encuentra centrada en la creación de empresas que operen en mercados
competitivos. Las nuevas empresas se ven obligadas a minimizar sus gastos, optimizar
sus inversiones y buscar nuevas filosofías de operación las cuales ahora son posibles
debido a los avances actuales en la tecnología digital aplicada a los equipos de
protección y control eléctrico así como en las comunicaciones.
Siendo la Subestación de Potencia una parte importante en los procesos operacionales
de una Empresa Eléctrica , el presente informe tiene como objetivo general presentar los
nuevos estándares y tendencias industriales relacionadas con la automatización de
Subestaciones de potencia las mismas que deben ser tomadas en consideración en todo
nuevo proceso de automatización de Subestaciones . El objetivo especifico del informe es
detallar las características generales de la Norma IEC 61850 Communication Networks,
and systems in Substations. y presentar los beneficios que su implementación traería a
las diferentes· áreas de la empresa eléctrica.
El capítulo I se presentan los Estándares Internacionales actuales y tendencias
industriales en la automatización de Subestaciones de Potencia El objetivo de este
capítulo es dar a conocer las normas internacionales actuales y tendencias que deben
ser tomadas en cuenta en todo proceso de Automatización de Subestaciones.
El capítulo II presenta la Norma IEC 61850 y su marco teórico. se indican también los
beneficios de su implementación así como los desarrollos futuros de la norma.
En el capítulo III se indican las aplicaciones de la norma alrededor del mundo lo cual
comprueba las características de verdadero estándar mundial.
Finalmente se presentan las principales conclusiones del informe.
ÍNDICE
INTRODUCCION 1
CAPÍTULO 1
ESTANDARES INTERNACIONALES ACTUALES Y TENDENCIAS INDUSTRIALES DE
AUTOMATIZACION DE SUBESTACIONES DE POTENCIA
1.1.
1.2.
1.2.1.
1.2.2.
1.2.3.
1.2.4.
1.2.5
1.2.6.
1.2.7.
1.3.
1.3.1.
1.3.2
1.3.3
Introducción
Estandares Internacionales Actuales
IEEE 1613 e IEC 61850-3
Protocolos de Comunicacion
IEEE 802.3 : Ethernet
IPV4 e lPV6
ICCP
Sincrophasor: IEEE Standard C37.118-2005
Sincronización de tiempo para comunicaciones en Subestaciones
Tendencias Industriales Actuales
Uso de los equipos Electronicos Inteligentes (IEDs)
Utilizacion de Fibra Optica
Migración de Comunicación Serial a Ethernet
1.3.4 Division de la Data en Operacional y No Operacional
1.3.5 Ciber Seguridad
CAPÍTULO 11
IEC 61850 2.1. Introducción
2.2. Descripcion
2.3. Caracteristicas
2.4 El futuro de IEC 61850
2.5 IEC 61850 y la "Red Inteligente Empresarial"
2.6 Beneficios Económicos por Implementación del IEC 61850
CAPÍTULO 111
APLICACIÓNES ALREDEDOR DEL MUNDO DEL IEC 61850 4.1. lntroduccion
4.2. Experiencia Internacional
3
3
3
3
5
8
8
10
11
11
12
12
12
13
13
13
16 16
19
23
28
28
29
32 32
32
CONCLUSIONES 34
ANEXO A ARQUITECTURAS TRADICIONALES BAJO LA NORMA IEC61850 35
VII
ANEXO B PROCESO DE INTEGRACION DE IEDS BAJO LA NORMA IEC 61850 38
ANEXO C EQUIPOS DE COMUNICACIONES QUE CUMPLEN CON LA NORMA IEC
61850
ANEXO D RESUMEN DE NORMAS IEC 61850
TERMINOS USUALES
BIBLIOGRAFIA
43
69
182
185
INTRODUCCIÓN
Antecedentes
La automatización de Subestaciones es desde la aparición del IEC 61850 mas que solo
la automatización de equipos. Es uno de los primeros pasos para la creación de un
altamente confiable sistema de potencia que responda rápidamente a los eventos en
tiempo real con apropiadas acciones y que soporte el planeamiento y administración
necesaria para un costo efectivo en las operaciones. La automatización no es
simplemente el reemplazo de procedimientos manuales mas bien debe permitir al
Sistema de potencia operar de una forma basada en la precisión de la información en el
momento oportuno.
En el pasado la atención de las empresas eléctricas estuvo enfocada solo en la
administración de la infraestructura del sistema de potencia. Sin embargo el mundo ha
cambiado, ahora hay 02 infraestructuras que deben ser administradas: La infraestructura
del Sistema de Potencia y la Infraestructura del Sistema de Comunicaciones.
La automatización de Subestaciones tal como la presenta la IEC 61850 no estuvo
disponible hasta hace algunos años atrás debido a que las comunicaciones no estuvieron
disponibles para soportar las aplicaciones que en ese entonces se requerían. Por lo tanto
uno de las principales habilitadores para que se logre la automatización de subestaciones
fue reconocer que el cableado extenso entre los equipos en patio de llaves y la sala de
control se podrían eliminar con la aplicación de la tecnología Ethernet . Hoy en día el
desarrollo de las comunicaciones hace posible que las aplicaciones hasta ese entonces
soñadas se efectúen.
Otro de los principales habilitadores es el avance de la tecnología digital que logro que
los tradicionales equipamientos como medidores, relés de protección y Unidades
Terminales Remotas (UTR) hayan adquirido nuevas características y funcionalidades,
una de ellas es la capacidad de "hablar un lenguaje" (protocolo de comunicación) a fin de
entregar toda la información valiosa que disponen.
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Objetivos del Informe
El informe tiene por objetivo presentar las nuevas tendencias mundiales relacionadas con
la automatización de Subestaciones de potencia las mismas que deben ser tomadas en
consideración en todo nuevo proceso de automatización de Subestaciones
fundamentalmente aquellas que se efectúan bajo la Norma IEC 61850.
Se presenta la Norma IEC 61850 como uno de de los primeros pasos para la creación de
un altamente confiable sistema de potencia que responda rápidamente a los eventos en
tiempo real con apropiadas acciones y que soporte el planeamiento y administración
necesaria para un costo efectivo en las operaciones.
Se indica además como la implementación de la Norma IEC 61850 conduce a la
formación de la red inteligente empresarial el cual traería muchos beneficios a las
diferentes áreas de la empresa eléctrica.
Estructura del Informe
El documento está dividido en tres capítulos y conclusiones:
El capítulo I se presentan los Estándares Internacionales actuales y tendencias
industriales en la automatización de Subestaciones de Potencia El objetivo de este
capítulo es dar a conocer las normas internacionales actuales y tendencias que deben
ser tomadas en cuenta en todo proceso de Automatización de Subestaciones.
El capítulo II presenta la Norma IEC 61850 y su marco teórico. se indican también los
beneficios de su implementación así como los desarrollos futuros de la norma.
En el capítulo III se indican las aplicaciones de la norma alrededor del mundo lo cual
comprueba las características de verdadero estándar mundial.
Finalmente se presentan las principales conclusiones del informe.
CAPÍTULO 1
ESTANCARES INTERNACIONALES ACTUALES Y TENDENCIAS INDUSTRIALES DE AUTOMATIZACION DE SUBESTACIONES DE POTENCIA
1.1 Introducción
Este capítulo describe los estándares internacionales actuales asociados a la
automatización de Subestaciones de Potencia y las nuevas tendencias industriales
usadas como referencia en la planificación y desarrollo de las nuevas arquitecturas de
automatización de Subestaciones.
1.2 Estándares Internacionales actuales
El avance de la tecnología digital y las comunicaciones en los equipos utilizados en las
Subestaciones Eléctricas han traído como consecuencia la necesidad de nuevos
estándares.
1.2.1 Operación de Equipos de Comunicaciones en Subestaciones Eléctricas :
IEEE 1613 e IEC 61850-3
Hoy en día existen 04 estándares IEEE desarrollados por el Power Systems Relaying
Commitee PRSC del IEEE dirigidos a la operación de los relés de protección en las
Subestaciones Eléctricas
• ANSI/IEEE C37.90-1989 IEEE Standard for Relays and Re/ay Systems
Associated with Electric Power Apparatus: Défine las condiciones de servicio ,
niveles de tensión, rangos de temperatura , humedad y los requerimientos
dieléctricos y capacidad de soporte al impulso de los relés de protección.
• IEEE Std C37.90.1-2002™ IEEE Standard for Surge Withstand Capability (SWC)
Tests for Relays and Re/ay Systems Associated with Electric Power Apparatus:
Define la capacidad requerida para soportar los transitorios sin daño o falsa
operación.
4
• C37.90.2 -2004 IEEE Standard for Withstand Capability of Re/ay Systems to
Radiated Electromagnetic lnterference from Transceivers: Define los
requerimientos de inmunidad para la operación de equipos de comunicaciones
personales (walkie-talkies) en ambientes cercanos a los re/es .
• IEEE C37.90.3 Standard Electrostatic Discharge Tests for Protective Relays:
Define los requerimientos de inmunidad de los relés de protección para
transitorios debido a baja humedad y tensiones de descarga estática.
Dado que hoy en día se utilizan muchos equipamientos de comunicaciones tales como
Switches y Routers en el ambiente en donde operan los relés de protección
(Subestaciones Eléctricas) dichos equipamientos deben tener el mismo o superiores
requerimientos de performance que los relés de protección
Es asi que el Grupo de trabajo C2TF1 del IEEE Power Engineering Society Substations
Committee elaboro el Estandard IEE1613 Standard Environmental and Testing
Requirements for Communications Networking Devices in Electric Power
Substations el cual provee nuevos criterios para las pruebas de equipos en las
Subestaciones. Básicamente el estándar indica que los equipos de Networking deben
cumplir similar o superiores condiciones de prueba que los reles de protección. El
estándar define condiciones de servicio, condiciones ambientales y valores de prueba
para modems, firewall, Routers, Switches y todo equipamiento de Networking dentro de
Subestaciones.
La norma IEE 1613 define 02 tipos de clase de performance:
PERFORMANCE CLASE 1 : Es para equipos usados para propósitos generales dentro
de una Subestación donde perdidas temporales de comunicación y/o errores de
comunicación pueden ser tolerados durante la ocurrencia de un transitorio.
PERFORMANCE CLASE 2 : Es para equipos usados dentro de subestaciones donde se
desea ningún error en los equipos de comunicaciones ante la ocurrencia de un transitorio.
La Performance Clase 1 es el mínimo requerimiento del IEE 1613, la performance Clase
2 no es mandataria y es una opción que puede ser usada por un fabricante o empresa
eléctrica.
Para cumplir con los requerimientos de Performance Clase 2 es necesario tener Fibra
óptica . Las fuentes de poder internas de los equipos tendrían que ser blindadas para que
dichos transitorios no lleguen a las fuentes de poder.
Similar al IEEE 1613 la norma IEC61850 también define requerimientos ambientales para
equipos de comunicaciones dentro de una Subestación. Este Estándar esta dividido en
5
1 O partes el cual ofrece un marco completo de pruebas incluyendo EMI (Interferencia
Electromagnética), requerimientos de inmunidad y medioambiente (IEC 61850-3).
1.2.2 Protocolos de Comunicación
Los protocolos de comunicación es el "lenguaje de los IEDs". Son un conjunto de reglas
que permiten que 02 equipos intercambien información. A continuación se describe los
protocolos de comunicación de mayor uso en el ambiente eléctrico:
DNP3 SERIAL Y DNP3 LAN
DNP es basado en los estandards de la IEC Technical Commitee 57, Working Group 3
quienes trabajaron en la estandarización de un protocolo de 3 capas OSI llamado
"Enhanced Performance Architecture" (EPA) que es un protocolo para telecontrol. DNP
fue seleccionada como una práctica recomendada del IEEE C.2 task Force como
protocolo recomendado para unidades terminales remotas
DNP 3 es un protocolo de adquisición de datos utilizado por las compañías eléctricas, gas
y agua . Es diseñado como un abierto, interoperable y simple protocolos para Sistemas
Scada . Usa la interrogación Maestra/Esclava para enviar y recibir información.
DNP 3 es un protocolo de 03 capas ( Capa física, Enlace de Datos y Aplicación) . Provee
multiplexación, fragmentación de datos , corrección de errores, priorización . DNP 3
ofrece las siguientes importantes características:
• Transferencia de archivos
• Capacidad de soportar 65520 equipos
• Sincronización de tiempo y estampando de eventos
• Mensajes tipo Broadcast
• Confirmación en la capa de enlace de datos y Capa de aplicación
6
La capa de aplicación es basada en objetos y se cuenta con una lista extensa de objetos
funciones y formatos para el que pregunta como el que responde. La Capa de enlace de
datos provee métodos de conseguir la información tales como POLL-RESPONSE
POLLED-REPORT-BY-EXCEPCION , UNSOLICITED-RESPONSED y PEER-TO-PEER
lo cual permite múltiples maestras.
En años recientes muchos vendedores han usado TCP/IP para transportar los mensajes
DNP 3 en lugar que los tradicionales medios seriales (RS 232 y RS 485) . La capa de
enlace de datos son inmersas en paquetes TCP/IP. Esta característica ha hecho que
DNP 3 tome ventaja de la tecnología Internet asi como de la tecnología Ethernet vía
redes LAN yWAN.
Este protocolo es utilizado en Norte América y Latinoamérica como protocolo de
comunicación entre el Centro de Control y las Subestaciones Eléctricas.
IEC J,0870-5-101
El IEC 60870-5-101 utiliza las capas 1, 2 y7 del Modelo OSI . Dicho protocolo puedes ser
implementado en dos modalidades:
A) Configuración tipo BUS, el cual utiliza una comunicación Maestra-Esclava con
interrogaciones cíclicas
B} Configuración dé _conexiones individuales,. el cual permite un balaceado acceso al
medio y envío de datos en ambas direcciones.
Las aplicaciones que efectúa dicho protocolo son las siguientes:
• Adquisición de datos por interrogación cíclica
• Adquisición de eventos
• Sincronización de tiempo
• Transmisión de ordenes
• Interrogación general
• Transferencia de archivos
Este protocolo es utilizado con mucha regularidad en Europa como protocolo de
comunicación entre el Centro de Control y las Subestaciones Eléctricas.
7
IEC 60870-5-103
Es un protocolo de comunicación creado para el intercambio de datos entre relés de
protección dentro de una Subestación.
La capa física soporta 02 ·configuraciones : RS485 tanto para su interface eléctrica como
de fibra óptica. Las velocidades de transmisión son de 9.6 kbps o de 19.2 kbps.
El protocolo opera como un Sistema Maestro esclavo y usa una interrogación cíclica
como método de acceso al medio. Soporta las capas 1, 2 y 7 del modelo OSI.
UCA2.0
El Electric Power Research lnstitute (EPRI) desarrolló la suite de protocolos conocida
como "Utilities Communications Architecture versión 2" (UCA 2.0) . Este protocolo es
basado en la utilización de Ethernet e incorpora la utilización de TCP/IP y MMS para las
capas de aplicación.
El protocolo utiliza las 07 capas del modelo OSI . El principio CSMA/CD de ethernet es
utilizado para el acceso al medio y soporta comunicaciones punto a punto así como
Maestro - Esclavo.
El protocolo UCA 2.0 puede ser utilizado dentro de una Subestación y hacia el centro de
control.
UCA 2.0 ofrece interconectividad e interoperatividad entre equipos de diferentes
fabricantes para intercambiar datos entiempo real en alta velocidad.
IEC 61850
¡,,IEC 61850 es un nivel superior al UCA 2.0 . Contiene. muchas de las especificaciones del
UCA 2.0 mas características adicionales . IEC 61850 fue publicada como estándar
internacional el año 2003.
Este protocolo es aplicable para la automatización y protección sobre Ethernet dentro de
una Subestación Eléctrica. Para el envío de información fuera de los limites de la
Subestación un estándar complementario se encuentra en desarrollo.
Actualmente los principales fabricantes de IEDs (ABB, AREVA, GE, SEL, SIEMENS)
ofrecen productos que cumplen con este estándar. IEC 61850 es diseñado para utilizar
una comunicación punto a punto a alta velocidad usando mensajería GOOSE (Generic
Object Orientated System Wide Events).
8
1.2.3 IEEE 802.3: Ethernet
El termino Ethernet se refiere a la familia de productos de Red de Area Local (LAN)
cubiertos por el estándar IEEE 802.3 el cual define el comúnmente conocido protocolo
CSMA/CD. 04 velocidades son actualmente definidos para operación sobre red de fibra
óptica y par trensado:
1 O Mbps - 1 O Base T Ethernet
100 Mbps - Fast Ethernet
1000 Mbps - Gigabit Ethernet
1 O Gigabit Ethernet el cual es el más reciente desarrollo publicado bajo el nombre IEEE
802.3ae como un suplemento al IEEE 802.3 .
Ethernet actualmente es usado por aproximadamente el 85% de las redes LAN de
computadoras de todo el mundo por sus siguientes cara!,'.:terísticas:
• Es fácil de entender, implementar , administrar y efectuar mantenimiento.
• Permite bajos costos de implementación de la red
• Posee una flexibilidad topológica en las instalaciones
• Garantía en la exitosa interconexión debido a que los productos cumplen un estándar
Ethernet LANs consisten de Nodos y medios de interconexión. El medio de interconexión
incluye 02 tipos de éable de cobre: Par trensado no apantallado (UTP) y par trensado
apantallado (STP)., adicionalmente existen muchos tipos de cables de fibra óptica. En
años recientes Wirelesss LAN (WI-FI) , estandarizado por el IEEE 802.11 ha sido
adicionado en muchas instalaciones.
1.2.4 IPV4 e IPV6
IPV4 es descrito en el Internet Engineering Task Force (IETF) RFC 791 (Septiembre
1981) 1Pv4 es la versión 4 del Protocolo IP (Internet Protocol). Esta fue la primera versión
del protocolo que se implementó extensamente, y forma la base de Internet.
1Pv4 usa direcciones de 32 bits, limitándola a 2A32 = 4.294.967.296 direcciones únicas,
muchas de las cuales están dedicadas a redes locales (LANs) en aproximadamente 18
millones o direcciones multicast (1 millon de direcciones) . Esto reduce el numero de
direcciones que pueden ser usados como direcciones publicas de internet y como el
numero de direcciones disponibles esta consumida, una escasez de direcciones parece
ser inevitable a la larga.
Para conectar dos redes LAN utilizando la porción publica de internet, son utilizadas
Virtual Prívate Network (VPN). VPNs trabajan insertando un Packete IP ( Packete
encapsulado) directamente dentro del campo de datos de otro packete IP ( Packete
9
encapsulador) y usando una dirección IP publica enrutable en el packete encapsulador.
Una vez que el packete VPN es enrutado alrededor de la red pública y encuentra al punto
final, el packete encapsulador es extraído y entonces transmitido en la red privada tan
igual como si las 02 redes privadas estuvieran directamente conectadas. Opcionalmente,
el packete encapsulado puede ser encriptado para asegurar el dato mientras viaja por la
red pública.
IP tiene la capacidad de proveer un parámetro llamado calidad del servicio (QoS) . En
una cabecera IP , 8 bits son asignados para definir a Tipo de Servicio (TOS) en términos
de prioridad , retardo, rendimiento de procesamiento y confiabilidad. La idea original fue
para especificar una preferencia sobre como la información será manejada en la Internet
cuando esta se envíe a un destino especifico. Esos bits han sido redefinidos muy
recientemente atraves del DIFFSERV Working Group del IETF y por los explícitos
códigos de Notificación de congestión. Además nuevas tecnologías están emergiendo
que requieren transmisión continua en tiempo real y por lo tanto se hará uso del campo
TOS. Un ejemplo es Voz sobre IP (VolP) el cual es usado para intercambio interactivo de
voz , otra aplicación seria aplicaciones en tiempo real SCADA en el ambiente de una
empresa eléctrica.
1Pv6 es la versión 6 del Protocolo de Internet (Internet Protocol), un estándar en
desarrollo del nivel dé red encargado de dirigir y encaminar los paquetes a través de una
red. 1Pv6 está destinado a sustituir al estándar 1Pv4, cuyo límite en el número de
direcciones de red admisibles está empezando a restringir el crecimiento de Internet y su
uso, especialmente en China, India, y otros países asiáticos densamente poblados. Pero
el nuevo estándar mejorará el servicio globalmente; por ejemplo, proporcionando a
futuras celdas telefónicas y dispositivos móviles con sus direcciones propias y
permanentes. Al día de hoy se calcula que las dos terceras partes de las direcciones que
ofrece 1Pv4 ya están asignadas
10
IPv4 soporta 4.294.967.296 (232) direcciones de red diferentes, un número inadecuado
para dar una dirección a cada persona del planeta, y mucho menos para cada coche,
teléfono, PDA, etcétera; mientras que IPv6 soporta
340.282.366.920.938.463A63.374.607.431.768.211.456 (2128 6 340 sextillones)
direcciones -cerca de 4,3 x 1020 (430 trillones) direcciones por cada pulgada cuadrada
(6, 7 x 1017 6 670 mil billones direcciones/mm2) de la superficie de La Tierra.
Adoptado por el Internet Engineering Task Force en 1994 (cuando era llamado "IP Next
Generation" o IPng), 1Pv6 cuenta con un pequeño porcentaje de las direcciones públicas
de Internet, que todavía están dominadas por IPv4. La adopción de IPv6 ha sido frenada
por la traducción de direcciones de red (NA T), que alivia parcialmente el problema de la
falta de direcciones IP. Pero NAT hace difícil o imposible el uso de algunas aplicaciones
P2P, como son la voz sobre IP (VolP) y juegos multiusuario. Además, NAT rompe con la
idea originaria de Internet donde todos pueden conectarse con todos. Actualmente, el
gran catalizador de IPv6 es la capacidad de ofrecer nuevos servicios, como la movilidad,
Calidad de Servicio (QoS), privacidad, etc. El gobierno de los Estados Unidos ha
ordenado el despliegue de IPv6 por todas sus agencias federales para el año 2008.
Se espera que IPv4 se siga soportando hasta por lo menos el 2011, dado que hay
muchos dispositivos heredados que no se migrarán a IPv6 nunca y que seguirán siendo
utilizados por mucho tiempo.
1.2.5 ICCP
Las empresas de servicios públicos alrededor del mundo especifican el lnter Control
Center Communications Protocol (ICCP) para proveer intercambio de datos entre centros
de control. ICCP cumple con el IEC 60870-6/TASE.2 .
ICCP opera sobre redes LANs y WANs para habilitar el intercambio de datos en tiempo
real , monitoreo y control de la información incluyendo valores de medición, datos de
planificación, datos de conteo de energía y mensajes del operador. Intercambio de datos
puede ocurrir entre los siguiente: Múltiples centros de control EMS, EMS y plantas de
poder DCS , EMS y Sistemas Scada de distribución, EMS y otros sistemas y
EMS/SCADA y Subestaciones.
Aplicaciones ICCP consisten de software Cliente y Servidor. El Software Cliente se
conecta a otros miembros de la red para solicitar datos y/o control. El software servidor
responde a las solicitudes del cliente por retornar el dato solicitado y ejecutar (si esta
permitido) la solicitud de control. Códigos de calidad tales como Setting Manual y Falla en
la telemetría son transmitidos con la información. Debido a la definición de grupos de
puntos llamados Virtual RTUs
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En el Perú el COES establece como requerimientos que las empresas de Generación,
Transmisión y distribución Eléctrica remitan ciertos tipos de señales en protocolo ICCP
con el fin de monitorear en tiempo real el comportamiento en estado estacionario del
Sistema Interconectado Nacional.
1.2.6 Synchrophasores: IEEE Standard C37.118-2005
La medición Sincronizada del Fasor o Syncrophasor provee un método para comparar
ángulos de las tensiones y corrientes en cualquier lugar del Sistema Eléctrico en donde
se encuentre un IED que tenga estas características.
El equipo de medición del Fasor también llamado PMU es un equipo que reporta por
medio de un puerto de comunicaciones los valores en tiempo real de los fasores de
tensión y corriente los cuales son sincronizados por medio de un GPS. Para empresas de
Trasmisión los PMUs dan una fotografía instantánea del estado del sistema eléctrico. Se
estima que en EEUU la utilización del Syncrophasor permitirá incrementar en un 20% la
eficiencia de la transmisión de la energía eléctrica.
Actualmente esta norma se encuentra en revisión del IEEE Power System Relaying
Commitee.
1.2. 7 Sincronización de tiempo para comunicaciones en Subestaciones
Para soportar precisiones mejores que 1 milisegundo la IEEE 1588 Standard for a
Precision C/ock Synchronization Protocol for Networked Measurement and Control
Systems define un protocolo de sincronización de tiempo en sistemas de medición y
control implementados con tecnología de red. El protocolo es aplicable a sistemas de
comunicación de redes LAN tales como ethemet.
Para implementar ello en cada Subestación debe tenerse un GPS . Dicho GPS sincroniza
vía Network Time Protocol (NTP) o Simple Network Time protocol (SNTP) . El GPS debe
tener uno o más IRIG-8 conexiones para sincronizar equipos que no son posible de
sincronizar por intermedio de la red LAN.
1.3 Tendencias Industriales Actuales
12
El avance de la tecnología digital y las comunicaciones también hizo posible que
aparezcan nuevas tendencias aplicables en la automatización de Subestaciones.
1.3.1 Uso de los equipos Electrónicos Inteligentes (IEDs)
Hoy en día con el avance de la electrónica y las comunicaciones los tradicionales
equipamientos como medidores, relés de protección y Unidades Terminales Remotas
(UTR) han adquirido nuevas características y funcionalidades, una de ellas es la
capacidad de "hablar un lenguaje " (protocolo de comunicación) a fin de entregar toda la
información valiosa que dispone.
El termino IED el cual se utilizara a lo largo del presente informe se refiere a " cualquier
dispositivo utilizado en Subestaciones Eléctricas que incorpora uno o mas procesadores
con la capacidad de intercambiar datos y efectuar secuencias de control desde o hacia
una fuente externa"
1.3.2 Utilización de la Fibra Óptica
La Fibra óptica provee aislamiento eléctrico entre los equipos de comunicación y aísla al
personal y equipami�ntos de Sobre Tensiones peligrosas. Es totalmente inmune al ruido
causado por campos electromagnéticos y puede ser tendida en áreas donde la
instalación de cables de cobre sería peligroso o exista peligro de corrupción de la data.
Los nuevos avances hacen que la fibra óptica sea una alternativa practica, económica y
segura a los cables de cobre.
Numerosas pruebas han demostrado que los cables de cobre no apantallados y
apantallados no son confiables para ser utilizados en redes de comunicación de datos en
Subestaciones Eléctricas. Dichas pruebas muestran que los transitorios eléctricos de
corta duración tienen severo impacto en la comunicación Ethernet si se usan los cables
de cobre. Dichos transitorios aparecen por ejemplo en el momento que un relé de
protección efectúa un disparo del interruptor. Por lo tanto es recomendable que cables de
fibra óptica sean utilizados para conectar todos los IEDs hacia la red LAN de la
Subestación.
1.3.3 Migración de Comunicación Serial a Ethernet
13
Las comunicaciones seriales son tradicionales en las instalaciones de las empresas
eléctricas. Dichos equipos requieren una conexión física directa para enviar su
información hacia una RTU . Una desventaja de las comunicaciones seriales es que
usualmente se encuentra asociada a protocolos propietarios y cuentan con limitada
velocidad. Ethernet en cambio ha ganado popularidad pues ofrece interoperabilidad y
performance. Hoy en día existen equipos llamados terminal servers que convierten la
comunicación serial en Ethernet llamados Terminal Servers .
1.3.4 División de la Data en Operacional y No Operacional
Actualmente en los procesos de automatización es necesaria la división de la data en
Operacional y No Operacional para efectos de dar priorización de una información con
respecto a la otra y de esta forma optimizar la performance de los equipos de
comunicaciones.
La Data Operacional es la data en tiempo real que requiere un mínimo retraso entre el
momento en que esta se genera hasta su visualización por los operadores del Sistema de
Automatización. Ejemplos de ello son los estados de los equipos de protección y
seccionamiento (abierto/cerrado),
La Data No Operacional también llamada data de soporte, es la información sobre un
evento o situación que es almacenada en archivos por los IEDs. Esta data no esta sujeta
a la necesidad de una inmediata visualización y por lo tanto es considerara como de baja
prioridad en su entrega.
1.3.5 Ciber Seguridad
Hoy en día los terroristas alrededor del mundo pueden hacer mas daño atraves de un
teclado que con una bomba.
El primer ataque extendido atraves de la red fue en 1988 cuando un hacker ataco a 6200
computadoras y causo 98 millones de dólares en daños en solo 2 días.
Estadísticas de diferentes fuentes demuestran que los ataques del Ciber espacio están
creciendo en magnitud y consecuencia.
Un análisis de los daños del Blackout que afecto a los Estados Unidos revela que se
ocasionaron entre 6 y 1 O Billones de dólares en pérdidas. Imaginemos el impacto que
pudiese darse si un hacker hubiese efectuado un ataque al Sistema de potencia.
Debido a ello la North American Electric Reliability Corporation (NERC) estableció unos
estándares de Ciber Seguridad a fin de establecer la seguridad en la información de los
14
Sistema Eléctricos de Norte América. A continuación se presentan los siguientes
estándares de Ciber Seguridad los cuales deben ser tomadas en cuenta en todo proceso
de automatización de Subestaciones:
CIP-002-01- Critical Cyber Assets
Este estándar requiere la necesidad de la identificación y enumeración de los elementos
críticos del Sistema Eléctrico. Una vez que estos son determinados se aplican los
equipos de seguridad necesarios.
CIP-003-1 - Security Management Controls
Este estándar requiere la identificación de las entidades responsables que tendrán una
administración de la seguridad para proteger los componentes críticos del Sistema
Eléctrico. Se debe incluir específicamente políticas de seguridad , programas de
protección y clasificación de la información, programas de control de accesos.
CIP-004- Personnel and Training:
Este estándar requiere que el personal al cual se le da acceso a los elementos críticos de
la Subestación tenga conocimiento del riesgo que implica prestar la clave a otro personal.
Para ello se hace necesario programas de entrenamiento en temas de seguridad de la
información al personal involucrado.
CIP-005-Electronic Security
Este estándar requiere la identificación y protección del perímetro electrónico de
seguridad donde residen los elementos críticos del Sistema Eléctrico.
CIP-006- Physical Security of Critica! Cyber Assets
Este estándar requiere la implementación de un programa físico para la protección de los
elementos identificados en CIP-002-01 . Tales protecciones serian por ejemplo personal
de seguridad , mecanismos como necesidad de llaves de acceso y autorización para
acceder a los elementos críticos.
CIP-007- System Security management
Este estándar requiere que las entidades responsables tengan sistemas de control de la
seguridad con la suficiente capacidad para detectar y prevenir cualquier falla o alteración
en la seguridad de los elementos críticos del sistema eléctrico causados por error, mal
uso o actividad maliciosa.
15
CIP-008 - lncident Reporting and Response Planning
Este estándar establece la necesidad de identificación , clasificación responsabilidad y
reporte de incidentes en la Ciber seguridad.
CIP-009 -Recovery Plans for Critical Cyber assets
Este estándar establece planes de recuperación de la información ante un evento de
desastres no controlado.
Hoy en día existes equipos que cumplen las características solicitadas por la NERC
algunos de los cuales los presentamos en el Anexo A.
En la Figura 1.1 se presenta algunos de estos equipos y su relación con los términos de
Cyber Seguridad indicados.
En el Anexo C se presenta una marca de equipos de comunicaciones que cumple con el
Estándar IEC61850 y también con los estándares de Ciber Seguridad de la NERC.
RuggedRouter™ Security Appliance (Router, Firewall, 10S)
IED
� IED = lntelligent Electronic Device
��
- = Cyber Security Interface
"Electronic Security Perimeter"
I I
RuggedServer™
Serial Device Server
/
-- --- --�
IED
RuggedSwitcb ™Ethernet Switches � -�---..-..(802.1 x, SSH, SSL)
Figura 1.1 Niveles de Seguridad en una Subestación
2.1. Introducción
CAPÍTULO 11
IEC 61850
La automatización de Subestaciones es un nuevo cambio para las empresas eléctricas
particularmente cuando las nuevas funcionalidades indicadas en la IEC 61850 son
utilizadas al máximo.
La automatización de Subestaciones es desde la aparición del IEC 61850 más que solo
la automatización de equipos. Es uno de los primeros pasos para la creación de un
altamente confiable sistema de potencia que responda rápidamente a los eventos en
tiempo real con apropiadas acciones y que soporte el planeamiento y administración
necesaria para un costo efectivo en las operaciones. La automatización no es
simplemente el reemplazo de procedimientos manuales más bien debe permitir al
Sistema de potencia operar de una forma basada en la precisión de la información en el
momento oportuno.
En el pasado la atención de las empresas eléctricas estuvo enfocada solo en la
administración de la infraestructura del sistema de potencia. Sin embargo el mundo ha
cambiado, ahora hay 02 infraestructuras que deben ser administradas: La infraestructura
del Sistema de Potencia y la Infraestructura del Sistema de Comunicaciones.
La automatización de Subestaciones tal como la presenta la IEC 61850 no estuvo
disponible hasta hace algunos años atrás debido a que las comunicaciones no estuvieron
disponibles para soportar las aplicaciones que en ese entonces se requerían. Por lo tanto
uno de los principales habilitadores para que se logre la automatización de subestaciones
fue reconocer que el cableado extenso entre los equipos en patio de llaves y la sala de
control se podría eliminar con la aplicación de la tecnología Ethernet. Hoy en día el
desarrollo de las comunicaciones hace posible que las aplicaciones hasta ese entonces
soñadas se efectúen ahora.
17
La arquitectura por años utilizada en la automatización de Subestaciones estuvo
enmarcada por la utilización de redes seriales RS232 y RS485 así como por una gran
cantidad de cableado del patio de llaves hacia los relés de protección, medidores, RTUs ,
registradores de falla , etc. La Figura 2.1 indica la arquitectura entonces utilizada.
SCADA�&HMI
IEC 101, Modbus,DNPvia RS232/485
Relays, meters, RTUs, recorders, ...
Lots o' copper wire! HMIe
_._. ....... .¡52---------------·>-
Figura 2.1 : Arquitectura de automatización de Subestaciones tradicional
Luego con el avance de la tecnología digital los relés, medidores y RTUs se
transformaron en IEDs y la red Ethernet se convirtió en la red escogida por muchos a fin
de lograr la Automatización de la Subestaciones. La Figura 2.2 indica la arquitectura
actualmente utilizada. Como principal característica se nota los esfuerzos necesarios
para reducir el cableado.
SCADA ��1'V �HMI /
..... ,,ttit:{��-:,,_ .. ,�:- •.
IP Protocols:
IEC 104, DNP, Modbus
IED
Modem,SDH, m icrowave, ...
.__ _____ �
IED
Figura 2.2 : Arquitectura de automatización actual
18
Otro de los esfuerzos de los ingenieros de automatización fue buscar un protocolo de
comunicación único debido a los diferentes que existían en el mundo. En la Figura 2.3 se
presenta los principales protocolos de comunicación existentes en el mundo
Figura 2.3 : Protocolos de Comunicación alrededor del mundo
El objetivo buscado por años ha sido definir una infraestructura de comunicaciones que
permita una peñecta integración de los IEDs con independencia del fabricante. La
definición de un Bus de estación ha sido por años el centro de estandarización mundial.
También la búsqueda,continua en la reducción del cableado tanto del tipo eléctrico como
de comunicación así como el sacar las mayores funcionalidades a los IEDs son parte de
los innumerables desvelos de los ingenieros de Automatización. La respuesta a todos
esos requerimientos fue plasmada en la norma IEC 61850 tal como lo indica la Figura
2.4.
SCADA, Fault
recordar ToSubX ---
Merging unit #1
StationBus 1000LX 9
-¡�i\
SubstationY
ProcessBus 100FX
Merging unit #2 SWitchyard
e
,-.---...--.. )-A
Figura 2.4: Arquitectura de Automatización bajo la norma IEC 61850
En el Anexo A se presentan algunas arquitecturas tradicionales en IEC 61850.
19
2.2. Descripción
En los años 90 tanto la EPRI como la IEEE hicieron los primeros esfuerzos en lograr una
Utility Communications Arquitecture (UCA) . Se centraron primero en los protocolos de
comunicación entre Centros de Control el concluyo con las especificaciones ICCP mas
tarde adaptadas por el IEC como la 61850 TASE.2.
La siguiente fase del UCA llamada UCA 2.0 comenzó en el año 1994 y se enfoco en el
"Bus de datos de la Subestación". En el año 1996 el Comité Técnico 57 del IEC comenzó
a trabajar en la Norma IEC 61850 también enfocado al "Bus de datos de la Subestación".
En el año 1997 los 02 grupos de trabajo EPRI/IEEE e IEC unieron esfuerzos en la
definición de un estándar internacional que combine el trabajo de ambos grupos. El
resultado fue la norma IEC 61850 actual. En la Figura 2.5 se presenta el proceso de
desarrollo de la Norma IEC 61850
1994
EPRI
IEEE, USI
1996
/EC TC57
Figura 2.5 : Proceso de desarrollo de la Norma IEC 61850
20
IEC 61850 es un nivel superior al UCA 2.0 . Contiene muchas de las especificaciones del
UCA 2.0 más características adicionales . IEC 61850 fue publicada como estándar
internacional el año 2003 . En el Anexo D se presentan un resumen de las normas
constituyentes de la IEC 61850 las cuales son las siguientes:
IEC 61850-1 , Part 1 : lntroduccion and Overview
Presenta una introducción y una visión general de la norma.
IEC 61850-2 , Part 2 : Glosario
Presenta la terminología y definiciones utilizadas en toda la norma.
IEC 61850-3, Part 3: General requeriments
Define requerimientos ambientales para equipos de comunicaciones dentro de una
Subestación. Ofrece un marco completo de pruebas incluyendo EMI (lnteñerencia
Electromagnética), requerimientos de inmunidad y medioambiente .
IEC 61850-4 , Part 4 : System and proyect management
La especificación de esta pertenece a la administración del proyecto y del sistema en lo
relacionado a : Los procesos de ingeniería y herramientas de soporte, El Ciclo de vida de
IEDs, El aseguramiento de la calidad.
IEC 61850-5 , Part 5 : Communications requirements for functions and device
models
Establece el modelo utilizado por el estándar para las funciones y modelos de equipos
utilizados por la norma.
IEC 61850-6 , Part 6 : Configuration description language for communication in
· electrical substation related to IEDs
Especifica las características del lenguaje de configuración de los IEDs que utilizan esta
norma. Este lenguaje es llamado Subestation Configuration Description Language (SCL).
IEC 61850-7-1 , Part 7-1 : Basic Communication structure for substation and feeders
equipment - Principies and models
Esta parte del IEC 61850 provee una vista general de la arquitectura de comunicaciones
e interacciones entre equipos tales como Reles de protección, interruptores,
transformadores, etc.
21
IEC 61850-7-2, Part 7-2: Basic Communication structure for substation and feeders
equipment - Abstract communication service interface (ACSI)
Esta parte del IEC 61850 define el Abstract Communication Service Interface (ACSI) para
usar dentro de la Subastación que requiere cooperación en tiempo real de IEDs.
IEC 61850-7-3, Part 7-3: Basic Communication structure for substation and feeders
equipment - Common Data Clases
Define los tipos de atributos y clases relativos a las aplicaciones utilizadas en
subestaciones.
IEC 61850-7-4, Part 7-4: Basic Communication structure for substation and feeders
equipment - Compatible logical node classes and data classes
Esta parte especifica los nombres de los Nodos Lógicos y Datos así como la relación
entre los mismos.
IEC 61850-7-410 , Part 7-410 : Hydroelectric Power Plants - Communication for
monitoring and control
Especifica los nombres de los Nodos Lógicos y Datos no mencionados en la IEC 61850-
7-4.
IEC 61850-8-1 , P�rt 8-1 : Specific Communication Service Mapping (SCMS) -
Mappings to MMS (ISO 9501 and ISO 9506-2) and ISOffEC 8802-3
Esta parte especifica un método de intercambio de datos critica y no critica atraves de
redes LAN para efectuar el Mapping de ACSI a MMS en muestras del tipo Ethernet.
IEC 61850-9-1 , Part 9-1 : Specific Communication Service Mapping (SCMS) -
Sampled Values over serial unidirectional multidrop point to point link
Esta parte aplica a equipos electrónicos que sirven de interface entre los transformadores
de corriente y tensión y los equipos de medición y retes de protección. Estos equipos son
llamados " Merging Units"
22
IEC 61850-9-2 , Part 9-2 : Specific Communication Service Mapping (SCMS) -
Sampled Values over 1S0/IEC 8802-3
Esta parte aplica al envió sobre Ethernet de las señales de los transformadores de
corriente y tensión electrónicos.
IEC 61850-10, Part 10: Conformance Testing
Especifica los procesos de prueba que deben cumplir los IEDs a fin de cumplir con la
norma IEC 61850.
En la figura 2.6 se presenta un resumen de estructura de la Norma IEC 61850
Parte 1
Parte 2
Parte 3
Parte 4
Parte 5
Parte 6
Parte 10
Parte 8
tmpacto en la ve11lficación
Figura 2.6 : Estructura del Estándar IEC 61850
El IEC 61850 provee interoperabilidad entre dispositivos electrónicos inteligentes (IED's)
para las aplicaciones de protecciones, monitoreo, medición, control y automatización en
las subestaciones. La funcionalidad de la automatización está dada por las tareas (de los
IED's) y no por el IEC 61850. De esta forma, el sistema de comunicaciones interno de la
subestación (Red LAN) es la red troncal de la automatización y el IEC 61850 es una
herramienta para el de diseño de la automatización. Este protocolo utiliza modelos
orientados a objetos para la descripción de los dispositivos y su funcionalidad y la
selección de la tecnología de comunicaciones está basada en las especificaciones de
23
usuario, lo cual constituye una las características más robustas del IEC 61850. La
funcionalidad de las interconexiones debe describirse también y se hace mediante la
ayuda del software "SCL" ("Substation Configuration description Language" herramienta
basada en lenguaje de marcaciones extensibles XML).
2.3. Características
lnteroperabilidad
El IEC 61850 requiere que cualquier IED que cumpla su norma provea un SCL
(generalmente un archivo) con la descripción de sus capacidades. El Nombre de tal
archivo es con extensión ICD (IED configuration description). Éste puede suministrarse
en CD o dentro de su misma unidad. Es importante que este archivo pueda ser leído por
otros dispositivos que cumplan la norma y tengan la herramienta. Además debe poseer
una base de datos para el integrador.
El resultado del proceso de diseño para IEC 61850 puede almacenarse en un archivo
seo que contiene las comunicaciones lógicas entre IED's dentro de las subredes y los
switches dentro de las subredes. Las figuras 2. 7 especifican todo el proceso de
interoperabilidad.
111 ICD
File
endor
1
ICD
File
endor
2
SCD
File
Figura 2.7: lnteroperabilidad entre archivos ICD de diferentes fabricantes de IEDs
La estructura del Archivo seo es mostrado en la Figura 2.8.
Structure of the SCD-file:
------·- Description:
} Single Line (Structure of the HV-plant); Llnks between HV
plant, LN and IEDs ::==================::::
IEDsection } eonfiguration of one or more
IEDs; Llnks to LN of other IED ::==::=======:======:
} eommunication links between
__ 1E_
o __
} Type of data objects, wich arelncluded In IEDs as lnstances
...._______,
Figura 2.8: Estructura del Archivo seo
La Figura 2.9 muestra el diagrama completo de interoperabilidad entre IEDs
ICD-
• ·
-llSD- .· Fil·
Cor,ifi�¡r.atfon ·,<>of'
Sy,�tem Configariatio�
fdi>I·.
r.;· """ 111 CID-
FIie
System Specification.. Tool
..
Figura 2.9: Diagrama completo de interoperabilidad entre IEDs
Definición de Objetos
24
25
Tradicionalmente para lecturar desde un HMI la información que posee un IED esta es
reconocida por una serie de "Números Mágicos" los cuales representan tipos de datos. El
problema es que el "Contexto de los datos" se pierde y se requiere denodados esfuerzos
de ingeniería para lograr tener la configuración del Mapping de direcciones del HMI hacia
los IEDs.
Ahora con el IEC 61850 la información de un IED es dividida en "Grupos Lógicos" los
cuales a su vez se dividen en Nodos Lógicos . Adicionalmente se tienen Clases de Datos
correspondientes a cada Nodo Lógico. La Figura 2.1 O presenta un diagrama esquemático
del Mapping en IEC 61850
Physical Cevice �network address)
Figura 2.10: Diagrama esquemático del Mapping en IEC 61850
En el Anexo B se presenta la forma de efectuar los procesos de integración de IEDs bajo
la Norma IEC 61850.
26
Comunicación Punto a Punto (GOOSE)
GOOSE es un acrónimo de Generic Object Orintated System Wide Events . Esta
reemplaza el convencional Cableado para que los IEDs intercambien información entre
ellos. En el momento que se detecta un evento (cambio de estado de un Interruptor en un
IED por ejemplo) , el IED usa una comunicación del tipo Multicast para notificar a los
otros IEDs que se encuentran en el mismo BUS que ha ocurrido un evento. La
peñormance del tiempo de envío es exigente, no mas de 4ms es permitido como tiempo
transcurrido entre que el evento ocurra y hasta que este es transmitido a los otros IEDs.
La Figura 2.11 presenta el diagrama esquemático de los mensajes GOOSE entre IEDs
CB Object
CB1 CB2 CB3 CB4
Figura 2.11 : diagrama esquemático de los mensajes GOOSE entre IEDs
El Numero de IEDs, la topología de la red y el tipo de evento generado contribuyen a la
cantidad de datos que será generada después de un evento. Dado que las colisiones son
posibles en una red Ethernet , los mensajes son GOOSE son retransmitidos múltiples
veces por cada IED. Los Switches de 10MB y 100Mb pueden entregar 100 mensajes
GOOSE dentro de 4 milisegundos.
27
Bus de Proceso
Los términos Bus de Proceso y Bus de Estación inicialmente usados por las tempranas
publicaciones del IEC 61850 ahora son historia. Hoy en dfa IEC 61850 no efectúa
precisiones con respecto a· la arquitectura de la Subestación.
Cuando el IEC 61850 inicio planteo una arquitectura de 03 niveles : Bus de estación, Bis
de Bahía y Bus de proceso. El Bus de Estación (IEC 61850 , Parte 8) fue planeado para
la comunicación entre la Estación (PC) y el Nivel de Bahía (IEDs) , El bus de proceso
(IEC 61850, Parte 9) para la comunicación entre el nivel de bahía y el nivel de proceso.
La Figura 2.12 presenta el planteo inicial de la arquitectura por Niveles del IEC 61850.
statlon Level
Bay Level
Procesa Level
Figura 2.12 : Niveles lníciales del IEC 61850
Conforme el proceso de estandarización del IEC 61850 progreso y la armonización con el
UCA era necesario, se decidió que el IEC 61850 no restrinja los limites de las interfaces
de comunicación en los 03 niveles. Por lo tanto se decido que la comunicación Ethernet
(1S0/IEC 8802-3) sea la base de las comunicaciones.
IEC 61850-9-1 e IEC 61850-9-2 son dedicados para especificar los modelos para la
transmisión de las muestras de las formas de onda de los parámetros eléctricos a
monitorear.
IEC 61850-9-1 es unidireccional y es dirigido a utilizarse para una comunicación punto a
punto de las muestras de las formas de onda hacia un IED. El IEC 61850-9-2 es mas
general y está dirigida hacia una comunicación con varios IEDs.
2.4. El Futuro de IEC 61850
28
La edición Nro 2 del Estándar se encuentra actualmente en preparación. Dicha edición
incorpora nuevos requerimientos y nuevas aplicaciones tales como medición de la calidad
de la energía. Tenemos actualmente los siguientes desarrollos futuros de la norma IEC
61850:
IEC 61850 Fuera de la Subestación
- Actualmente se encuentra en desarrollo el estándar que permitirá la comunicación
bajo la norma IEC 61850 de los IEDs de diferentes subestaciones eléctricas.
- Actualmente se encuentra en desarrollo el estándar que permitirá la comunicación
bajo la norma IEC 61850 entre un centro de control y las subestaciones.
IEC 61850 en Centrales de Generación:
Actualmente se encuentra en desarrollo la norma IEC 61850 para Centrales
hidroeléctricas y Centrales Eólicas.
2.5. IEC 61850 y la "Red Inteligente Empresarial"
Actualmente las empresas eléctricas alrededor del mundo se encuentran transformando
su "red electromecánica" de la centuria anterior por la "red Inteligente" constituida por
IEDs y Computadores. Las mismas tecnologías que revolucionaron las computadoras y
las comunicaciones y crearon Internet ahora se encuentran transformando la
infraestructura de las Subestaciones Eléctricas.
Un numero de entidades tales como la EPRI y el Departamento de Energía de los EEUU
(DOE) han planteado iniciativas direccionadas a modernizar la infraestructura de las
empresas eléctricas así tenemos la "EPRl's lntelliGrid" y "DOE's GridWise".
La Figura 2.13 presenta una vista conceptual de los componentes típicos de la
información empresarial de una compañía eléctrica. Dicha infraestructura utiliza una
misma infraestructura para el acceso a la información en todas las áreas de la empresa.
Esta visión requiere una estratégico conocimiento de las necesidades de cada área y las
capacidades de integración de las mismas así como la integración de diversas bases de
datos.
29
Figura 2.13 : Red Inteligente Empresarial
Los habilitadores para que se forme la Red inteligente empresarial son los IEDs y el
protocolo IEC 61850.
2.6. Beneficios Económicos por Implementación del IEC 61850
La implementación de la Automatización de Subestaciones bajo el esquema del IEC
61850 ofrece los siguientes beneficios económicos a la empresa
1.- Ahorro en Costos directos de capital como resultado del monitoreo continuo de los
interruptores y transformadores por el uso de los IEDs. Esto trae como consecuencia un
ahorro por reducir la probabilidad de una falla catastrófica y la vida útil de dichos equipos.
Los mantenimientos usuales y mensuales se ven optimizados pues continuamente las
condiciones de los equipos principales de la subestación se encuentran monitoreadas.
2.- Ahorro por reducción en el tiempo de Análisis de la Falla . Los tiempos de análisis
de la · falla e investigación de sucesos permitirán la restauración inmediata de los
elementos críticos de una Subestación. Ello es posible gracias a las herramientas de
análisis de los IEDs (análisis de eventos, oscilografías y alarmas).
30
3.- Ahorro por el conocimiento preciso de las caracteristicas de sobrecarga de
líneas de transmisión y transformadores . El continuo calculo y monitoreo de las
condiciones dinámicas de los equipos por parte de los IEDs habilita a las empresas
eléctricas a plantear restricciones referentes a la máxima capacidad a transmitir sin
sobrecargar excesivamente los equipos y así evitar deterioro de sus aislamientos.
4.- Ahorro por el conocimiento oportuno y preciso de las alarmas asociadas a los
IEDs. El procesamiento inteligente de las alarmas de los IEDs de una Subestación hace
que se tomen las decisiones mas acertadas referentes al envio del personal a la
Subestación con los consiguientes gastos que esto implica.
5.- Ahorro por el conocimiento oportuno y preciso de los valores del Factor de
potencia y Tensión . El conocimiento del factor de potencia durante las horas punta y
fuera punta habilita a la empresa eléctrica a reducir las pérdidas eléctricas y a tener un
mejor conocimiento a la hora de efectuar transferencias de carga.
Los anteriores puntos fueron cuantificados por KEMA CONSULTING tomando como
ejemplo una empresa eléctrica americana . Dichos resultados son mostrados en la Tabla
2.1.
Tabla2.1 : Ahorro anual por implementación del IEC 61850 (Fuente KEMA
CONSULTING)
FUNCION EQUIPO DE UNA MONTO ESTIMADO DE
SUBESTACION AHORRO ANUAL
Ahorro por el Monitoreo Transformador de 500kV $ 44028
continuo de Transformador de 230kV $22014
Interruptores y Interruptor de 500kV $9638
transformadores. Interruptor de 230kV $22286
Ahorro por Mejora en el Línea en 500kV $2500
tiempo de Análisis de la Línea en 230kV $1600
falla. Circuito de Distribución $300
Ahorro por el Transformador de 500kV Se difiere $4 Millones en
conocimiento preciso de el lapso de 3 años
las características de Transformador de 230kV Se difiere $3 Millones en
sobrecarga de líneas de el lapso de 3 años
transmisión y
transformadores.
Ahorro por el Toda la Subestación $1500
conocimiento preciso de
las alarmas asociadas a
los IEDs.
Ahorro por el Circuitos de Distribución $13029
conocimiento oportuno y
preciso de los valores
del Factor de potencia y
Tensión.
31
CAPÍTULO 111
APLICACIÓNES ALREDEDOR DEL MUNDO DEL IEC 61850
3.1 Introducción
Hasta diciembre del año 2005 aproximadamente se han efectuado aproximadamente 11 O
Sistemas de Automatización de Subestaciones basados en el IEC 61850 . 70 de ellos ya
se encuentran en operación.
3.2 Aplicaciones Internacionales
SUIZA
ABB Suiza realizo la primera implementación mundial del IEC 61850 en Noviembre del
año 2004 . Hay sin embargo otros importantes proyectos iniciados incluyendo la
modernización dºe la Subestación Laufenburg en 380kV . Esta Subestación es un
importante nodo del Sistema Interconectado Europeo. El proyecto Laufenburg comenzó
en Diciembre del año 2004 y el punto central es lograr la modernización de 17 bahías
para fines del año 2006 utilizando el IEC 61850.
ALEMANIA
Alemania posee el mas grande numero de implementaciones operativas y cuenta con
muchas otras en proceso de pruebas. El punto de vista de un Fabricante Alemán es que
el Estándar IEC 61850 comience a ser el estándar único para comunicación de
subestaciones en el mundo. Esta opinión refleja el esfuerzo gastado para mejorar
. equipos y para definir configuración estandarizada. . Conforme se incremente el uso del
IEC61850 , otros protocolos de comunicación gradualmente desaparecerán. Otro factor
importante es que en 2/3 partes de los caso en donde se usa el IEC 61850 el nivel de
tensión es superior a los 100 kV lo cual indica la importancia de su utilización.
33
ITALIA
Tema, EL Operador del Sistema Eléctrico Italiano, ha desarrollado una serie de
especificaciones para el uso del IEC61850 como estándar dentro de las Subestaciones.
El nombre del proyecto llamado SICAS es un esfuerzo por crear un estándar integrado de
· comunicaciones que sirva a las necesidades de TERNA mientras al mismo tiempo ,
atraves del uso del IEC 61850, mantiene la autonomía del vendedor. Dicho requerimiento
especifica que los diseños de cada vendedor sean intercambiables en el Nivel de Bahía.
Por lo tanto, mientras el diseño de cada bahía podría diferir en aspectos, la comunicación
externa seria la misma.
ESPAÑA
IBERDROLA , una empresa eléctrica Española, ha diseñado un SAS (Sistema de
Automatización de Subestaciones) basado en el IEC 61850. Este proyecto es llamado
"Ciudad Universitaria" . El proyecto es diseñado para comprobar la efectividad del IEC
61850 y también comprobar la interoperabilidad entre IEDs.
Para lberdrola , el IEC 61850 abre nuevas posibilidades para la integración y uso de
Sistemas de Protección y Control. Además lberdrola considera dos características
importantes del protocolo que deben ser probadas:
lnteroperatibilidad : Equipos de protección y Control de diferentes fabricantes deberían
trabajar consistentemente como indica la teoría.
Herramientas de Ingeniería: Los beneficios de trabajos de ingeniería deberían
corresponder a la teoría.
La "Ciudad Universitaria" comenzó en el año 2004 con la creación de grupos de trabajo y
la participación de lberinco quien al igual que lberdrola, se familiarizo con el IEC 61850 y
. tuvo extensiva experiencia en SAS. Después de algún retardo en el proceso de
construcción de la Subestación , otra Subestación en España escogió introducir el IEC
61850.
Uno de las conclusiones del proyecto fue efectuar muchas consultas técnicas al grupo de
desarrollo del IEC 61850.
CONCLUSIONES
Las nuevas tendencias en la automatización de subestaciones de potencia son las
siguientes:
1. La utilización de IEDs con tecnología digitales como medidores, relés de protección y
Unidades Terminales Remotas (UTR) que ahora tienen nuevas características y
funcionalidades, una de ellas es la capacidad de "hablar un lenguaje " (protocolo de
comunicación) a fin de entregar toda la información valiosa que disponen.
2. La Utilización de la tecnología Ethernet en Fibra Óptica en Subestaciones.
3. El establecimiento de criterios de seguridad en la información procesada en las
subestaciones ( tales como la norma NERC indicada en 1.3.5).
4. Utilización de la Norma IEC 61850 en el ambiente de la Subastación la cual a su vez
trae los siguientes beneficios:
o lnteroperabilidad, IEDs de diferentes fabricantes pueden intercambiar y usar
información sobre medios de comunicación comunes (la funcionalidad en los
diferentes disp�sitivos no es necesariamente la misma).
o La ingeniería y configuración de datos es transportable entre herramientas de
diferentes fabricantes.
o Reduce la ingeniería y la configuración
o Capacidades de comunicación, adquisición de datos, y control son incluidas
directamente en los equipos primarios.
o Libre asignación de funciones en sistemas de configuraciones centralizadas odescentralizadas.
o Reducción del cableado convencional.
o Redes LAN en lugar de múltiples cables de cobre seriales en las Subestaciones
Eléctricas.
o Los servicios y las inversiones serán duraderos a pesar de los rápidos cambios
tecnológicos.
o El estándar está diseñado para seguir tanto el progreso en las tecnologías decomunicación, como los requerimientos que envuelven a estos sistemas.
5. Posibilita la creación de la "red inteligent e empresarial" el cual traería muchosbeneficios a las diferentes áreas de la empresa eléctrica.
ANEXO A
ARQUITECTURAS TRADICIONALES BAJO LA NORMA IEC 61850
ANEXOB
PROCESO DE INTEGRACION DE IEDS BAJO LA NORMA IEC 61850
ANEXO A
ARQUITECTURAS TRADICIONALES BAJO LA NORMA IEC 61850
Router
IE e 61850�-x
, Arquitectura de Implementación Mixta
Rmta-
IE C 61850�-x
Arquitectura de lmplementacion con Bus de Proceso
Router-
Cm*ol
Ceder HM
IEC 61850.a-x
IE e 61850-9-x
Arquitectura con un solo Switch
Network control Center
Router switch
HSI
1111!1-- -
____ ...-------1
Ethernet In rlng whh swltches
••••
IEC 61850-9-2 Process bus
Arquitectura en anillo
Englneeñng/ Monltorlng
IEC 61850-8-1 Statlon bus
ANEXOB
PROCESO DE INTEGRACION DE IEDS BAJO LA NORMA IEC 61850
IED1
CB1
O Slctnoro PCMerTrannls&btl & � lll02
IED1 is a multi-function IED and supports the following features:
Protection (Time Over Current, 51) PTOC LN
Protection related (Autoreclosing, 79) RREC LN
Monitoñng of CB XCBR LN
Control of CB CSWI LN
Monitoñng of Discomect Switch XSWI LN
Control of Disconnect SWitch
Measurement r,/, A, W, etc)
Metering (Energy)
IED1
CB1
CSWILN
MMXULN
MMTRLN
Loglcal Devlce
Accessing Data Think Windows Explorer
PTOC
RREC
XCBR
CSWI
XSWI
CSWI
MMXU
MMTR
IED1/XCBR
(Time Over Current LN )
(Autorecloser LN )
(Switchgear - Circuit Breaker) <===1 (Control - Circuit Breaker)
(Switchgear - Disconnect)
(Control - Disconnect)
(Measurement Unit)
(Metering)
Accessing Data Tree view
PTOC RREC XCBR
Mocle Beh Health Name Loe EEHealth EEName OperCnt Pos BlkOpen BlkClos ChMotEna CBOpCap POWCap
IED1/XCBR.Pos
(Mode) (Behavior ) (Health) (Name plate) (Local operation) (Externa! equlpment) (Externa! equipment name plate) (Operatlon counter) (Switch positlon)<;::=:J (Block openlng) (Block closing) (Charger motor enabled) (Circuit breaker operating capability) (Point On Wave switching capability)
Mode Beh Health Name Loe
EEHealth EEName OperCnt Pos
ctIVal
IED1/XCBR.Pos.stVal
(Mode) (Behavior ) (Health) (Name plate) (Local operation) (Externa! equipment) (Extemal equipment name plate) (Operalion counter) (Switch posilion)
stV�.,,...--.,, intermediate-state (O) pulseConfig off (1) operTim on (2) q bad-state (3) ... more
Logical Node Groups Group
Oesignator
System Logical Nodes L
Protection f unctions p
Protection related functions R
Supervisory control e
Generic References G
lnterfacing and Archiving 1
Automatic Control A
Metering and Measurement M
Switchgear X
lnstrument Transformer T
Power Transformer y
Further power system equipment z
Sensors s
24
/ POIR PHAR
., ___ ._ _ PSCH Group numueri PTEF D�gnator' PZSU
System Loglcal Nodes L 2 ,1 :,SH Protection functions P 27 ( PTW
PDOP Protection related funcüons R 10 \ ... mcnSupervisoly control e 4 t Generic References G 3 ,,-MMXU lnterfacing and Archiving 1 4 MMTR
MSQI Automatic Control A 4 MHAI
�M_e_terin __
g-and
--Meas
--urem--ent
---+---M-----,1---7-<.__
--7' ��
DirKlionel element Harmonlc restralnt PR>IKtionSchem, Trantllnt Earth Fault Z.ro spNd or underspNdOiallnceplOlldlon Volta per Hz 191ay UndlrvoltageDnctionll over pawer
Measurlng (Mlasurand unM) Melamg Seql,enceandlmbalance Hannonica and lnter-harmonlcs DifflNnlill MN1urement1
Switchgear X 2 -. 1-"r------------1---...;;...--------+-----+----"�
lnstrument Transfonner TY
24 �
Power Transformer � �F_u_rther
--power
--system
---eq-w-·
pm-
eot____,1-- -z-____,1---
1-,----1
1 xcBR Cirait Br111k•
J __ .....;. __ ;;...__....;....;....._.,... ______ ---1L XSWI CirC1it Switch
Sensors S 3 �------------______________ ..., ___ -t.
86 1
'
Data Classes Number pe - Current of a non three phase drcult
System information 13
/4 ................................ ,.2. ... ,
g - Angle between pilase vottage and current Physical device information 11 / Anln -Analogue Input used for ganenc 1/0
ChAnVal - Array of analogue channel numbers and Measurands 66'-. actual values at a certaln time (Ume lag)
Metered values 14 "' ClrcA - Meastred drculatlng current In a transformer
" parallellng appllcatlon
Controllable Data 36 CtlV -Voltage on sec:ondary of transfonner as used for voltage control.
Status information 85 Den - Denslty of gas or other lnsulaUng Medlum
Settings 130 DQOSeq -Dlreet. quadrature. and zero axis quantlty ECC - Thls Is the measured current through a Petersen
355 Col! In neutral compensated netWOlks. FDkm - The dlstance to a fault In kllometres FDOhm - The dlstance to a fault In Ohms HaRmaA - Current Harmonlc RMS (un-normallzed THD) for A. B. C. N HaRmaV - Vollaga Harmonlc RMS (un-nonnallzed THD) for AB, AN. BC. BN, CA. CN, NG HaTdA - Curren! Total Harmonlc Dlstortlon HaTdV - Voltage Total Hannonlc DlstorUon More .....
ANEXOC
EQUIPOS DE COMUNICACIONES QUE CUMPLEN CON LA NORMA IEC 61850
RuggedCom "Industrial Strength Networks"
Product Ov_erview
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RuggedCom Products
• Exceeds IEC 61850-3 EMI lmmunity• Designed for IEC 61850-8-1 Station Bus• Zero-Packet-Loss TM for I EC 61850-9-2 Process Bus• Supports up to Gigabit Speeds for Process Bus Applications• Use RuggedServer™ to Connect Legacy Serial Devices to
the Station Bus LAN
• Plus all Products are RuggedRatedTM for Operation in HarshEnvironments
RuggedCom Products are Designed for Mission Critical Systems where
High Reliability and Uptime are of Paramount lmportance
RuggedRatedTM Technology
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� Rated for reliable ,operation in harsh electrical environments
- Electric utility substations: Meets IEEE 1613, Exceeds IEC 61850-3
� Rated for operation over a wide temperature range
- -40ºC to +85ºC (+185ºF)
- Passive cooling - no fans
- CSA/UL 60950 safety approval to +85ºC
� Rated for high availability
- lntegrated single and dual redundant power supplies
- 24VDC (12VDC), 48VDC, or 88-300VDC/85-264VAC
- Dual power supplies can be powered from different sources
� Rated for substation installations
- 18 or 20 gauge galvanized steel enclosure for durability
- heavy duty 19" rack or din rail mount
- industrial terminal blocks for power and 1/0 connections
� 5-Year Warran_ty
Other RuggedRated™ Features
.; �SJi .... ,.. . .. ·';;ti•it ....•. - '"",e�; ���iiíli::(�! , 'ÍI. fi . .fa°l.'ó!',7}.i)í ,'.; '·· ..,]� ¡-. �·�o �·':1 • . . ·- ..•.•. ········�··· 1· ...: H,
1� �': �i ,.. --��:.u .,0.'_.---·-:"�'::.c.�-
» High MTBF of > 500,000hrs
» Network Availability of > 99.999º/o
» No Moving Parts far lncreased Reliability
» IP66/67 Rated Products (Waterproof)
» Shock and Vibration Resistant
» High Humidity Range (> 95%)
RuggedCom · ...
The Communications Backbone far IEC 61850
• The Worldwide Leader in Substation Hardened Ethernet
• Largest lnstalled Base of IEC 61850 Applications Worldwide
• Most Complete Line of Hardened Ethernet Products:
Routers, Switches, Serial Servers, Media Converters
• Preferred Supplier of Substation Ethernet Devices by Majar OEMs
(Siemens, ABB, Areva, SEL, GE ... )
•l I F R O S T & S U L L I V A N
Excellence in Technology Award
Recipient of Frost and Sullivan 2006 "Excellence in Technology" Award far Substation Hardened Ethernet Switches.
Industrial Power Supply
... P0\',11:R 5UPPL Y 1 _., l'()Wí � :,111'Pl � · �'
íhll";Aff-. H�:.>Jl�OfO
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½-t+-11-'
Power Supply 1
» Fully integrated power supply (no externa! adaptors)
» Universal high-voltage range:88-300VDC or 85-264VAC
» Popular low voltage DC ranges:24VDC, 48VDC
» CSA/UL 60950 safety approved to +85ºC
Power Supply 2 (Optional)
» Dual redundant power supply option
» Parallel load sharing with true N+1 redundancy
» Can be powered from different sources:
-e.g. PS 1 from 11 OVAC and PS 2 from 48VDC
-e.g. PS 1 from 125VDC and PS 2 from 220VAC
-e.g. PS 1 24VDC and PS 2 from 125VDC
-Any combination!
Port unblocks and allows new path
' New .., � 4 ,_ Network Traffic -=
, Path(s) '4
Technology
Enhanced Rapid Spanning Tree Protocol (eRSTP1M)
� Enhanced IEEE 802.1w Rapid Spanning Tree Protocol
� High-Speed Fault Tolerant Ring Architectures
� Fast Fault Recovery: < Sms/hop fault recovery
� Large Rings Configurations: up to 80 switches
� Compatible with RSTP (IEEE 802.1w)
eRSTP™ Fastest Network Fault Recovery in the lndustry . . .<5mslhop vs. 300ms of competitors
20K
•
•
Test Setup
ROOT
RING
15-Switches
SmartBlta 800 Natwork Teatlng Syatem
•
•
16K
Test Results
1 !2 25.7 2,3 23.8 3!4 21.8 4,5 20.3 5,6 18.3
6i1 16.71 7,8 11.9 8,9 o.o
9!10 5.9
10! 11 13.4
11J2 14.1 12J3 16.3, 13,14 18.0 14,15 19.8 15,1 20.9
eRSTP™ Peñormance Example:
For a network comprised of 15 RuggedSwitch Ethernet switches (i.e. S1 - S15) in a ring topology we can expect better than 5ms/hop fault recovery performance:
Expected worst case Fault Recovery time:
<75ms
Actual testing performed on RuggedSwitch switches with eRSTP technology using an industry standard SmartBits network analyzer revealed:
Actual worst case Fault Recovery time:
<26ms
eRSTP™ actual performance is 2x better than expected!
IR(OS1
Rugged Operating System™
Rugged Operating System TM
Rugged Operating System (RQSTM )
}> Zero Collisions: IEEE 802.3x Full Duplex Operation
}> Priority Queuing: IEEE 802.1 p for high priority real-time control
}> VLAN: IEEE 802.1 q for isolating real-time traffic
}> Enhanced IEEE 802.1w Rapid Spanning Tree for fast fault recovery
}> IGMP Snooping for multicast filtering and management
}> Network management: including SNMP, RMON , Port Mirroring
}> Rich set of diagnostic tools
}> Common firmware across all managed switches
}> Simple firmware upgrade as new features become available
Ful/y Managed Switch Designed for Real-Time Control
RuggedSwitch TM RS900G
Industrial/y Hardened - Gigabit Managed Ethernet Switch
Dual Gigabit Ports: • Fiber Optical (MMF/SMF)• Pluggable Optics (SFP)• se, ST, LC and MTRJ• Bi-directional (single strand)• Distances up to 70km
Fast Ethernet Ports: • 8 - Fast Ethernet Ports
(10/1 00BaseTX)
lntegrated Power Supply • Universal high-voltage range: __ ,_....,.
88-300VDC or 85 - 264VAC• Popular low voltage DC ranges:
24VDC, 48VDC • Dual Redundant (Optional)• Parallel Load Sharing
Failsafe Output Relay • Form-C contact output• 1A@30VDC
> Gigabit - Dual fiber optical 1 000BaseXports allow for high-speed Gigabit ·backbone (up to 70km).
> RuggedRated™ - lndustrially Hardened
- EMI lmmunity (IEC 61850-3, IEEE 1613),
- Operating Temperature (-40 to +85ºC)
> ROS™ (Rugged Operating System)- Advanced Layer 2 and 3 Network
Management
> eRSTP™ for high speed {<5ms) networkfault recovery and redundancy
> Port rate limiting (128, 256, 512, 4000,8000 kbps) for network traffic management
> Hazardous Location Certification:- Class 1 Division 2
The RuggedSwitch TM RSG2100
"Modularity plus Gigabit Ethernet"
)- Modularity- 3 Gigabit Ports, .16 Fast Ethernet Ports (virtually any mix of fiber or copper desired)
)- RuggedRated™ "lndustrially Hardened": IEC 61850-3, IEEE 1613, (-40 to +85ºC)
)- lntegrated Dual Redundant Power Supplies 24Vdc, 48Vdc, or (88 - 300Vdc / 85 - 264Vac)
)- Zero-Packet-Loss TM Technology for immunity to high levels of EMI
)- ROS™ (Rugged Operating System) Advanced Layer 2 and 3 Management
)- eRSTP™ for high speed (<5ms) network fault recovery and redundancy
)- Port rate limiting (128, 256, 512, 4000, 8000 kbps) for network traffic management
Gigabit Ports: • up to 3 Gigabit Ethernet Ports• 10/100/1000 TX RJ45• 1 000SX Multimode• 1 000LX Singlemode• Pluggable Optics (SFP)• se, ST, LC and MTRJ
Mounting Options • Panel/Din Rail• 19" Rack Mount
The RuggedSwitch TM RSG2100
3 Gigabit Ports
Modularity (8x2)
Fast Ethernet Ports: • up to 16 Fast Ethernet Ports• virtually any mix of fiber or copper desired• 10/1 00TX RJ45• 1 0FL Multi- and Singlemode• 1 00FX Multi- an� Singlemode
lntegrated Power Supply • Universal high-voltage range:
88-300VDC or 85 - 264VAC• Popular low voltage DC ranges:
24VDC, 48VDC • Dual Redundant (Optional)• Parallel Load Sharing
Failsafe Output Relay
• Form-C contact output• 1A@30VDC
' Modular HMI: • Front or Rear Mount
The RuggedSwitch TM RSG2200
"9 Port Modular Managed Gigabit Ethernet Switch"
� Modularity - 9 Gigabit Ports (virtually any mix of fiber or copper desired)
� RuggedRated™ "lndustrially Hardened": IEC 61850-3, IEEE 1613, (-40 to +85ºC)
� Zero-Packet-Loss ™ Technology for immunity to high levels of EMI
� lntegrated Dual Redundant Power Supplies 24Vdc, 48Vdc, or (88 - 300Vdc / 85 - 264Vac)
� ROS™ (Rugged Operating System) Advanced Layer 2 and 3 Management
� eRSTP™ for high speed (<5ms) network fault recovery and redundancy
� Port rate limiting (128, 256, 512, 4000, 8000 kbps) for network traffic management
Gigabit Ports: • up to 3 Gigabit Ethernet Ports• 10/100/1000 TX RJ45• 1000SX Multimode• 1 OOOLX Singlemode• Pluggable Optics (SFP)• se, ST, LC and MTRJ
Mounting Options • Panel/Din Rail• 19" Rack Mount
The RuggedSwitch TM RSG2200
9 Gigabit Ports
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Modularity: • 5 available slots• up to 9 ports
lntegrated Power Supply • Universal high-voltage range:
88-300VDC or 85 - 264VAC• Popular low voltage DC ranges:
24VDC, 48VDC • Dual Redundant (Optional)• Parallel Load Sharing
Failsafe Output Relay • Form-C contact output• 1A@30VDC
Modular HMI: • Front or Rear Mount
RSG2200/2100 Mounting
Front Mounting Options
HMI
Power
AII communications ports out the front, power port from the rear
Rear Mounting
HMI
• 1 Power
Both power and communications ports from the rear, HMI port from front
HMI
Power 1 •
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RSG2200/2100 Mounting
DIN Rail / Panel Mount
Communication Porta
Options
The RuggedSwitch TM RS969
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"The World's First IP65/IP67 Rated, Ful/y Managed, Industrial Ethernet Switch with Gigabit"
)- Waterproof: IP65 (Water Jets) and IP67 (lmmersion)
> Industrial Operating Temperature: -40 to +85C -
)- High lmmunity to EMI: Meets or exceeds IEC 61850-3, IEEE 1613, NEMA TS-2 and more ...
)- lntegrated Power Supplies: Low and high voltage ranges with true (N+1) redundancy option
» High Speed Fault Recovery: eRSTP™ delivers < Sms per hop fault recovery performance
» Fully Managed: ROS™ delivers advanced networking and management features
)- Gigabit: 2-Gigabit fiber optical waterproof ports for high-bandwidth applications
Fast Ethernet Ports: • 8 - Fast Ethernet Ports (10/100BaseTX)• M 12 Connectors• High EMI immunity• Transient and Surge protected
Water-proof Enclosure • 1 P65 Rated (Water-Jet)• IP67 Rated (lmmersed)• DIN Rail or Flush Mount•Aluminum
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Fiber Optical Gigabit Ethernet Ports • 2 - Fiber Optical Gigabit Ethernet
Ports (1 000BaseX) • Fiber Optical (up to 25km)• WateliflJrésf:eevms•wJireril,-lilBt im .1:.1se.
RS969 (M12 Connectors)
LEO lndicators • Link Activity per port• Power and Alarm
�
Console Port: • RS232 programming port
Failsafe Output Relay • Form-C contact output• 1A@30VDC
Power Supply • Universal high-voltage range:
88-300VDC or 85 - 264VAC• Popular low voltage DC ranges:
24VDC, 48VDC • M12 Connector
RS969 (RJ45 Connectors)
Fast Ethernet Ports: • 8 - Fast Ethernet Ports (1011 00Base TX)• IP67 Rated RJ45 Connectors• High EMI immunity• Transient and Surge protected
Water-proof Enclosure - � 1
• IP65 Rated (Water-Jet)• IP67 Rated (lmmersed)• DIN Rail or Flush Mount•Aluminum
LEO lndicators • Link Activity per port• Power and Alarm
Fiber Optical Gigabit Ethernet Ports • 2 - Fiber Optical Gigabit EthernetPorts (1 000BaseX)• Fiber Optical (up to 25km)• Waterproof covers when not in use
Console Port: • RS232 programming port
Failsafe Output Relay • Form-C contact output• 1A@30VDC
Power Supply • Universal high-voltage range:
88-300VDC or 85 - 264VAC• Popular low voltage DC ranges:
24VDC, 48VDC • M23 Connector• Dual-Redundant (option)• Para/le/ Load Sharing• Can be different sources!
The RuggedRouter™ RX1000
"Industrial/y Hardened Cyber Security Appliance"
> lntegrated Router/FirewallNPN
> Wide Operating Temperature Range: -40 to +85C
> _High lmmunity to EMI: Meets or exceeds IEC 61850-3, IEEE 1613, NEMA TS-2 and more ...
> lntegrated Power Supplies: Low and high voltage ranges with true (N+1) redundancy option
> RuggedRated™ for Harsh Environments
> Modular: Various Types and Configuration of Interface Ports
> 5 Year Warrantee
Multiple Ethernet Ports: • Quad 10/100 Mbps• Fiber or Copper• LC, ST, MTRJ, se
V.90 Modem (Optional)• 56 kbps
RX1000 Physical Features
Multiple WAN ports • Quad T1/E1• Dual DSL• Dual DOS 56164kbps Activity
Modular HMI:
GPS/IRIG Ports • Built-in GPS, Antenna Input• Multiple IRIG-8 Outputs• Manchester, AM, Baseband,
IRIG-8 Types
• Front or Rear Mount
I Mounting Options • Panel/Din Rail• 19" Rack Mount
lntegrated Power Supply • Universal high-voltage range:
88-300VDC or 85 - 264VAC• Popular low voltage DC ranges:
24VDC, 48VDC • Dual Redundant (Optional)• Parallel Load Sharing
' Failsafe Output Relay • Form-C contact output• 1A@30VDC
RX1000 Physical Features
Enclosure • IP40• 18 AWG Galvanizad Steel
Operating Temperature • -40C to +85C
\• No Fans
,I
EMI lmmunity • Meets IEEE 1613 (electric power substations)• Exceeds IEC 61850-3 (electric utility substations)• Exceeds IEEE 61800-3 (variable speed drive system)• Exceeds IEC 61000-6-2 (generic industrial environment)• Exceeds NEMA TS-2 (traffic control equipment)
Network Conflguratlon
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RX1000 Key Router Features
Security Appliance Functions
> lntegrated Router/FirewallNPN
> Stateful Firewall with NAT
> Full lPSec Virtual Private Networking
> VPN with 3DES, DES, AES
> IDS (coming soon)
Protocols
> WAN: Frame Relay, PPP, PAP, CHAP Authentication, PPPoE (coming soon)
> IP: Routing , RIP/RIPII, OSPF, DHCP Agent
> Traffic shaping and policing
Management Tools
> Web Based GUI, SSH, CU (command line interface)
> SNMP v2/v3
> Remate Syslog
> Rich set of diagnostics with logging and alarming
» Highly lntegrated Device
- 4 isolated serial ports, a 4-port Managed EthernetSwitch (fiber and copper options), V.90 Modem
.
» Multifunctional Operation
- serial-to-ethernet, remote access server, and routerfunctionality
» Managed Ethernet Switch
- advanced networking features for fault-tolerantnetworks suitable for real-time control
» Advanced Serial Functionality
- supports Modbus and DNP 3.0 protocols- serial encapsulation; COM port redirection with serial IP
RuggedServer™ RS400
Serial to Ethernet
"Industrial/y Hardened Serial Device
Server"
» RuggedRated™ for Harsh Environments
- Serial ports have 2kV of galvanic isolation to protectagainst ground potential rise during ground faults
)- lntegrated Power Supplies
- Low and high voltage ranges
» Wide Operating Temperature Range
- -40 to +85C
» High lmmunity to EMI
- Meets or exceeds IEC 61850-3, IEEE 1613, NEMA TS-2IEC 61000-6-2, IEC 61800-3
Serial Ports
RuggedServer™ RS400
Serial to Ethernet • 4 - RS485/RS232 Ports
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Mounting Options • Panel/Din Rail• 19" Rack Mount
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88-300VDC or 85 - 264VAC• Popular low voltage DC ranges:
24VDC, 48VDC
�
• 4-Port Ethernet Switch• Fiber & Copper Ports
'
lntegrated V.90 Modem • 56 kbps
Failsafe Output Relay • (220 VDC / 250 VAC)
ANEXOD
RESUMEN DE NORMAS IEC 61850
TECHNICAL
REPORT
IEC
TR 61850-1
First edition
2003-04
Communication networks and systems in substations -
Part 1: lntroduction and overview
Réseaux et systemes de communication dans les postes -
Partie 1: lntroduction et vue d'ensemble
© IEC 2003 - Copyright - all rights reserved
No part of lhis publicalion may be reproduced or utlllzed In any form or by any means, electronic or mechanical, including photocopying and microfilm, without permission in wriling from the publisher.
lntemalional Electrotechnical Commission, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Switzerland
Telephone: +41 22 919 02 11 Telefax: +41 22 919 03 00 E-mail: inmail@iec.ch Web: www.iec.ch
Commission Eleclrotechnique lnlernalionale lnlernational Eleclrolechnical Comm ission Me>K,qyH8POAH8R 3neKTporeXHM�eCK8R KOMMCCMR
PRICE CODE W
For price, see curren/ catalogue
-2- TR 61850-1 © IEC:2003(E)
CONTENTS
FOREWORD .......................................................................................................................... 4
1 Scope ......................... : .................................................................................................... 6
2 Reference documents ...................................................................................................... 6
3 Terms, definitions and abbreviations ................................................................................ 7
3.1 Terms and definitions ............................................................................................. 7
3.2 Abbreviated terms .................................................................................................. 9
4 Objectives ........................................................................................................................ 9
5 History ............................................................................................................................ 11
6 Approach to the elaboration of an applicable standard .................................................... 12
6.1 General ................................................................................................................. 12
6.2 Functions and logical nodes .................................................................................. 12
6.3 Substation topologies ............................................................................................ 16
6.4 Dynamic scenarios ................................................................................................ 17
6.5 Requirements for a physical communication system .............................................. 17
7 How to cope with fast innovation of communication technology ....................................... 18
7 .1 lndependence of communication from application .................................................. 18
7 .2 Data modelling and services .................................................................................. 19
8 General system aspects .................................................................................................. 20
8.1 Motivation .............................................................................................................. 20
8.2 Engineering-tools and parameters ......................................................................... 20
8.3 Substation automation system configuration language ........................................... 21
8.4 Quality and life-cycle management ........................................................................ 22
8.5 General requirements ............................................................................................ 22
9 Conformance testing ....................................................................................................... 23
1 O Structure and contents of the standard series ................................................................. 23
Annex A (informative) Types of substations and communication bus structures .................... 26
Annex B (informative) Documents which have been conside,ed in the IEC 61850 series ............................................................................................................................. 36
Figure 1 - Logical interfaces of an SAS ................................................................................. 11
Figure 2 - Interface model of a substation automation system .............................................. 13
Figure 3 - Relationship between functions, logical nodes, and physical nodes (examples) ............................................................................................................................ 14
Figure 4 -Types of MV and HV substations ................................ ; ......................................... 16
Figure 5 - Mapping of logical interfaces to physical interfaces; mapping of logical interface 8 to the station bus ................................................................................................. 17
Figure 6 - Mapping of logical interfaces to physical interfaces; mapping of logical interface 8 to the process bus ............................................................................................... 18
Figure 7 - Basic reference model .......................................................................................... 19
Figure 8 - The modelling approach of the IEC 61850 series .................................................. 20
Figure 9 -Exchange of system parameters ........................................................................... 21
Figure 1 O - Periods for delivery obligations (example) .......................................................... 22
Figure A.1 - Examples of typical single line diagram for type D1 ........................................... 27
TR 61850-1 © IEC:2003(E) -3-
Figure A.2 -Examples of typical single line diagrams for type 02 ......................................... 27
Figure A.3 -Example of typical single line diagram for type 03 ............................................. 28
Figure A.4 -Examples of typical single line diagrams for type T1 ......................................... 28
Figure A.5 - Example of typical single line diagram for type T2 ............................................. 29
Figure A.6 - Possible locations of current and voltage transformers in substation 02-2 ........ 32
Figure A.7 -Assi�nment of bay units (example) .................................................................... 32
Figure A.8 -Typical protection zones ................................................................................... 33
Figure A.9 - Alternativa solutions for the process level communication bus ........................... 34
Table 1 - Types of messages ................................................................................................ 15
Table 2 -Calculated information flow at logical interfaces (example) .................................... 17
Table A.1 -Types of substations and interfaces used ........................................................... 30
Table A.2 -Types of substations and functions used ............................................................ 31
-4- TR 61850-1 © IEC:2003(E)
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS AND SYSTEMS
IN SUBSTATIONS -
Part 1: lntroduction and overview
FOREWORD
1) The IEC (lnternational Electrotechnical Commission) is a worldwide organization for standardization comprising ali national electrotechnical committees (IEC National Committees). The object of the IEC is to promoteinternational co-operation on all questions concerning standardization in the electrical and electronic fields. Tothis end and in addition to other activities, the IEC publishes lnternational Standards. Their preparation isentrusted to technical committees; any IEC National Committee interested in the subject dealt with mayparticipate in this preparatory work. lnternational, governmental and non-governmental organizations liaisingwith the IEC also participate in this preparation. The IEC collaborates closely with the lnternationalOrganization for Standardization (ISO) in accordance with conditions determined by agreement between thetwo organizations.
2) The formal decisions or agreements of the IEC on technical matters express, as nearly as possible, aninternational consensus of opinion on the relevant subjects since each technical committee has representationfrom all interested National Committees.
3) The documents produced have the form of recommendations for international use and are published in the form of standards, technical specifications, technical reports or guides and they are accepted by the NationalCommittees in that sense.
4) In order to promote international unification, IEC National Committees undertake to apply IEC lnternationalStandards transparently to the maximum extent possible in their national and regional standards. Anydivergence between the IEC Standard and the corresponding national or regional standard shall be clearlyindicated in the latter.
5) The IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for any equipment declared to be in conformity with one of its standards.
6) Attention is drawn to the possibility that sorne of the elements of this technical report may be the subject of patent rights. The IEC shall not be held responsible for identifying any or all such patent rights.
The main task of IEC technical committees is to prepare lnternational Standards. However, a technical committee may propase the publication of a technical report when it has collected data of a different kind from that which is normally published as an lnternational Standard, for example "state of the art".
IEC 61850-1, which is a technical report, has been preparad by IEC technical committee 57: Power system control and associated communications
The text of this technical report is based on the following documents:
Enquiry draft Report on voting
57/524/CDV 57/561/RVC
Full information on the voting for the approval of this technical report can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the 1SO/IEC Directivas, Part 2.
TR 61850-1 © IEC:2003(E) -5-
IEC 61850 consists of the following parts, under the general title Communication networks
and systems in substations 1.
Part 1: lntroduction and overview
Part 2: Glossary 2
Part 3: General requirements
Part 4: System and project management
Part 5: Communication requirements for functions and device models 3
Part 6: Configuration description language for communication in electrical substations related to I EDs 2
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
Part 7-4: Basic communication structure for substation and feeder equipment - Compatible logicaLn.a.de classes and data classes
Part 8-1: Specific communication service mapping (SCSM) - Mappings to MMS (1SO/IEC 9506-1 and ISO/IEC 9506-2) and to ISO/IEC 8802-3
2
Part 9-1: Specific communication service mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
Part 9-2: Specific communication service mapping (SCSM) - Sampled values over ISO/IEC 8802-3
2
Part 1 O: Conformance testing 2
This part is an introduction and overview of the IEC 61850 standard series. lt describes the philosophy, the work approach, the contents of the other parts, and documents of other bodies which have been reviewed.
The committee has decided that the contents of this publication will remain unchanged until 2005. At this date, the publication will be
• reconfirmed;
withdrawn;
replaced by a revised edition, or
• amended.
1 For more details, see Clause 1 O.
2 Under consideration.
3 To be published.
1 Scope
-6- TR 61850-1 © IEC:2003(E)
COMMUNICATION NETWORKS AND SYSTEMS
IN SUBSTATIONS -
Part 1: lntroduction and overview
This technical report is applicable to substation automation systems (SAS). lt defines the communication between intelligent electronic devices (IEDs) in the substation and the related system requirements.
This part gives an introduction and overview of the IEC 61850 standard series. lt refers to and includes text and Figures from other parts of the IEC 61850 standard series.
2 Reference documents
IEC 60870-5-103:1997, Telecontrol equipment and systems - Part 5-103: Transmissionprotocols - Companion standard for the informative interface of protection equipment
IEC 61850-3: Communication networks and systems in substations - Part 3: Generalrequirements
IEC 61850-5: Communication networks and systems in substations - Part 5: Communicationrequirements for functions and device models
IEC 61850-7-1: Communication networks and systems in substations - Part 7-1: Basiccommunication structurp for substation and feeder equipment - Principies and models
IEC 61850-7-2: Communication networks and systems in substations - Part 7-2: Basiccommunication structure for substation and feeder equipment - Abstract communicationservice interface (ACSI)
IEC 61850-7-3: Communication networks and systems in substations - Part 7-3: Basiccommunication structure for substation and feeder equipment - Common data classes
IEC 61850-7-4: Communication networks and systems in substations - Part 7-4: Basiccommunication structure for substation and feeder equipment - Compatible logical nodeclasses and data classes
ISO 9001, 2001: Quality management systems - Requirements
IEEE C37.2, 1996 IEEE Standard Electrical Power System Device Function Numbers and Contact Designations
IEEE 100, 1996, IEEE Standard Dictionary of Electrical and Electronic Terms
IEEE-SA TR 1550, 1999: Utility Communications Architecture (UCA) Version 2.0 - Part 4: UCAGeneric Object Models for Substation and Feeder Equipment (GOMSFE)
TECHNICAL
SPECIFICATION
IEC
TS 61850-2
First edition
2003-08
Communication networks and systems in substations
Part 2: Glossary
© IEC 2003 - Copyright - all rights reserved
No part of thls publication may be reproduced or utillzed In any form or by any means, electronic or mechanical, including photocopying and microfilm, without ¡>ermlsslon in writing from the publisher.
lntemational Electrotechnical Commission, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Switze�and
Telephone: +41 22919 02 11 Telefax: +41 22919 03 00 E-mail: inmail@iec.ch Web: www.iec.ch
Comm ission E lectrotechnique lnternationale lnternational Electrotechnical Commission Me>K,!\yHapOAH8R 3neKTporexHMYeCK8R KOMMCCMR
PRICE CODE X
For price, see current catalogue
-2- TS 61850-2 © IEC:2003(E)
CONTENTS
FOREWORD ........................................................................................................................... 3
1 Scope .............................................................................................................................. 5
2 Terms and definitions ....................................................................................................... 5
3 Abbreviations .................................................................................................................. 28
Bibliography .......................................................................................................................... 40
TS 61850-2 © IEC:2003(E) -3-
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 2: Glossary
FOREWORD
1) The lnternational Electrotechnical Commission (IEC) is a worldwide organization fer standardization comprisingall national electrotechnical committees (IEC National Committees). The object of IEC is to prometeinternational co-operation on all questions concerning standardization in the electrical and electronic fields. To this end and in addition to other activities, IEC publishes lnternational Standards, Technical Specifications,Technical Reports, and Guides (hereafter referred to as 'IEC Publication(s)'). Their preparation is entrusted totechnical committees; any IEC National Committee interested in the subject dealt with may participate in thispreparatory work. lnternational, governmental and non-governmental organizations liaising with the IEC alsoparticipate in this preparation. IEC collaborates closely with the lnternational Organization fer Standardization(ISO) in accordance with conditions determined by agreement between the two organizations.
2) The formal decisions or agreements of IEC on technical matters express, as nearly as possible, an internationalconsensus of opinion on the relevan! subjects since each technical committee has representation from allinterested IEC National Committees.
3) IEC Publications have the form of recommendations fer international use and are accepted by IEC NationalCommittees in that sense. While all reasonable efforts are made to ensure that the technical content of IECPublications is accurate, IEC cannot be held responsible fer the way in which they are used or fer anymisinterpretation by any end user.
4) In order to promete international uniformity, IEC National Committees undertake to apply IEC Publicationstransparently to the maximum extent possible in their national and regional publications. Any divergencebetween any IEC Publication and the corresponding national or regional publication shall be clearly indicated inthe latter.
5) IEC provides no marking procedure to indicate its approval and cannot be rendered responsible fer anyequipment declared to be; in conformity with an IEC Publication.
6) AII users should ensure that they have the lates! edition of this publication.
7) No liability shall attach to IEC or its directors, employees, servants or agents including individual experts andmembers of its technical committees and IEC National Committees fer any personal injury, property damage or other damage of any nature whatsoever, whether direct or indirect, or fer costs (including legal fees) andexpenses arising out of the publication, use of, or reliance upen, this IEC Publication or any other IECPublications.
8) Attention is drawn to the Normative references cited in this publication. Use of the referenced publications isindispensable fer the corree! application of this publication.
9) Attention is drawn to the possibility that sorne of the elements of this IEC Publication may be the subject of patent rights. IEC shall not be held responsible fer identifying any or all such patent rights.
The main task of IEC technical committees is to prepare lnternational Standards. In exceptional circumstances, a technical committee may propose the publication of a technical specification when
the required support cannot be obtained for the publication of an lnternational Standard, despite repeated efforts, or
the subject is still under technical development or where, for any other reason, there is the future but no immediate possibility of an agreement on an lnternational Standard.
Technical specifications are subject to review within three years of publication to decide whether they can be transformed into lnternational Standards.
IEC 61850-2, which is a technical specification, has been prepared by IEC technical committee 57: Power system control and associated communications.
-4- TS 61850-2 © IEC:2003(E)
The text of this technical specification is based on the following documents:
Enquiry draft Report on voting
57/615/DTS 57/645/RVC
Full information on the voting for the approval of this technical specification can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 2.
IEC 61850 consists of the following parts, under the general title Communícatíon networks andsystems in substatíons.
Part 1: lntroduction and overview
Part 2: Glossary
Part 3: General requirements
Part 4: System and project management
Part 5: Communication requirements for functions and device models
P.aft 6-: Configuration description language for communication in electrical substations related to IEDs 1
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
Part 7-4: Basic communication structure for substation and feeder equipment - Compatible logical nade classes and data classes
Part 8-1: Specific communication service mapping (SCSM) - Mappings to MMS (ISO/IEC 9506-1 and ISO/IEC 9506-2) over ISO/IEC 8802-3
Part 9-1: Specific communication service mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
Part 9-2: Specific communication service mapping (SCSM) - Sampled values over ISO/IEC 8802-3 1
Part 10: Conformance testing 1
The committee has decided that the contents of this publication will remain unchanged until 2005. At this date, the publication will be either
reconfirmed; withdrawn; replaced by a revised edition, or amended.
1 Under consideration.
TS 61850-2 © IEC:2003(E) -5-
1 Scope
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 2: Glossary
This part of the IEC 61850 series applies to Substation Automation Systems (SAS). lt defines the communication between intelligent electronic devices (IEDs) in the substation and the related system requirements.
This part of the IEC 61850 series contains the glossary of specific terminology and definitions used in the context of Substation Automation Systems within the various parts of the standard.
NORME
INTERNATIONALE
INTERNATIONAL
STANDARD
CEI
IEC
61850-3
Premiére édition
First edition
2002-01
Réseaux et systemes de communication dans les postes -
Partie 3: Prescriptions générales
Communication networks and systems in substations
Part 3: 'General requirements
© IEC 2002 Droits de reproduction réservés - Copyright - all rights reserved
Aueune partle de eette publlcatlon ne peut 6tre reproduite ni
utilisée sous quelque forme que ce soll et par aueun proeédé,
éleetronique ou mécanique, y eomprls la photoeople et les
microfilms, sans l'aeeord éerit de l'édlteur.
No part of lhis publlcation may be reproduced or ulilized in
any form or by any means, e1ectronic or mechanical,
lncluding photoeopying and mictonlm, wilhout permission in
writing from the publisher.
lntemational Electrotechnical Commission 3, rue de Varembé Geneva, Switzertand
Telefax: +41 22 919 0300 e-mail: inmail@iec.ch IEC web site http://www.iec.ch
111 Commission Electrotechnique lnternationale lnternational Electrotechnical Commission
MeHiAYHapOAHaA 3neKTpOT8XHH48CHaA HOMHCCHA
•
CODE PRIX
PRICE CODE Q
Pour prix, voir catalogue en vigueur
For price, see current catalogue
-2- 61850-3 © CEl:2002
SOMMAIRE
AVANT-PROPOS .................................................................................................................... 4
1 Domaine d'application et objet .......................................................................................... 8
2 Références normatives ..................................................................................................... 8
3 Définitions et abréviations .............................................................................................. 1 O
3.1 Définitions ............................................................................................................. 1 O
3.2 Abréviations .......................................................................................................... 1 O
4 Exigences de qualité ...................................................................................................... 12
4.1 Généralités ............................................................................................................ 12
4.2 Fiabilité ................................................................................................................. 12
4.3 Disponibilité du systéme ........................................................................................ 14
4.4 Maintenabilité ........................................................................................................ 16
4.5 Sécurité ................................................................................................................. 16
4.6 lntégrité des données ............................................................................................ 16
4. 7 Prescriptions générales relatives au réseau .......................................................... 16
5 Conditions d'environnement ........................................................................................... 16
5.1 Généralités ............................................................................................................ 16
5.2 Température .......................................................................................................... 18
5.3 Humidité ................................................................................................................ 18
5.4 Pression barométrique .......................................................................................... 18
5.5 Prescriptions mécaniques et sismiques ................................................................. 18
5.6 Pollution et corros ion ............................................................................................. 18
5.7 lmmunité aux'perturbations électromagnétiques .................................................... 20
5.8 Rayonnement électromagnétique .......................................................................... 26
6 Services auxiliaires ........................................................................................................ 26
6.1 Généralités ............................................................................................................ 26
6.2 Gamme de tensions ............................................................................................... 26
6.3 Tolérances sur la tension ...................................................................................... 26
6.4 lnterruptions d'alimentation ................................................................................... 28
6.5 Qualité de l'alimentation ........................................................................................ 28
Annexe A (informative) Sécurité d'accés .............................................................................. 30
61850-3 © IEC:2002 -3-
CONTENTS
FOREWORD ........................................................................................................................... 5
1 Seo pe and object. ............................................................................................................. 9
2 Normative references ....................................................................................................... 9
3 Definitions and abbreviations .......................................................................................... 11
3.1 Definitions ............................................................................................................. 11 3.2 Abbreviations ........................................................................................................ 11
4 Quality requirements ...................................................................................................... 13
4.1 General ................................................................................................................. 13 4.2 Reliability .............................................................................................................. 13 4.3 System availability ................................................................................................. 15 4.4 Maintainability ....................................................................................................... 17 4.5 Security ................................................................................................................. 17 4.6 Data integrity ......................................................................................................... 17 4.7 General network requirements ............................................................................... 17
5 Environmental conditions ................................................................................................ 17
5.1 General ................................................................................................................. 17 5.2 Temperature .......................................................................................................... 19 5.3 Humidity ................................................................................................................ 19 5.4 Barometric pressure .............................................................................................. 19 5.5 Mechanical and seismic ......................................................................................... 19 5.6 Pollution and corros ion .......................................................................................... 19 5.7 EMI immunity' ........................................................................................................ 21 5.8 EMI radiation ......................................................................................................... 27
6 Auxiliary services ........................................................................................................... 27
6.1 General ............................ · ..................................................................................... 27 6.2 Voltage range ........................................................................................................ 27 6.3 Voltage tolerance .................................................................................................. 27 6.4 Voltage interruptions ............................................. ,, .............................................. 29 6.5 Voltage quality ...................................................................................................... 29
Annex A (informative) Access security ................................................................................. 31
-4- 61850-3 © CEl:2002
COMMISSION ÉLECTROTECHNIQUE INTERNATIONALE
RÉSEAUX ET SYSTEMES DE COMMUNICATION DANS LES POSTES -
Partie 3: Prescriptions générales
AVANT-PROPOS
1) La CEI (Commission Électrotechnique lnternationale) est une organisation mondiale de normalisationcomposée de !'ensemble des comités électrotechniques nationaux (Comités nationaux de la CEI). La CEI apour objet de favoriser la coopération internationale pour toutes les questions de normalisation dans les domaines de l'électricité et de l'électronique. A cet effet, la CEI, entre autres activités, publie des Normes internationales. Leur élaboration est confiée a des comités d'études, aux travaux desquels tout Comité national intéressé par le sujet traité peut participar. Les organisations internationales, gouvernementales et nongouvernementales, en liaison avec la CEI, participent également aux travaux. La CEI collabore étroitement avec l'Organisation lnternationale de Normalisation (ISO), selon des conditions fixées par accord entre lesdeux organisations.
2) Les décisions ou accords officiels de la CEI concernant les questions techniques représentent, dans la mesuredu possible, un accord international sur les sujets étudiés, étant donné que les Comités nationaux intéresséssont représentés dans chaque comité d'études.
3) Les documents produits se présentent sous la forme de recommandations internationales. lls sont publiéscomme normes, spécifications techniques, rapports techniques ou guides et agréés comme tels par lesComités nationaux.
4) Dans le-but d'encourager l'unification internationale, les Comités nationaux de la CEI s'engagent a appliquer defacon transparente, dans toute la mesure possible, les Normas internationales de la CEI dans leurs normesnationales et régionales. Toute divergence entre la norme de la CEI et la norme nationale ou régionale correspondante doit etre indiquée en termes clairs dans cette derniére.
5) La CEI n'a fixé aucune procédure concernant le marquage comme indication d'approbation et sa responsabilitén'est pas engagée quand un matériel est déclaré conforme a l'une de ses normes.
6) L'attention est attirée suP le fait que certains des éléments de la présente Norme internationale peuvent fairel'objet de droits de propriété intellectuelle ou de droits analogues. La CEI ne saurait etre tenue pourresponsable de ne pas avoir identifié de tels droits de propriété et de ne pas avoir signalé leur existence.
La Norme internationale CEI 61850-3 a été établie par le comité d'études 57 de la CEI: Conduite des systemes de puissance et communications associées.
Le texte de cette norme est issu des documents suivants:
FDIS Rapport de vote
57/557/FDIS 57/572/RVD
Le rapport de vote indiqué dans le tableau ci-dessus donne toute information sur le vote ayant abouti a l'approbation de cette norme.
Cette publication a été rédigée selon les Directives ISO/CEI, Partie 3.
L'annexe A est donnée uniquement a titre d'information.
61850-3 © IEC:2002 -5-
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 3: General requirements
FOREWORD
1) The IEC (lnternational Electrotechnical Commission) is a world-wide organisation for standardisationcomprising all national electrotechnical committees (IEC National Committees). The object of the IEC is to promete international co-operation on all questions concerning standardisation in the electrical and electronicfields. To this end and in addition to other activities, the IEC publishes lnternational Standards. Theirpreparation is entrusted to technical committees; any IEC National Committee interested in the subject dealtwith may participate in this preparatory work. lnternational, governmental and non-governmental organisationsliasing with the IEC also participate in this preparation. The IEC collaborates closely with the lnternationalOrganisation for Standardisation (ISO) in accordance with conditions determined by agreement between the two organisations.
2) The formal decisions or agreements of the IEC on technical matters express, as nearly as possible, aninternational consensus of opinion on the relevant subjects since each technical committee has representationfrom all interested National Committees.
3) The documents produced have the form of recommendations for international use and are published in the formof standards, technical specifications, technical reports or guides and they are accepted by the NationalCommittees in that sense.
4) In order to promete international unification, IEC National Committees undertake to apply. IEC lnternationalStandards transparently to the maximum extent possible in their national and regional standards. Anydivergence between the IEC Standard and the corresponding national or regional standard shall be clearlyindicated in the latter.
5) The IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for anyequipment declared to be in conformity with one of its standards.
6) Attention is drawn to the possibility that sorne of the elements of this lnternational Standard may be the subject of patent rights. The IEC shall not be held responsible for identifying any or all such patent rights.
lnternational Standard IEC 61850-3 has been prepared by IEC technical committee 57: Power system control and associated communications.
The text of this standard is based on the following documents:
FDIS Report on voting
57/557/FDIS 57/572/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 3.
Annex A is for information only.
-6- 61850-3 © CEl:2002
La CEI 61850 comprend les parties suivantes, présentées sous le titre général: Réseaux et systemes de communication dans les postes:
Partie 1: lntroduction et vue généraIe 1
Partie 2: Glossary1
Partie 3: Prescriptions générales
Partie 4: Gestion du systéme et gestion de projet
Partie 5: Communication requirements for functions and device models1
Partie 6: Substation automation system configuration description language1
Partie 7-1: Basic communication structure for substation and feeder equipment - Principies and models1
Partie 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSl)1
Partie 7-3: Basic communication structure for substation and feeder equipment - Common data classes1
Partie 7-4: Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes1
Partie 8-1: Specific communication service mapping (SCSM) - Mapping to MMS (ISO/IEC 9506 Part 1 and Part 2)1
Partie 9-1: Specific communication service mapping (SCSM) - Serial unidirectional multidrop point to point link 1
Partie 9-2: Specific communication service mapping (SCSM) - Mapping on a IEEE 802.3 based process bus 1
Partie 1 O: Conformance testing1
Le comité a décidé que le contenu de cette publication ne sera pas modifié avant 2004. A cette date, la publication sera
reconduite;
supprimée;
remplacée par une édition révisée, ou
amendée.
1 A l'étude.
61850-3 © IEC:2002 -7-
IEC 61850 consists of the following parts, under the general title: Communication networks and systems in substations:
Part 1 :·Introduction and overview1
Part 2: Glossary1
Part 3: General requirements
Part 4: System and project management
Part 5: Communication requirements for functions and device models1
Part 6: Substation automation system configuration description language1
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models1
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSl)1
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes1
Part 7-4: Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes1
Part 8-1: Specific communication service mapping (SCSM) - Mapping to MMS (ISO/IEC 9506 Part 1 and Part 2)1
Part 9-1: Specific communication service mapping (SCSM) - Serial unidirectional multidrop point to point link1
Part 9-2: Specific communication service mapping (SCSM) - Mapping on a IEEE 802.3 based process bus1
Part 1 O: Conformance testing1
The committee has decided that the contents of this publication will remain unchanged until 2004; At this date, the publication will be
reconfirmed;
withdrawn;
replaced by a revised edition, or
amended.
1 Under consideration.
-8- 61850-3 © CEl:2002
RÉSEAUX ET SYSTEMES DE COMMUNICATION DANS LES POSTES -
Partie 3: Prescriptions générales
1 Domaine d'application et objet
La présente partie de la CEI 61850 s'applique aux systémes d'automatisation de poste (SAS). Elle définit la communication entre les dispositifs électroniques intelligents (IED) dans le poste ainsi que les prescriptions concernant les systémes associés.
Les spécifications de la présente partie font partie des prescriptions générales du réseau de communication, en mettant l'accent sur les prescriptions de qualité. Cette partie traite également des lignes directrices relatives aux conditions d'environnement et aux services auxiliaires, en donnant des recommandations sur la pertinence des prescriptions spécifiques d'autres normes et spécifications.
2 Références normatives
Les documents normatifs suivants contiennent des dispositions qui, par suite de la référence qui y est faite, constituent des dispositions valables pour la présente partie de la CEI 61850. Pour les références datées, les amendements ultérieurs ou les révisions de ces publications ne s'appliquent pas. Toutefois, les parties prenantes aux accords fondés sur la présente partie de la CEI 61850 sont invitées a rechercher la possibilité d'appliquer les éditions les plus récentes des documents normatifs indiqués ci-aprés. Pour les références non datées, la derniére édition du document normatif en référence s'applique. Les membres de la CEI et de 1'1S0 possédent le registre des Normes internationales en vigueur.
CEI 60654-4:1987, Conditions de fonctionnement pour les matériels de mesure et commande dans les processus industriels - Quatrieme partie: lnfluences de la corrosion et de /'érosion
CEI 60694:1996, Spécifications communes aux normes de /'appareil/age a haute tension
CEI 60870-2-1 :1995, Matériels et systemes de téléconduite - Partie 2: Conditions de fonctionnement - Section 1: A/imentation et compatibilité électromagnétique
CEI 60870-2-2: 1996, Matériels et systemes de téléconduite - Partie 2: Conditions de fonctionnement - Section 2: Conditions d'environnement (inf/uences c/imatiques, mécaniques et autres influences non électriques)
CEI 60870-4: 1990, Matériels et systemes de téléconduite - Quatrieme partie: Prescriptions relatives aux performances
CEI 61000-4-3: 1995, Compatibilité électromagnétique (CEM) - Partie 4: Techniques d'essai et de mesure - Section 3: Essai d'immunité aux champs électromagnétiques rayonnés aux fréquences radioélectriques
CEI 61000-4-4:1995, Compatibilité électromagnétique (CEM) - Partie 4: Techniques d'essai et de mesure - Section 4: Essais d'immunité aux transitoires électriques rapides en salves. Publication fondamentale en CEM
CEI 61000-4-5:1995, Compatibilité électromagnétique (CEM) - Partie 4: Techniques d'essai et de mesure - Section 5: Essai d'immunité aux ondes de choc
61850-3 © IEC:2002 -9-
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 3: General requirements
1 Scope and object
This part of IEC 61850 applies to substation automation systems (SAS). lt defines the communication between intelligent electronic devices (IEDs) in the substation and the related system requirements.
The specifications of this part pertain to the general requirements of the communication network, with emphasis on the quality requirements. lt also deals with guidelines for environmental conditions and auxiliary services, with recommendations on the relevance of specific requirements from other standards and specifications.
2 Normative references
The following normative documents contain provisions which, through reference in this text, constitute provisions of this part of IEC 61850. For dated references, subsequent amendments to, or revisions of, any of these publications do not apply. However, parties to agreements based on this part of IEC 61850 are encouraged to investigate the possibility of applying the most recent editions of the normative documents indicated below. For undated references, the latest edition of the normative document referred to applies. Members of IEC and ISO maintain registers of currently valid lnternational Standards.
,
IEC 60654-4:1987, Operating conditions for industrial-process measurement and control equipment - Part 4: Corrosive and erosive inf/uences
IEC 60694:1996, Common specifications for high-voltage switchgear and controlgear standards
IEC 60870-2-1:1995, Telecontrol equipment and systems - Part 2: Operating conditions -Section 1: Power supply and electromagnetic compatibility
IEC 60870-2-2:1996, Telecontrol equipment and systems - Part 2: Operating conditions -Section 2: Environmental conditions (climatic, mechanical and other non-electrical influences)
IEC 60870-4: 1990, Telecontrol equipment and systems - Part 4: Performance requirements
IEC 61000-4-3:1995, Electromagnetic compatibility (EMC) - Part 4: Testing and measurement techniques - Section 3: Radiated, radio-frequency, electromagnetic field immunity test
IEC 61000-4-4:1995, Electromagnetic compatibility (EMC) - Part 4: Testing and measurement techniques - Section 4: Electrical fast transientlburst immunity test. Basic EMC Publication
IEC 61000-4-5:1995, Electromagnetic compatibility (EMC) - Part 4: Testing and measurement techniques - Section 5: Surge immunity test
-10- 61850-3 © CEl:2002
CEI 61000-4-6:1996, Compatibilité é/ectromagnétique (CEM) - Partie 4: Techniques d'essaiet de mesure - Section 6: /mmunité aux perturbations conduites, induites par les champsradioé/ectriques
CEI 61000-4-8:1993, Compatibilité é/ectromagnétique (CEM) - Partie 4: Techniques d'essaiet de mesure - Section 8: Essai d'immunité au champ magnétique a la fréquence du réseau
CEI 61000-4-10:1993, Compatibilité é/ectromagnétique (CEM) - Partie 4: Techniques d'essaiet de mesure - Section 10: Essai d'immunité au champ magnétique oscil/atoire amorti
CEI 61000-4-12:1995, Compatibilité électromagnétique (CEM) - Partie 4: Techniques d'essaiet de mesure - Section 12: Essai d'immunité aux ondes oscil/atoires
CEI 61000-4-16: 1998, Compatibilité é/ectromagnétique (CEM) - Partie 4-16: Techniquesd'essai et de mesure - Essai d'immunité aux perturbations conduites en mode commun dansla gamme de fréquences de O Hz a 150 kHz
CEI TS 61000-6-5:2001, Compatibilité électromagnétique (CEM) - Partie 6: Normesgénériques - Section 5: lmmunité pour les environnements de centrales é/ectriques et depostes
CISPR 22:1997, Apparei/s de traitement de l'information - Caractéristiques des perturbationsradioé/ectriques - Limites et méthodes de mesure
IEEE C37.90.2:1995, IEEE Standard for Withstand Capability of Re/ay Systems to Radiated Electromagnetic lnterference from Transceivers
61850-3 © IEC:2002 - 11 -
IEC 61000-4-6:1996, Electromagnetic compatibility (EMC) - Part 4: Testing and measurementtechniques - Section 6: lmmunity to conducted disturbances, induced by radio-frequencyfie/ds
IEC 61000-4-8:1993, Electrqmagnetic compatibility (EMC) - Part 4: Testing and measurementtechniques - Section 8: Power frequency magnetic field immunity test
IEC 61000-4-10:1993, Electromagnetic compatibility (EMC) - Part 4: Testing and measurement techniques - Section 10: Damped oscillatory magnetic field immunity test
IEC 61000-4-12:1995, Electromagnetic compatibility (EMC) - Part 4: Testing and measurement techniques - Section 12: Oscillatory waves immunity test
IEC 61000-4-16:1998, Electromagnetic compatibility (EMC) - Part 4-16: Testing and measurement techniques - Test for immunity to conducted, common mode disturbances in thefrequency range O Hz to 150 kHz
IEC TS 61000-6-5:2001, E/ectromagnetic compatibility (EMC) - Part 6-5: Generic standards -
lmmunity for power station and substation environments
CISPR 22:1997, IEEE Standard for lnformation Technology Equipment - Radio DisturbanceCharacteristics - Limits and Methods of Measurement
IEEE C37.90.2:1995, Withstand capability of re/ay systems to radiated electromagnetic interference from transceivers
NORME
INTERNATIONALE
INTERNATIONAL
STANDARD
CEI
IEC
61850-4
Premiére édition
First edition
2002-01
Réseaux et systemes de communication dans les postes -
Partie 4: Gestion du systeme et gestion de projet
Communication networks and systems in substations -
Part 4: System and project management
© IEC 2002 Droits de reproduction réservés - Copyright - all rights reserved
Aucune partle de cetto publlcation no pout 6tro reproduite ni
utilisée sous quolque formo que ce solt et par aucun procédé,
éloctronlque ou mécanlque, y compris la photocoplo et los
microfilms, sans l'accord écrit do l'édlleur.
No part of this publlcation may be reproducod or utillzed in
any form or by any means, electronlc or mechanical,
lncludlng photocopying and microfilm, wilhout permission in
writing from the publisher.
lntemational Electrotechnical Commission 3, rue de Varembé Geneva, Switzerland
Telefax: +41 22 919 0300 e-mail: inmail@iec.ch IEC web site http://www.iec.ch
111 Commission Electrotechnique lnternationale lnternational Electrotechnical Commission Me>H,QyHapo,11HaA 3neKTpoT8XHH'f8CH3A HOMHCCMA
CODE PRIX
PRICE CODE u
Pour prix, voir catalogue en vigueur
For price, see current catalogue
-2- 61850-4 © CEl:2002
SOMMAIRE
AVANT-PROPOS .................................................................................................................... 4
1 Domaine d'application et objet .......................................................................................... 8
2 Références normativas ..................................................................................................... 8
3 Définitions ...................................................................................................................... 1 O 4 Abréviations .................................................................................................................... 16 5 Exigences liées a l'étude ................................................................................................. 16
5.1 lntroduction ........................................................................................................... 16 5.2 Catégories et types de paramétres ......................................................................... 18 5.3 Les outils d'étude .................................................................................................. 24 5.4 Flexibilité et extensibilité ........................................................................................ 28 5.5 Evolutivité .............................................................................................................. 30 5.6 Documentation de projet automatique .................................................................... 32 5.7 Documentation standard ........................................................................................ 38 5.8 Support de l'intégrateur systéme ............................................................................ 38
6 Cycle de vie du systéme ................................................................................................. 38
6.1 Exigences liées aux versions des produits ............................................................. 38 6.2 Annonce de l'aFret de fabrication du produit ........................................................... 42 6.3 Support a pres l'arret de fabrication ........................................................................ 42
7 Assurance qua lité ........................................................................................................... 44 7.1 Répartition des responsabilités .............................................................................. 44 7.2 Equipement d'essai ............................................................................................... 48 7 .3 Classification des essais de qualité ........................................................................ 50
Annexe A (informativa) Annonce de l'arret de la fabrication (exemple) .................................. 56 Annexe B (informativa) Obligations de livraison aprés l'arret de la fabrication (exemple) ....... 58
Figure 1 - Structure du SAS et de son environnement.. ......................................................... 16 Figure 2 - Structure des paramétres SAS et IED ................................................................... 20 Figure 3 - Les taches d'étude et leurs relations ..................................................................... 24 Figure 4 - Le processus de paramétrage ............................................................................... 26 Figure 5 - La documentation de projet du SAS ...................................................................... 32 Figure 6 - Deux significations du cycle de vie SAS ............................................................... .40 Figure 7 - Les étapes de l'assurance qualité - Responsabilité du constructeur et de l'intégrateur systéme .................................................................... .-........................................ 44 Figure 8 - Contenu de l'essai du systéme .............................................................................. 50 Figure 9 - Contenu de l'essai de type .................................................................................... 52 Figure 1 O - Contenu de l'essai individue! de série .................................................................. 52 Figure 11 - Les étapes d'essai de l'essai de réception sur site .............................................. 54 Figure A.1 - Conditions d'annonce ........................................................................................ 56 Figure B.1 - Périodes des obligations de livraison ...................................... _. .......................... 58
61850-4 © IEC:2002 -3-
CONTENTS
FOREWORD ........................................................................................................................... 5
1 Seo pe and object .............................................................................................................. 9
2 Normative references ........................................................................................................ 9
3 Definitions ... : .................................................................................................................. 11
4 Abbreviations .................................................................................................................. 17
5 Engineering requirements ............................................................................................... 17
5.1 1 ntroduction ........................................................................................................... 17 5.2 Categories and types of parameters ....................................................................... 19
5.3 Engineering too Is ................................................................................................... 25
5.4 Flexibility and expandability ................................................................................... 29
5.5 Scalability .............................................................................................................. 31 5.6 Automatic project documentation ........................................................................... 33
5. 7 Standard documentation ........................................................................................ 39
5.8 System integrator's support ................................................................................... 39
6 System life cycle ............................................................................................................. 39
6.1 Requirements of product versions .......................................................................... 39
6.2 Announcement of product discontinuation .............................................................. 43
6.3 Support after discontinuation ................................................................................. 43 7 Quality assurance ........................................................................................................... 45
7 .1 Division of responsibility ........................................................................................ 45 7.2 Test equipme�t. ................................................................................................... .... 497 .3 Classification of quality tests .................................................................................. 51
Annex A (informative) Announcement of discontinuation (example) ....................................... 57
Annex B (informative) Delivery obligations after discontinuation (example) ............................ 59
Figure 1 - Structure of the SAS and its environment.. ............................................................ 17
Figure 2 - Structure of SAS and IED parameters ................................................................... 21
Figure 3 - Engineering tasks and their relationship ................................................................ 25
Figure 4 - R,arameterization process ..................................................................................... 27
Figure 5 - Project related documentation of SAS ................................................................... 33
Figure 6 - Two meanings of the SAS life cycle ...................................................................... 41
Figure 7 - Stages of quality assurance - Responsibility of manufacturer and system integrator ................................................................... .-........................................ 45
Figure 8 - Contents of system test ........................................................................................ 51
Figure 9 - Contents of type test ............................................................................................. 53
Figure 1 O - Contents of routine test.. ..................................................................................... 53
Figure 11 - Testing stages for site acceptance test ............................................................... 55
Figure A.1 - Announcement conditions .................................................................................. 57
Figure B.1 - Periods for delivery obligations ............................................... _ ........................... 59
-4- 61850-4 © CEl:2002
COMMISSION ÉLECTROTECHNIQUE INTERNATIONALE
RÉSEAUX ET SYSTEMES DE COMMUNICATION DANS LES POSTES -
Partie 4: Gestion du systeme et gestion de projet
AVANT-PROPOS
1) La CEI (Commission Électrotechnique lnternationale) est une organisation mondlale de normalisation composée de !'ensemble des comités électrotechniques nationaux (Comités nationaux de la CEI). La CEI a pour objet de favoriser la coopération internationale pour toutes les questions de normalisation dans les domaines del'électricité et de l'électronique. A cet effet, la CEI, entre autres activités, publie des Normes internationales.Leur élaboration est confiée a des comités d'études, aux travaux desquels tout Comité national intéressé par lesujet traité peut participer. Les organisations internationales, gouvernementales et non gouvernementales, enliaison avec la CEI, participent également aux travaux. La CEI collabore étroitement avec l'Organisationlnternationale de Normalisation (ISO), selon des conditions fixées par accord entre les deux organisations.
2) Les décisions ou accords officiels de la CEI concernant les questions techniques représentent, dans la mesuredu possible, un accord international sur les sujets étudiés, étant donné que les Comités nationaux intéresséssont représentés dans chaque comité d'études.
3) Les ·documents produits se présentent sous la forme de recommandations internationales. lls sont publiéscomme normes, spécifications techniques, rapports techniques ou guides et agréés comme tels par les Comitésnationaux.
4) Dans le but d'encourager l'unification internationale, les Comités nationaux de la CEI s'engagent a appliquer de fai;:on transparente, dans toute la mesure possible, les Normes internationales de la CEI dans leurs normes nationales et régionales. Toute divergence entre la norme de la CEI et la norme nationale ou régionalecorrespondante doit étre indiquée en termes clairs dans cette derniére.
5) La CEI n'a fixé aucune procédure concernant le marquage comme indication d'approbation et sa responsabilitén'est pas engagée quand un matériel est déclaré conforme a l'une de ses normes.
6) L'attention est attirée sur le fait que certains des éléments de la présente Norme internationale peuvent fairel'objet de droits de propriété intellectuelle ou de droits analogues. La CEI ne saurait étre tenue pourresponsable de ne pas avoir identifié de tels droits de propriété et de ne pas avoir signalé leur existence.
La Norme internationale CEI 61850-4 a été établie par le comité d'études 57 de la CEI: Conduite des systémes de puissance et communications associées.
Le texte de cette norme est issu des documents suivants:
FDIS Rapport de vote
57/558/FDIS 57/573/RVD
Le rapport de vote indiqué dans le tableau ci-dessus donne toute information sur le vote ayant abouti a l'approbation de cette norme.
Cette publication a été rédigée selon les Directives ISO/CEI, Partie 3.
Les annexes A et B sont données uniquement a titre d'information.
La CEI 61850 comprend les parties suivantes, présentées sous le titre général: Réseaux et systémes de communication dans les postes:
Partie 1: lntroduction et vue générale 1
1 l'étude.
61850-4 © IEC:2002 -5-
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 4: System and project management
FOREWORD
1) The IEC (lnternational Electrotechnical Commission) is a worldwide organization for standardization comprisingall national electrotechnical committees (IEC National Committees). The object of the IEC is to promoteinternational co-operation on all questions concerning standardization in the electrical and electronic fields. Tothis end and in addition to other activities, the IEC publishes lnternational Standards. Their preparation isentrusted to technical committees; any IEC National Committee interested in the subject dealt with mayparticipate in this preparatory work. lnternational, governmental and non-governmental organizations liaisingwith the IEC also participate in this preparation. The IEC collaborates closely with the lnternational Organizationfor Standardization {ISO) in accordance with conditions determined by agreement between the twoorganizations.
2) The formal decisions or agreements of the IEC on technical matters express, as nearly as possible, aninternational consensus of opinion on the relevant subjects since each technical committee has representationfrom all interested National Committees.
3) The documents produced have the form of recommendations for international use and are published in the formof standards, technical specifications, technical reports or guides and they are accepted by the NationalCommittees in that sense.
4) In order to promote international unification, IEC National Committees undertake to apply IEC lnternationalStandards transparently to the maximum extent possible in their national and regional standards. Anydivergence between the IEC Standard and the corresponding national or regional standard shall be clearlyindicated in the latter.
5) The IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for anyequipment declared to be in conformity with one of its standards.
6) Attention is drawn to the possibility that sorne of the elements of this lnternational Standard may be the subjectof patent rights. The IEC shall not be held responsible for identifying any or all such patent rights.
lnternational Standard IEC 61850-4 has been prepared by IEC technical committee 57: Power system control and associated communications
The text of this standard is based on the following documents:
FDIS Report on voting
57/558/FDIS 57/573/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 3.
Annexes A and B are for information only.
IEC 61850 consists of the following parts, under the general title: Comm unication networks and systems in substations:
Part 1: lntroduction and overview1
1 Under consideration.
-6- 61850-4 © CEl:2002
Partie 2: Glossary1
Partie 3: Prescriptions générales
Partie 4: Gestion du systeme et gestion de projet
Partie 5: Communication requirements for functions and device models1
Partie 6: Substation automation system configuration description language 1
Partie 7-1: Basic communication structure for substation and feeder equipment - Principies and models1
Partie 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI} 1
Partie 7-3: Basic communication structure for substation and feeder equipment - Common data classes 1
Partie 7-4: Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes1
Partie 8-1: Specific communication service mapping (SCSM) - Mapping to MMS {1SO/IEC 9506 Part 1 and Part 2) 1
Partie 9-1: Specific communication service mapping (SCSM) - Serial unidirectional multidrop point to point link 1
Partie 9-2: Specific communication service mapping (SCSM) - Mapping on a IEEE 802.3 based process bus 1
Partie 1 O: Conformance testing1
Le comité a décidé que le contenu de cette publication ne sera pas modifié avant 2004. A cette date, la publication sera
• reconduite;• supprimée;
remplacée par une édition révisée, ouamendée.
1 A l'étude.
61850-4 © IEC:2002 -7-
Part 2: Glossary1
Part 3: General requirements
Part 4: System and project management
Part 5: Communication requirements for functions and device models1
Part 6: Substation automation system configuration description language 1
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models1
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSl) 1
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes1
Part 7-4: Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes 1
Part 8-1: Specific communication service mapping (SCSM) - Mapping to MMS (1SO/IEC 9506 Part 1 and Part 2) 1
Part 9-1: Specific communication service mapping (SCSM) - Serial unidirectional multidrop point to point link1
Part 9-2: Specific comm'unication service mapping (SCSM) - Mapping on a IEEE 802.3 based process bus 1
Part 1 O: Conformance testing1
The committee has decided that the contents of this publication will remain unchanged until 2004. At this date, the publication will be
reconfirmed; withdrawn; replaced by a revised edition, or
• amended.
1 Under consideration.
-8- 61850-4 © CEl:2002
RÉSEAUX ET SYSTEMES DE COMMUNICATION DANS LES POSTES -
Partie 4: Gestion du systeme et gestion de projet
1 Domaine d'application et objet
Cette partie de la CEI 61850 s'applique aux systémes d'automatisation de poste (SAS). Elle définit la communication entre les dispositifs électroniques intelligents (IED) dans le poste ainsi que les exigences concernant les systémes associés.
Les spécifications contenues dans cette partie se rapportent a la gestion du systéme et a la gestion de projet en ce qui concerne:
- le processus d'étude et les outils de support associés;
- le cycle de vie du systéme global et de ses IED;
- l'assurance qualité, de l'étape de développement jusqu'a l'arret de fabrication et la misehors service du SAS et de ses IED.
Les exigences du processus de gestion du systéme et de gestion de projet ainsi que celles des outils de support spécifiques pour l'étude et les essais sont décrites.
2 Références normatives
Les documents normatifs suivants contiennent des dispositions qui, par suite de la référence qui y est faite, constituent des dispositions valables pour la présente partie de la CEI 61850. Pour les références datées, les amendements ultérieurs ou les révisions de ces publications ne s'appliquent pas. Toutefois, les parties prenantes aux accords fondés sur la présente partie de la CEI 61850 sont invitées a rechercher la possibilité d'appliquer les éditions les plus récentes des documents normatifs indiqués ci-aprés. Pour les références non datées, la derniére édition du document normatif en référence s'applique. Les membres de la CEI et de I'ISO possédent le registre des Normes internationales en vigueur.
CEI 60848:1988, Etablissement des diagrammes fonctionnels pour systemes de commande
CEI 61082 (toutes les parties), Etablissement des documents utilisés en électrotechnique
CEI 61175:1993, Désignations des signaux et connexions
CEI 61346 (toutes les parties), Systemes industriels, instal/ations et apparei/s, et produits industriels - Príncipes de structuration et désignations de référence
ISO 9001: 1994, Systemes qua/ité - Modele pour l'assurance de la qualité en conception, développement, production, installation et prestations associées (en anglais seulement)
61850-4 © IEC:2002 -9-
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 4: System and project management
1 Scope and object
This part of IEC 61850 applies to substation automation systems (SAS). lt defines the communication between intelligent electronic devices (IEDs) in the substation and the related system requirements.
The specifications of this part pertain to the system and project management with respect to:
- the engineering process and its supporting tools;
- the life cycle of the overall system and its IEDs;
- the quality assurance beginning with the development stage and ending with discon-tinuation and decommissioning of the SAS and its IEDs.
The requirements of the system and project management process and of special supporting tools for engineering and testing are described.
2 Normative references
The following normative documents contain provisions which, through reference in this text, constitute provisions of this part of IEC 61850. For dated references, subsequent amendments to, or revisions of, any ,of these publications do not apply. However, parties to agreements based on this part of IEC 61850 are encouraged to investigate the possibility of applying the most recent editions of the normative documents indicated below. For undated references, the latest edition of the normative document referred to applies. Members of IEC and ISO maintain registers of currently valid lnternational Standards.
IEC 60848:1988, Preparation of function charts for control systems
IEC 61082 (all parts), Preparation of documents used in the electrotechnology
IEC 61175:1993, Designations for signals and connections
IEC 61346 (all parts}, Industrial systems, installations and equipment and industrial products -
Structuring principies and reference designations
ISO 9001: 1994, Qua/ity systems - Model for quality assurance in design, development, production, installation and seNicing
INTERNATIONAL
STANDARD
IEC
61850-5
First edition
2003-07
Communication networks and systems in substations -
Part 5: Communication requirements .for functions and device models
© IEC 2003 - Copyright - all rights reserved
No part of thls publlcatlon may be reproduced or utlllzed In any form or by any means, electronlc or mechantcal, tncludlng photocopylng and microfilm, wlthout permlsslon In wrltlng from the publlsher.
lntemationat Electrotechnlcal Commlsslon, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Switzertand
Telephone: +41 22 919 02 11 Telefax: +41 22 919 03 00 E-mail: lnmall@lec.ch Web: www.lec.ch
Commission Electrotechnique lnternationale lnternational Electrotechnical Commission Me)l(,llyHapOAH8R 3neKTpOT8XHH48CK8R KOMHCCHR
PRICE CODE XF
For plica, sea curran/ catalogue
-2- 61850-5 © IEC:2003(E)
CONTENTS
FOREWORD .......................................................................................................................... 6
INTRODUCTION .................................................................................................................... 8
1 Scope .............................................................................................................................. 9
2 Normative references ....................................................................................................... 9
3 Terms and de fin itions ..................................................................................................... 1 O
4 Abbreviations .................................................................................................................. 13
5 Substation automation system functions ......................................................................... 14
5.1 lntroduction ........................................................................................................... 14
5.2 Logical allocation of functions and interfaces ......................................................... 14
5.3 The physical allocation of functions and interfaces ................................................ 16
5.4 The role of interfaces ............................................................................................. 16
6 Goal and requirements ................................................................................................... 17
6.1 lnteroperability ....................................................................................................... 17
6.2 Static design requirements .................................................................................... 17
6.3 Dynamic interaction requirements .......................................................................... 17
6.4 Response behavior requirements ........................................................................... 18
6.5 Approach to interoperability ................................................................................... 18
6.6 Conformance test requirements ............................................................................. 18
7 Rules for function definition ............................................................................................ 18
7.1 Function description .............................................................................................. 19
7.2 Logical Node description ....................................................................................... 19
7.3 PICOM description ................................................................................................. 19
8 Categories of functions ................................................................................................... 19
8.1 System support functions ....................................................................................... 19
8.2 System configuration or maintenance functions ..................................................... 19
8.3 Operational or control functions ............................................................................. 20
8.4 Local process automation functions ....................................................................... 20
8.5. Distributed automatic support functions ................................................................. 20
8.6 Distributed process automation functions ............................................................... 20
9 The logical node concept ................................................................................................ 20
9.1 Logical nodes and logical connections ................................................................... 20
9.2 The need for a formal system description .............................................................. 21
9.3 Requirements for logical node behavior ................................................................. 22
9.4 Examples for decomposition of common functions into logical nodes ..................... 22
1 O The PICOM concept ........................................................................................................ 23
10.1 Attributes of PICOMS ............................................................................................ 24
10.2 PICOMs and data models ...................................................................................... 25
11 List of logical nodes ........................................................................................................ 25
11.1 Logical Nodes for protection functions ................................................................... 26
11.2 Logical Nodes for control ....................................................................................... 31
11.3 Physical device ...................................................................................................... 34
11.4 System and device security ................................................................................... 34
11.5 LNs related to primary equipment .......................................................................... 34
11.6 LNs related to system services .............................................................................. 37
61850-5 © IEC:2003(E) -3-
12 The application of LN (informative) ................................................................................. 37
12.1 Basic principies ..................................................................................................... 37
12.2 Basic examples ..................................................................................................... 38
12.3 Additional examples ............................................................................................... 39
12.4 Remarks on modeling ............................................................................................ 42
. 13 Message performance requirements ............................................................................... 43
13.1 lntroduction ........................................................................................................... 43
13.2 Basic time requirements ........................................................................................ 43
13.3 Event time definition .............................................................................................. 44
13.4 Transfer time definition .......................................................................................... 44
13.5 The introduction and use of message types .......................................................... .45
13.6 The introduction and use of performance classes ................................................. .45
13. 7 Message types and performance classes .............................................................. .46
14 Requirements for data integrity ....................................................................................... 49
15 System performance requirements .................................................................................. 49
15.1 lntroduction ........................................................................................................... 49
15.2 Calculation methods .............................................................................................. 50
15.3 Calculation results ................................................................................................. 51
15.4 Summary ............................................................................................................... 51
16 Additional requirements for the data model ..................................................................... 52
16.1 Requirements for the addressing of logical nodes .................................................. 52
16.2 Requirements for the data model ........................................................................... 52
Annex A (informative) Logical nodes and related PICOMs .................................................... 53
Annex B (informative) Pl,COM identification and message classification ............................... 67
Annex C (informative) Communication optimization .............................................................. 74
Annex D (informative) Rules for function definition ............................................................... 75
Annex E (informative) lnteraction of functions and logical nodes .......................................... 77
Annex F (informative) Categories of functions ...................................................................... 78
Annex G (informative) Functions .......................................................................................... 80
Annex H (informative) Results from the function description ............................................... 105
Annex 1 (informative) Performance calculations .................................................................. 111
Annex J (informative) Examples for protection functions in compensated networks ............ 129
Bibliography ........................................................................................................................ 131
Figure 1 - Relative position of this part of the IEC 61850 series ............................................. 8
Figure 2 - Leve Is and logical interfaces in substation automation systems ............................ 15
Figure 3 - The logical node and link concept... ...................................................................... 21
Figure 4 - Examples of the application of the logical node concept ....................................... 23
Figure 5 - Protection function consisting of 3 logical nodes ................................................... 25
Figure 6 - The basic communication links of a logical node of main protection type .............. 29
Figure 7 - Decomposition of functions into interacting LNs on different levels: examples for generic automatic function, breaker control function and voltage control function ............ 38
-4- 61850-5 © IEC:2003(E)
Figure 8 - Decomposition of functions into interacting LN on different levels: examples for generic function with telecontrol interface, protection function and measuring/metering function .......................................................................................... 38
Figure 9 - Example for control and protection LNs of a transformer bay combined in one physical device (sorne k\nd of maximum allocation) ........................................................ 39
Figure 1 O - Example for interaction of LNs for switchgear control, interlocking, synchrocheck, autoreclosure and protection .......................................................................... 39
Figure 11 - Example for sequential interacting of LNs (local and remate) for a complex function such as point-on-wave switching - Sequence view .................................................. 40
Figure 12 - Example for functional interacting of LNs (local and remate) for a complex function such as point-on-wave switching - Architecture view ............................................... 40
Figure 13 - Example for automatic tap changer control for voltage regulation ....................... 41
Figure 14 - Circuit breaker controllable per phase (one instance of XCBR per phase) and instrument transformers with measuring units per phase (one instance of TCTR or TVTR per phase) ................................................................................................................... 41
Figure 15 - Distributed busbar protection (LN instances of PBDF for central unit and for units per bay - left) and interlocking (LN instance of CILO) on bay leve! per switch/circuit breaker (right) ................................................................................................. .42
Figure 16 - Definition of overall transfer time ........................................................................ 45
Figure 1.1 - T1-1 small size transmission substation/ D2-1 medium size distribution substation ........................................................................................................................... 111
Figure 1.2 - T1-2 small size transmission substation with one and a half breaker scheme/T2-2 large size transmission substation with ring bus ............................................. 112
Figure 1.3 - Substation of type T1-1 with allocation functions .............................................. 114
Figure 1.4 - Substation of type 02-1 with allocated functions ............................................... 115
Figure 1.5 - Substation of type T1-2 (functions allocated in the same way as for T2-2 in Figure l.6 .................. , ...................................................................................................... 116
Figure 1.6 - Substation of type T2-2 with allocated functions ............................................... 117
Figure 1.7 - Large transmission substation with a ring similar to type T2-2 (function allocation described in Clause 1.2) ....................................................................................... 118
Figure 1.8 - Large transmission substation with a ring similar to T2-2 (function allocation see text below) .................................................................................................... 119
Figure 1.9 - Ethernet configuration with shared hub ............................................................. 128
Figure 1.1 O - Ethernet configuration with switched hubs ...................................................... 128
Figure J.1 - The transient earth fault in a compensated network ......................................... 129
Figure J.2 - Short term bypass for single earth fault in compensated networks ................... 130
Figure J.3 - The double earth fault in compensated networks ............................................. 130
Table 1 - Raw data for protection and control ...................................................................... .47
Table 2 - Raw data for metering ........................................................................................... 48
Table· A.1 - PICOM groups .................................................................................................... 53
Table A.2 - Logical node list ................................................................................................. 53
Table B.1 - ldentification and type allocation of PICOMs - Part 1 ......................................... 68
Table B.2 - ldentification and type allocation of PICOMs - Part 2 ......................................... 69
Table B.3 - ldentification and type allocation of PICOMs - Part 3 ......................................... 70
Table B.4 - ldentification and type allocation of PICOMs - Part 4 ......................................... 71
Table B.5 - PICOM types - Part 1 ......................................................................................... 72
Table B.6 - PICOM types - Part 2 ......................................................................................... 73
61850-5 © IEC:2003(E) -5-
Table H.1 -Function-function interaction -Part 1 ............................................................... 105
Table H.2 -Function-function interaction - Part 2 ............................................................... 106
Table H.3 -Function decomposition into Logical Nodes - Part 1 ........................................ 107
Table H.4 - Function decomposition into Logical Nodes - Part 2 ........................................ 108
Table H.5 - Function decomposition into Logical Nodes - Part 3 ........................................ 109
Table H.6 - Function decomposition into Logical Nodes - Part 4 ........................................ 11 O
Table 1.1 -Definition of the configuration of all substations evaluated ................................. 112
Table 1.2 -Overview of the main results of the performed calculations based on one common bus system covering all interfaces excluding interface 2 and 9 .............................. 113
Table 1.3 -Results for the substation T1-1 .......................................................................... 114
Table 1.4 - Results for the substation D2-1 .......................................................................... 115
Table 1.5 - Results for the substation T1-2 .......................................................................... 116
Table 1.6 - Results for the substation T1-2 .......................................................................... 117
Table 1.7 -Results for the substation according to Figure 1.7 (function allocation described in Clause 1.2) ...................................................................................................... 118
Table 1.8 -138 kV affected (faulted) lines and related messages ........................................ 121
Table 1.9 - Message delays of 38 -256 byte multicast messages on a shared hub network ............................................................................................................................... 122
Table 1.1 O -Message delays of 38 messages on a switched hub network ........................... 122
TableJ .. 11 -Message delays of a variable number of messages on a shared hub network ............................................................................................................................... 123
Table 1.12 - Message delays of a variable number of messages on a switched hub network ............................................................................................................................... 123
Table 1.13 -Summary table ................................................................................................ 124
Table 1.14 -_138 kV affected lines ....................................................................................... 125
Table 1.15-138 kV unaffected lines (per line) .................................................................... 125
Table 1.16 -Total f38 kV lines ............................................................................................ 125
Table 1.17 -345 kV affected lines/per line/per relay system -Relay 1 ................................ 126
Table 1.18-345 kV affected lines/per line/per relay system -Relay 2 ................................ 126
Table L 19 -345 kV affected lines/per line/system communications ..................................... 126
Table 1.20 -345 kV affected lines ....................................................................................... 127
Table 1.21 -345 kV unaffected lines/per line ....................................................................... 127
Table 1.22 -Total 345 kV lines ...................... , ...................................................................... 127
Table 1.23 -Total LAN ........................................................................................................ 127
-6- 61850-5 © IEC:2003(E)
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS-
Part 5: Communication requirements for functions and device models
FOREWORD
1) The lnternational Electrotechnical Commission (IEC) is a worldwide organization for standardization comprisingall national electrotechnical committees (IEC National Committees). The object of IEC is to prometeinternational co-operation on all questions concerning standardization in the electrical and electronic fields. Tothis end and in addition to other activities, IEC publishes lnternational Standards, Technical Specifications,Technical Reports, and Guides (hereafter referred to as 'IEC Publication(s)'). Their preparation is entrusted to technical committees; any IEC National Committee interested in the subject dealt with may participate in thispreparatory work. lnternational, governmental and non-governmental organizations liaising with the IEC alsoparticipate in this preparation. IEC collaborates closely with the lnternational Organization for Standardization(ISO) in accordance with conditions determined by agreement between the two organizations.
2) The formal decisions or agreements of IEC on technical matters express, as nearly as possible, an internationalconsensus of opinion on the relevant subjects since each technical committee has representation from allinterested IEC National Committees.
3) IEC Publications have the form of recommendations for international use and are accepted by IEC NationalCommittees in that sense. While all reasonable efforts are made to ensure that the technical content of IECPublications Js accurate, IEC cannot be held responsible for the way in which they are used or for anymisinterpretation by any end user.
4) In order to promete international uniformity, IEC National Committees undertake to apply IEC Publicationstransparently to the maximum extent possible in their national and regional publications. Any divergencebetween any IEC Publication and the corresponding national or regional publication shall be clearly indicated in the latter.
5) IEC provides no marking1 procedure to indicate its approval and cannot be rendered responsible for anyequipment declared to be in conformity with an IEC Publication.
6) AII users should ensure that they have the lates! edition of this publication.
7) No liability shall attach to IEC or its directors, employees, servants or agents including individual experts andmembers of its technical committees and IEC National Committees for any personal injury, property damage orother damage of any nature whatsoever, whether direct or indirect, or for costs (including legal fees) and expenses arising out of the publication, use of, or reliance upon, this IEC Publication or any other IEC Publications.
8) Attention is drawn to the Normative references cited in this publication. Use of the referenced publications is indispensable for the corree! application of this publication.
9) Attention is drawn to the possibility that sorne of the elements of this IEC Publication may be the subject ofpatent rights. IEC shall not be held responsible for identifying any or all such patent rights.
lnternational Standard IEC 61850-5 has been prepared by IEC technical committee 57: Power system control and associated communications.
The text of this standard is based on the following documents:
FDIS Report on voting
57/641/FDIS 57/649/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 2.
61850-5 © IEC:2003(E) -7-
The content of this part of I EC 61850 is based on existing or emerging standards and applications. In particular the approach to formulate the requirements is based upon
CIGRE Technical Report, Ref. No. 180, Communication requirements in terms of data flow within substations. CE/SC 34 03, 2001, 112 pp. Ref. No. 180
K.P. Brand, Communication requirements in terms of data flow within substations - Results of WG34.03 and standardization within IEC, Electra 173, 77-85 (1997)
IEEE-SA TR 1550-2003: IEEE-SA Technical Report on Utility Communications Architecture (UCA
™), Version 2.0, Part 4: UCA Generic Object Models for Substation and Feeder
Equipment (GOMSFE).
IEC 61850 consists of the following parts, under the general title Communication networks and systems in substations.
Part 1:
Part 2:
Part 3:
Part 4:
Part 5:
Part 6:
lntroduction and overview
Glossary 1
General requirements
System and project management
Communication requirements for functions and device models
Configuration description language for communication in electrical substations related to IEDs 2
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
Part 7-4: 8qsic communication structure for substation and feeder equipment - Compatible logical node classes and data classes
Part 8-1: Specific communication service mapping (SCSM) - Mappings to MMS (ISO/IEC 9506-1 and ISO/IEC 9506-2) and to ISO/IEC 8802-3 2
Part 9-1: Specific communication service mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
Part 9-2: Specific communication service mapping (SCSM) - Sampled values over ISO/IEC 8802-3
2
Part 1 O: Conformance testing 2
This publication has been drafted in accordance with the 1SO/IEC Directives, Part 2.
The committee has decided that the contents of this publication will remain unchanged until 2005. At this date, the publication will be
reconfirmed;
withdrawn;
replaced by a revised edition, or
amended.
1 To be published.
2 Under consideration.
-8- 61850-5 © IEC:2003(E)
INTRODUCTION
The IEC 61850 series is intended to provide interoperability between all devices in substations. Communication between these devices has to fulfil a lot of requirements imposed by all the functions to be per,formed in substations. Depending on the philosophy both of the vendor and of the user and on the state-of-the-art in technology, the allocation of functions to devices and control levels is not commonly fixed. This results in different requirements for the different communication interfaces within the substation. The IEC 61850 series shall support any allocation of functions.
The IEC 61850 series should have a long lifetime but be able to follow the fast changes in communication technology by both its technical approach and its document structure. Figure 1 shows the relationship of this part of the IEC 61850 series to subsequent parts of the IEC 61850 series. The IEC 61850 series has been organized so that changes to one part do not require a significant rewriting of another part, i.e. the parts are based on the communication requirements in this part of the IEC 61850 series; the derived modelling requirements in subsequent parts will not change the requirements of this part of the IEC 61850 series. The general parts, the requirement specification and the modelling parts are independent from any implementation. The implementation needed for the use of the IEC 61850 series is defined in sorne dedicated parts.
This part of the IEC 61850 series defines the communication requirements for functions and device models for substations.
The modelling of communication requires the definition of objects (for example, data objects, data sets, report control, log control) and services provided by objects (for example, get, set, report, create, delete). This is defined in IEC 61850-7-x with a clear interface to implementation. To use the benefits of communication technology, in the IEC 61850 series, no new OSI stacks are defined but a standardized mapping on existing stacks is given in IEC 61850-8-x and IEC 61850-9-x. A substation configuration language (IEC 61850-6) and a standardized conforman.ce testing complement the IEC 61850 series. Figure 1 shows the general structure of the documents of the IEC 61850 series, as well as the relative position of IEC 61850-5 within this series.
NOTE To keep the layered approach of the IEC 61850 series which does not mix application and implementation requirements, terms such as client, server, data objects, etc. are normally not used in this part of the IEC 61850 series (requirements). In IEC 61850-7-x (modeling), IEC 61850-8-x and IEC 61850-9-x (specific communication service mapping) terms belonging to application requirements such as PICOMs are normally not used.
IEC 61850-10 Confonnance
tasting
IEC 61850-6 Substation configumtion
language
IEC 61850-8-x IEC 61850-9-x
Specmc communlcation servlce mapplng
IEC 61850-7-4 Compatible loglcal noda and
data object adresslng
IEC 61850-7-3 Common data classos and
altributes
IEC 61850-7-2 Abstract communication sorvica Interface (ACSI)
IEC 61850-7-1 Communlcation reference
modol
IEC tg(>J,03
Figure 1 - Relative position of this part of the IEC 61850 series
61850-5 © IEC:2003(E) -9-
1 Scope
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS -
Part 5: Communication requirements for functions and device models
This part of IEC 61850 applies to Substation Automation Systems (SAS). lt standardizes the communication between intelligent electronic devices (IEOs) and the related system requirements.
The specifications of this part refer to the communication requirements of the functions being performed in the substation automation system and to device models. AII known functions and their communication requirements are identified.
The description of the functions is not used to standardize the functions, but to identify communication requirements between technical services and the substation, and communication requirements between lntelligent Electronic Oevices within the substation. The basic goal is interoperability for all interactions.
Standardizing functions and their implementation is completely outside the scope of this part of IEC 61850. Therefore, a single philosophy for allocating functions to devices cannot be assumed in the IEC 61850 series. To support the resulting request for free allocation of functions, a proper breakdown of functions into parts relevant for communication is defined. The exchanged data and their required performance are defined. These definitions are supplemented by informative data flow calculations for typical substation configurations.
lntelligent electronic devices from substations such as protective devices are also found in other installations such as power plants. Using this part of IEC 61850 for such devices in these plants also would facilitate the system integration but this is beyond the scope of this part of IEC 61850.
2 Normative references
The following referenced documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies.
IEC 60044-8, lnstrument transformers - Part 8: Electronic current transformers
IEC 60870-4, Telecontrol equipment and systems - Part 4: Performance requirements
IEC 61346 (all parts), Industrial systems, instal/ations and equipment and industrial products -Structuring principies and reference designations
IEC 61850-2, Communication networks and system in substations - Part 2: Glossary 3
IEC 62053-22, Electricity metering equipment (a.c.) - Particular Requirements - Part 22: Static meters for active energy (classes 0,2 S and O, 5 S)
3 To be published.
-10- 61850-5 © IEC:2003(E)
IEEE Std C37.2:1996, IEEE Standard Electrlcal Power System Devlce Functlon Numbers and Contact Designations
NOTE Informativa references are found In the Blbllography.
INTERNATIONAL
STANDARD
IEC
61850-7-1
First edition
2003-07
Communication networks and systems in substations -
Part 7-1: Basic communication structure for substation and feeder equipment -Principies and models
© IEC 2003 - Copyright - all rights reserved
No part of this publicatlon may be reproduced or utillzed In any form or by any means, electronlc or mechanlcal, lncludlng photocopying and microfilm, wlthout permlsslon In writlng from the publisher.
lntemational Electrotechnlcal Commissi(?n, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Switze�and
Telephone: +41 22 919 02 11 Telefax: +41 22 919 03 00 E-mail: lnmall@iec.ch Web: www.lec.ch
Commission Electrotechnique lnternationale lnternational Electrotechnical Comm ission Me)t(,llyHapOAH8ff 3neKTpOT8XHM�8CK8ff KOMMCCMR
PRICE CODE XE
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-2- 61850-7-1 © IEC:2003(E)
CONTENTS
FOREWORD .......................................................................................................................... 7
INTRODUCTION .................. .' ................................................................................................. 9
1 Scope ............................................................................................................................. 11
2 Normative references ...................................................................................................... 12
3 Terms and definitions ..................................................................................................... 12
4 Abbreviated terms ........................................................................................................... 13
5 Overview of concepts the IEC 61850 series .................................................................... 13
5.1 Objective ............................................................................................................... 13 5.2 Topology and communication functions of substation automation systems ............. 14 5.3 The information models of substation automation systems ..................................... 15 5.4 Applications modelled by logical nodes defined in IEC 61850-7-4 .......................... 16 5.5 The semantic is attached to data ........................................................................... 19 5.6 The services to exchange information .................................................................... 21 5.7 Services mapped to concrete communication protocols ......................................... 22 5.8 The configuration of a substation ........................................................................... 23 5.9 Summary ............................................................................................................... 23
6 Modelling approach of the IEC 61850 series ................................................................... 24
6.1 Decomposition of application functions and information ......................................... 24 6.2 Creating information models by stepwise composition ........................................... 26 6.3 Example of an IED composition ............................................................................. 29 6.4 lnformation exéhange models ................................................................................ 29
7 Application view .............................................................................................................. 42
7.1 lntroduction ........................................................................................................... 42 7.2 First modelling step - Logical nodes and data ...................................................... .44
8 Device view .................................................................................................................... 47
8.1 lntroduction ........................................................................................................... 47 8.2 Second modelling step - logical device model ....................................................... 47
9 Communication view ....................................................................................................... 49
9.1 The service models of the IEC 61850 series .......................................................... 49 9.2 The virtualisation ................................................................................................... 52 9.3 Basic information exchange mechanisms ............................................................... 53 9.4 The client-server building blocks ............................................................................ 54 9.5 Interfaces inside and between devices ................................................................... 57
10 Where physical devices, application models and communication meet. ........................... 58 11 Relationships between IEC 61850-7-2, IEC 61850-7-3 and IEC 61850-7-4 ...................... 59
11.1 Refinements of class definitions ............................................................................ 59 11.2 Example 1 - Logical node and data class .............................................................. 60 11.3 Example 2- Relationship of IEC 61850-7-2, IEC 61850-7-3, and
IEC 61850-7-4 ....................................................................................................... 62 12 Mapping the ACSI to real communication systems .......................................................... 64
12.1 lntroduction ...................................... : .................................................................... 64 12.2 Mapping example (IEC 61850-8-1) ......................................................................... 66
61850-7-1 © IEC:2003(E) -3-
13 Formal specification method ........................................................................................... 71
13.1 Notation of ACSI classes ....................................................................................... 71
13.2 Class modelling ..................................................................................................... 72
13.3 Service tables ........................................................................................................ 77
13.4 Referencing instances ........................................................................................... 78
14 Name spaces .................................................................................................................. 80
14.1 General ................................................................................................................. 80
14.2 Name spaces defined in IEC 61850-7-x ................................................................. 82
14.3 Specification of name spaces ................................................................................ 85
14.4 Attributes for references to name spaces ............................................................... 87
14.5 Common rules for extensions of name spaces ....................................................... 89
15 Approaches for the definition of a new semantic ............................................................. 91
15.1 General ................................................................................................................. 91
15.2 Semantic for new definition .................................................................................... 92
15.3 Approach 1 (fixed semantic) .................................................................................. 92
15.4 Approach 2 (flexible semantic) ............................................................................... 92
15.5 Approach 3 (reusable flexible semantic) ................................................................ 93
Annex A (informative) Overview of IEC 61850-7-x, IEC 61850-8-x, and IEC 61850-9-x ........ 94
Annex B (informative) Allocation of data to logical nodes ..................................................... 97
Annex C (informative) Use of the substation configuration language (SCL} ........................ 100
Annex D (informative) Applying the LN concept to options for future extensions ................. 102
Annex E (informative) Relation between logical nodes and PICOMs ................................... 107
Annex F (informative) Relation between IEC 61850-7-x (IEC 61850-8-x) and UCA 2.0® ..... 108
Bibliography ........................................................................................................................ 109
lndex ................................................................................................................................... 111
Figure 1 - Sample substation automation topology ................................................................ 14
Figure 2 - Modelling approach (conceptual) .......................................................................... 15
Figure 3 - Logical node information categories ..................................................................... 18
Figure 4 - Build up of devices (principle) ............................................................................... 18
Figure 5 - Position information depicted as a tree (conceptual) ............................................. 19
Figure 6 - Service excerpt .................................................................................................... 21
Figure 7 - Example of communication mapping ..................................................................... 22
Figure 8 - Summary ...................................................................... : ....................................... 24
Figure 9 - Decomposition and composition process (conceptual) .......................................... 25
Figure 10 - XCBR1 information depicted as a tree ................................................................ 28
Figure 11 - Example of IED composition ............................................................................... 29
Figure 12 - Output and Input model (principle) ...................................................................... 30
Figure 13 - Output model (step 1) ·(conceptual) .................................................................... 31
Figure 14 - Output model (step 2) (conceptual} .................................................................... 31
Figure 15 - GSE output model (conceptual) .......................................................................... 32
Figure 16 - Setting data (conceptual) .................................................................................... 33
-4- 61850-7-1 © IEC:2003(E)
Figure 17 - Input model for analogue values (step 1) (conceptual) ....................................... 34
Figure 18 - Deadbanded value (conceptual) ........................................................................ 35
Figure 19 -Input model for analogue values (step 2) (conceptual) ....................................... 35
Figure 20 - Range values ..... ,. ............................................................................................... 36
Figure 21 -Reporting and logging model (conceptual) .......................................................... 36
Figure 22 -Data set members and reporting ......................................................................... 37
Figure 23 - Buffered report control block (conceptual) ......................................................... 38
Figure 24 -Buffer time .......................................................................................................... 39
Figure 25 - Data set members and inclusion-bitstring ........................................................... 40
Figure 26 -Log control block - conceptual ............................................................................ 40
Figure 27 -Peer-to-peer data value publishing model (conceptual) ..................................... .41
Figure 28 -Real world devices ............................................................................................. 43
Figure 29 -Logical no des and data (1 EC 61850-7-2) ............................................................. 44
Figure 30 - Simple example of modelling .............................................................................. 45
Figure 31 -Basic building blocks ......................................................................................... .45
Figure 32 - Logical nodes and PICOM .................................................................................. 46
Figure 33 - Logical nodes connected (outside view in IEC 61850-7-x) ................................. .46
Figure 34 - Logical device building block .............................................................................. 47
Figure 35 -Logical devices and LLN0/LPHD ......................................................................... 48
Figure 36 - Logical devices in proxies or gateways .............................................................. .49
Figure 37 - ACSI communication methods ............................................................................ 50
Figure 38 -Virtualisation ...................................................................................................... 52
Figure 39 -VirtualisatiorY and usage ..................................................................................... 52
Figure 40 -lnformation flow and modelling ........................................................................... 53
Figure 41 -Application of the GSE model ............................................................................. 53
Figure 42 - Server building blocks ........................................................................................ 54
Figure 43 -lnteraction between application process and application layer (client/server) ........................................................................................................................ 55
Figure 44 - Example for a service ...... : .................................................................................. 55
Figure 45 - Client/server and logical nodes ........................................................................... 56
Figure 46 -Client and server role ......................................................................................... 56
Figure 4 7 - Logical nodes communicate with logical no des ................................................... 57
Figure 48 -Interfaces inside and between devices ............................................................... 57
Figure 49 - Component hierarchy of different views (excerpt) ............................................... 58
Figure 50 - Refinement of the DATA class ............................................................................ 59
Figure 51 - lnstances of a DATA class (conceptual) .............................................................. 62
Figure 52 - Relation between parts of the IEC 61850 series ................................................. 63
Figure 53 - ACSI mapping to an application layer ................................................................. 64
Figure 54 - ACSI mappings (conceptual) .............................................................................. 65
Figure 55 - ACSI mapping to communication stacks/profiles ................................................. 66
Figure 56 - Mapping to MMS (conceptual) ............................................................................ 66
Figure 57 - Mapping approach .............................................................................................. 67
Figure 58 - Mapping detail of mapping to a MMS named variable ......................................... 68
61850-7-1 © IEC:2003(E) -5-
Figure 59 -Example of MMS named variable (process values) ............................................. 68
Figure 60 -Use of MMS named variables and named variable list ........................................ 69
Figure 61 - MMS lnformation Report message ...................................................................... 70
Figure 62 -Mapping example ................................................................................................ 71
Figure 63 -Abstract data model example for IEC 61850-7 .................................................... 73
Figure 64 -Relation of TrgOp and Reporting ........................................................................ 76
Figure 65 - Sequence diagram ............................................................................................. 78
Figure 66 -References ......................................................................................................... 78
Figure 67 -Use of FCD and FCDA ....................................................................................... 79
Figure 68 -Object names and object reference .................................................................... 80
Figure 69 -Definition of names and semantics ..................................................................... 81
Figure 70 - One name with two meanings ............................................................................. 81
Figure 71 - Name space as class repository ......................................................................... 82
Figure 72 -AII instances derived from classes in a single name space ................................. 83
Figure 73 - lnstances derived from multiple name spaces ..................................................... 84
Figure 74 -lnherited name spaces ....................................................................................... 84
"Figure 75 - Example of logical node and data name spaces ................................................. 86
Figure 76 -Example common data class name spaces ......................................................... 87
Figure 77 - Extensions of name spaces (conceptual) ............................................................ 90
Figure 78 - Use of extended name space (conceptual) ......................................................... 91
Figure A.1 - Overall communication system architecture ....................................................... 94
Figure 8.1 -Example for control and protection LNs combined in one physical device .......... 97
Figure 8.2 -Merging unit and sampled value exchange (topology) ....................................... 98
Figure 8.3 - Merging unit and sampled value exchange (data) .............................................. 98
Figure C.1 -Application of SCL for LNs (conceptual) .......................................................... 100
Figure C.2 -Application of SCL for data (conceptual) ......................................................... 101
Figure D.1 - Seamless communication (simplified) .............................................................. 102
Figure D.2 - Example for new logical nodes ........................................................................ 103
Figure D.3 - Example for control center view and mapping to substation view ..................... 105
Figure E.1 -Exchanged data between subfunctions (logical nodes) .................................... 107
Figure E.2 - Relationship between PICOMS and client/server model .................................. 107
Figure F.1 - Relation between the IEC 61850 series and UCA ............................................ 108
Table 1 - Guide for the reader .............................................................................................. 1 O
Table 2 - LN groups ............................................................................................................... 16
Table 3 -Logical node class XC8R (conceptual) .................................................................. 27
Table 4 -Excerpt of integer status setting ............................................................................ 33
Table 5 - Comparison of the data access methods ............................................................... 37
Table 6 - ACSI models and services ..................................................................................... 50
Table 7 -Logical node circuit breaker ................................................................................... 60
Table 8 - Controllable double point (DPC) ............................................................................ 61
Table 9 - ACSI class definition .............................................................................................. 72
Table 10 - Single point status common data class (SPS) ....................................................... 74
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Table 11 - Quality components attribute definition ................................................................ 7 4
Table 12 - Basic status information template (excerpt) ......................................................... 75
Table 13 - Trigger option ...................................................................................................... 75
Table 14 - Logical node class (LN) definition ........................................................................ 76
Table 15 - Excerpt of logical node name plate common data class (LPL) .............................. 87
Table 16 - Excerpt of common data class ............................................................................. 88
Table A.1 - Excerpt of data classes for measurands ............................................................. 95
Table A.2 - List of common data classes .............................................................................. 96
61850-7-1 © IEC:2003(E) -7-
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
FOREWORD
1) The lnternational Electrotechnical Commission (IEC) is a worldwide organization for standardization comprisingali national electrotechnical committees (IEC National Committees). The object of IEC is to promoteinternational co-operation on ali questions concerning standardization in the electrical and electronic fields. Tothis end and in addition to other activities, IEC publishes lnternational Standards, Technical Specifications,Technical Reports, and Guides (hereafter referred to as 'IEC Publication(s)'). Their preparation is entrusted totechnical committees; any IEC National Committee interested in the subject dealt with may participate in thispreparatory work. lnternational, governmental and non-governmental organizations liaising with the IEC alsoparticipate in this preparation. IEC collaborates closely with the lnternational Organization for Standardization(ISO) in accordance with conditions determinad by agreement between the two organizations.
2) The formal decisions or agreements of IEC on technical matters express, as nearly as possible, an internationalconsensus of opinion on the relevan! subjects since each technical committee has representation from allinterested IEC National Committees.
3) IEC Publications have the form of recommendations for international use and are accepted by IEC NationalCommittees in that sense. While all reasonable efforts are made to ensure that the technical content of IECPublications is accurate, IEC cannot be held responsible for the way in which they are used or for any misinterpretation by any end user.
4) In order to promote internatíonal uniformity, IEC National Committees undertake to apply IEC Publicationstransparently to the maximum extent possible in their national and regional publications. Any divergencebetween any IEC Publication and the corresponding national or regional publication shall be clearly indicated in the latter.
5) IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for any equipment declared to be in, conformity with an IEC Publication.
6) AII users should ensure that they have the lates! edition of this publication.
7) No liability shall attach to IEC or its directors, employees, servants or agents including individual experts and members of its technical committees and IEC National Committees for any personal injury, property damage orother damage of any nature whatsoever, whether direct or indirect, or for costs (including legal fees) andexpenses arising out of the publication, use of, or reliance upon, this IEC Publication or any other IECPublications.
8) Attention is drawn to the Normative references cited in this publication. Use of the referenced publications is indispensable for the corree! application of this publication.
9) Attention is drawn to the possibility that sorne of the elements of this IEC Publication may be the subject of patent rights. IEC shall not be held responsible for identifying any or all such patent rights.
lnternational Standard IEC 61850-7-1 has been prepared by IEC technical committee 57: Power system control and associated communications.
The text of this standard is based on the following documents:
FDIS Report on voting
57/637/FDIS 57/646/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IE(¡ Directives, Part 2.
-8- 61850-7-1 © IEC:2003(E)
IEC 61850 consists of the following parts, under the general title Communication networks and systems in substations.
Part 1: lntroduction and overview
Part 2: Glossary 1
Part 3: General requirements
Part 4: System and project management
Part 5: Communication requirements for functions and device models
Part 6: Configuration description language for communication in electrical substations related to IEDs 2
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
Part 7-4: Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes
Part 8-1: Specific communication service mapping (SCSM) - Mappings to MMS (ISO/IEC 9506-1 and ISO/IEC 9506-2) and to ISO/IEC 8802-3 2
Part 9-1: Specific communication service mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
Part 9-2: Specific communication service mapping (SCSM) - Sampled values over ISO/IEC 8802-3 2
Part 1 O: Conformance testing 2
The content of this part is based on existing or emerging standards and applications.
The committee has decided that the contents of this publication will remain unchanged until 2005. At this date, the publication will be
reconfirmed;
withdrawn;
replaced by a revised edition, or
amended.
A bilingual version of this standard may be issued at a later date.
1 To be published.
2 Under consideration.
61850-7-1 © IEC:2003(E) -9-
INTRODUCTION
This part of the IEC 61850 series provides an overview of the architecture for communication and interactions between substation devices such as protection devices, breakers, transformers, substation host� etc.
This document is part of a set of specifications which details a layered substation communication architecture. This architecture has been chosen to provide abstract definitions of classes (representing hierarchical information models) and services such that the specifications are independent of specific protocol stacks, implementations, and operating systems.
The goal of the IEC 61850 series is to provide interoperability between the IEDs from different suppliers or, more precisely, between functions to be performed in a substation but residing in equipment (physical devices) from different suppliers. lnteroperable functions may be those functions that represent interfaces to the process (for example, circuit breaker) or substation automation functions such as protection functions. This part of the IEC 61850 series uses simple examples of functions to describe the concepts and methods applied in the IEC 61850
series.
This part of the IEC 61850 series describes the relationships between other parts of the IEC 61850 series. Finally this part defines how inter-operability is reached.
NOTE lnterchangeability, i.e. the ability to replace a device from the same vendor, or from different vendors, utilising the same communication interface and as a mínimum, providing the same functionality, and with no impact on the rest of the system. lf differences in functionality are accepted, the exchange may require sorne changes somewhere in the system also. lnterchangeability implies a standardisation of functions and, in a strong sense, of devices which are both outside the scope of this standard. lnterchangeability is outside the scope, but it will be supported following this standard for interoperability.
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Table 1 - Guide for the reader
IEC User IEC IEC IEC IEC IEC IEC IEC 61850-8-x
61850-1 61850-5 61850-7-1 61850-7-4 61850-7-3 61850-7-2 61850-61
IEC 61850-9-x
.
(lntroduc- (Require- (Principies) (Logical (Common (lnform- (Configur-(Concrete tion and ments) nades and data ation ation
overview) data classes) exchange) language) communi-
classes) cation stack)
>,, Manager X - Clause 5 - - - - -
In :::, Engineer X X X X X X
extracts -
Application X X X X
In In engineer
X extracts
X extracts
Communi-.. cation X X X - - X - X
engineer e
Product In In In X X X X
extracts extracts extracts -
manager
Marketing Clause 5 In In In In
X X extracts extracts extracts extracts
-
Application X X X X X - X -
engineer e
Communi-., 1 e cation X - X - - X X X
engineer
AII others X X X - - - - -
The 'x' means that this part of the IEC 61850 series should be read.
The 'in extracts' means that extracts of this part of the IEC 61850 series should be read to understand the conceptual approach used.
The ·-· means that this part of the IEC 61850 series may be read.
• These documents are under consideration.
This part of the IEC 61850 series is intended for all stakeholders of standardised communication and standardised systems in the utility industry. lt provides an overview of and an introduction to IEC 61850-7-4, IEC 61850-7-3, IEC 61850-7-2, IEC 61850-6, and IEC 61850-8-1.
Table 1 provides a simplified guide as to which parts of the IEC 61850 series should be read by various stakeholders. Four groups are shown: utility, vendar, various consultants, and others.
61850-7-1 © IEC:2003(E) - 11 -
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS -
1 Scope
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
This part of the IEC 61850 series introduces the modelling methods, communication principies, and information models that are u sed in the parts of I EC 61850-7-x. The purpose of this part of the IEC 61850 series is to provide - from a conceptual point of view -
assistance to understand the basic modelling concepts and description methods for:
- substation-specific information models for substation automation systems,
- device functions used for substation automation purposes, and
- communication systems to provide interoperability within substations.
Furthermore, this part of the IEC 61850 series provides explanations and provides detailed requirements relatin_g to the relation between IEC 61850-7-4, IEC 61850-7-3, IEC 61850-7-2 and IEC 61850-5. This part explains how the abstract services and models of IEC 61850-7-x are mapped to concrete communication protocols as defined in IEC 61850-8-1.
The concepts and models provided in this part of the IEC 61850 series may also be applied to describe information models and functions for:
- substation to substation information exchange,
- substation to control centre information exchange,
- information exchange for distributed automation,
- information exchange for metering,
- condition monitoring and diagnosis, and
- information exchange with engineering systems for device configuration.
NOTE 1 This part of IEC 61850 uses examples and excerpts from other parts of the IEC 61850 series. These excerpts are used to explain concepts and methods. These examples and excerpts are informative in this part of IEC 61850.
NOTE 2 Examples in this part use names of classes (e.g. XCBR for a class of a logical node) defined in IEC 61850-7-4, IEC 61850-7-3, and service names defined in IEC 61850-7-2. The normative names are defined in IEC 61850-7-4, IEC 61850-7-3, and IEC 61850-7-2 only.
NOTE 3 This part of IEC 61850 does not provide a comprehensive tutorial. lt is recommended that this part be read first - in conjunction with IEC 61850-7-4, IEC 61850-7-3, and IEC 61850-7-2. In addition, it is recommended that IEC 61850-1 and IEC 61850-5 also be read.
NOTE 4 This part of IEC 61850 does not discuss implementation issues.
-12 - 61850-7-1 © IEC:2003(E)
2 Normative references
The following referenced documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (iilcluding any amendments) applies.
IEC 61850-2, Communication networks and systems in substations - Part 2: G/ossary 3
IEC 61850-5, Communication networks and systems in substations - Part 5: Communicationrequirements for functions and devices mode/s
3
IEC 61850-7-2, Communication networks and systems in substations - Part 7-2: Basiccommunication structure for substation and feeder equipment - Abstract communicationservice interface (ACSI)
IEC 61850-7-3, Communication networks and systems in substations - Part 7-3: Basiccommunication structure for substation and feeder equipment - Common data classes
IEC 61850-7-4, Communication networks and systems in substations - Part 7-4: Basiccommunication structure for substation and feeder equipment - Compatible logical nodec/asses and data classes
ISO/IEC 8802-3:2000, lnformation technology - Te/ecommunications and information exchange between systems - Local and metropolitan area networks - Specific requirements -Part 3: Carrier sense mu/tiple access with col/ision detection (CSMAICD) access method and physica/ /ayer specifications
ISO/IEC 8825 (all parts), lnformation technology- ASN.1 encoding rules
ISO 9506-1 :2003, Industrial automation systems - Manufacturing Message Specification -
Part 1: Service definition
ISO 9506-2:2003, Industrial automation systems - Manufacturing Message Specification -
Part 2: Protocol specification
INTERNATIONAL
STANDARD
Communication networks and systems in substations -
Part 7"!3_: Basic communication structure
IEC
61850-7-3
First edition
2003-05
for substation and feeder equipment -Common data classes
© IEC 2003 - Copyright - ali rights reserved
No part of this publication may be reproduced or utlllzed In any form or by any means, electronic or mechanical, includlng photocopying and microfilm, without permission in writing from the publisher.
lntemational Electrotechnical Commission, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Switzerland
Telephone: +41 22 919 02 11 Telefax: +41 22 919 03 00 E-mail: inmall@iec.ch Web: www.iec.ch
Commission Electrotechnique lnternationale lnternational Electrotechnical Comm ission Me)l(JlyHapOAH8R 3neKTpOT8XHH�eCK8R KOMHCCHR
PRICE CODE XB
For prica, sea current catalogue
-2-
CONTENTS
61850-7-3 © IEC:2003(E)
FOREWORD .......................................................................................................................... 6
INTRODUCTION .................................................................................................................... 8
1 Scope ............................. : ................................................................................................ 9
2 Normati:ve references ....................................................................................................... 9
3 Terms and definitions ..................................................................................................... 1 o
4 Abbreviated terms ........................................................................................................... 1 o
5 Conditions for attribute inclusion ..................................................................................... 1 o
6 Common data attribute types .......................................................................................... 11
6.1 General ................................................................................................................. 11
6.2 Quality ................................................................................................................... 11
6.2.1 Overview .................................................................................................... 11
6.2.2 Validity ....................................................................................................... 12
6.2.3 Detail quality .............................................................................................. 12
6.2.4 Source ....................................................................................................... 13
6.2.5 Test ........................................................................................................... 14
·6.2·.6 B1-o·cked by operator ................................................................................... 14
6.2. 7 Quality in the client server context. ............................................................ 14
6.2.8 Relation between quality identifiers ............................................................ 15
6.3 Analogue value ...................................................................................................... 17
6.4 Configuration of analogue value ............................................................................ 17
6.5 Range configuration ............................................................................................... 18
6.6 Step position with transient indication .................................................................... 18
6.7 Pulse configuration ................................................................................................ 19
6.8 Originator .............................................................................................................. 19
6.9 Unit definition ........................................................................................................ 20
6.1 O Vector definition ..................................................................................................... 20
6.11 Point definition ....................................................................................................... 21
6.12 CtlModels definition ............................................................................................... 21
6.13 SboClasses definition ............................................................................................ 21
7 Common data class specifications .................................................................................. 21
7.1 General ................................................................................................................. 21
7.2 Name spaces ......................................................................................................... 21
7.3 Common data class specifications for status information ....................................... 22
7.3.1 Basic status information template .............................................................. 22
7.3.2 Single point status (SPS) ........................................................................... 22
7.3.3 Double point status (DPS) .......................................................................... 23
7.3.4 lnteger status (INS) .................................................................................... 24
7.3.5 Protection activation information (ACT) ...................................................... 24
7.3.6 Directional protection activation information (ACD) .................................... 25
7 .3. 7 Security violation counting (SEC) ............................................................... 25
7.3.8 Binary counter reading (BCR) .................................................................... 26
7.4 Common data class specifications for measurand information ............................... 27
7.4.1 Basic measurand information template ....................................................... 27
7 .4.2 Measured val u e (MV) ................................................................................. 28
7.4.3 Complex measured value (CMV) ................................................................ 29
7.4.4 Sampled value (SAV) ................................................................................. 30
61850-7-3 © IEC:2003(E) -3-
7.4.5 Phase to ground related measured values of a three phase system (WYE) 31
7.4.6 Phase to phase related measured values of a three phase system (DEL) ... 32
7.4. 7 Sequence (SEQ) ........................................................................................ 33
7.4.8 Harmonic Value (HMV) .............................................................................. 34
7.4.9 Harmonic value for WYE (HWYE) .............................................................. 35
7.4.10 Harmonic value for DEL (HDEL) ................................................................. 36
7.5 Common data class specifications for controllable status information .................... 37
7.5.1 Application of services ............................................................................... 37
7.5.2 Controllable single point (SPC) .................................................................. 38
7.5.3 Controllable double point (DPC) ................................................................. 39
7.5.4 Controllable integer status (INC) ................................................................ 40
7.5.5 Binary controlled step position information (BSC) ..................................... .41
7.5.6 lnteger controlled step position information (ISC) ....................................... 42
7.6 Common data class specifications for controllable analogue information ............... 43
7.6.1 Application of services ............................................................................... 43
7.6.2 Controllable analogue set point information (APC) ..................................... 44
7.7 Common data class specifications for status settings ............................................. 45
7. 7 .1 Application of services ............................................................................... 45
7.7.2 Single point setting (SPG) .......................................................................... 45
7.7.3 lnteger status setting (ING) ........................................................................ 46
7.8 Common data class specifications for analogue settings ........................................ 47
7.8.1 Application of services .............................................................................. .47
7.8.2 Analogue setting (ASG) ............................................................................. 47
7.8.3 Setting curve (CURVE) ............................................................................. .48
7.9 Common data class specifications for description information ................................ 49
7.9.1 Basic description information template ....................................................... 49
7.9.2 Device name plate (DPL) ........................................................................... 49
7.9.3 Logical node name plate (LPL) .................................................................. 50
7.9.4 Curve shape description (CSD) .................................................................. 50 8 Data attribute semantic ................................................................................................... 51
Annex A (normative) Val u e range for units and multiplier ..................................................... 60
Annex B (informative) Functional constraints ....................................................................... 63
Figure 1 - Quality identifiers in a single client - server relationship ....................................... 14
Figure 2 - Quality identifiers in a multiple client - server relationship .................................... 15
Figure 3 - lnteraction of substitution and validity ................................................................... 16
Figure 4 - Configuration of command output pulse ................................................................ 19
Table 1 - Quality ................................................................................................................... 11
Table 2 - Analogue val u e ...................................................................................................... 17
Table 3 - Configuration of analogue value ............................................................................ 17
Table 4 - Range configuration .............................................................................................. 18
Table 5 - Step position with transient indication .................................................................... 18
Table 6 - Pulse configuration ...................................................................... _. ......................... 19
Table 7 - Originator .............................................................................................................. 19
Table 8 - Values for orCat .................................................................................................... 20
-4- 61850-7-3 © IEC:2003(E)
Table 9 - Unit ....................................................................................................................... 20
Table 1 O - Vector .................................................................................................................. 20
Table 11 - Point .................................................................................................................... 21
Table 12 - Name space attributes ......................................................................................... 22
Table 13 - Basic status information template ........................................................................ 22
Table 14 - Single point status common data class definition ................................................. 23
Table 15 - Double point status common data class specification ........................................... 23
Table 16 - lnteger status common data class specification ................................................... 24
Table 17 - Protection activation information common data class specification ....................... 24
Table 18 - Directional protection activation information common data class specification .... 25
Table 19 - Security violation counting common data class specification ................................ 25
Table 20 - Binary counter reading common data class specification ..................................... 26
Table 21 - Basic measurand information template ................................................................ 27
Table 22 - Meas u red val u e ................................................................................................... 28
Table 23 - Complex measured value ..................................................................................... 29
Table 24 - Sampled value ..................................................................................................... 30
Tab_le 25 - WYE .................................................................................................................... 31
Table 26 - Delta .................................................................................................................... 32
Table 27 - Sequence ............................................................................................................ 33
Table 28 - Harmonic value .................................................................................................... 34
Table 29 - Harmonic values for WYE .................................................................................... 35
Table 30 - Harmonic values for delta .................................................................................... 36
Table 31 - Basic controllable status information template ..................................................... 37
Table 32 -Controllable single point ...................................................................................... 38
Table 33 - Controllable double point.. ................................................................................... 39
Table 34 - Controllable integer status ................................................................................... 40
Table 35 - Binary controlled step position information ........................................................... 41
Table 36 - lnteger controlled step position information .......................................................... 42
Table 37 - Basic controllable analogue information template ................................................ 43
Table 38- Controllable analogue set point information .......................................................... 44
Table 39 - Basic status setting template ............................................................................... 45
Table 40 - Single point setting .............................................................................................. 45
Table 41 - lnteger status setting ........................................................................................... 46
Table 42 - Basic analogue setting template .......................................................................... 47
Table 43 -Analogue setting .......................................................... , ....................................... 47
Table 44 - Setting curve ....................................................................................................... 48
Table 45 - Basic description information template ................................................................ .49
Table 46 - Device name plate common data class specification ............................................ 49
Table 47 - Logical node name plate common data class specification ................................... 50
Table 48 -Curve shape description common data class specification ................................... 50
Table 49 - Semantics of data attributes ................................................................................ 51
61850-7-3 © IEC:2003(E) -5-
Table A.1 - SI units: base units ............................................................................................. 60
Table A.2 - SI units: derived units ......................................................................................... 60
Table A.3 - SI units: extended units ...................................................................................... 61
Table A.4 - SI units: industry specific units ........................................................................... 61
Table A.5 - Multiplier ............................................................................................................ 62
Table B.1 - Functional constraints ........................................................................................ 63
-6- 61850-7-3 © IEC:2003(E)
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
FOREWORD
1) The IEC {lnternational Electrotechnical Commission) is a worldwide organisation for standardisation comprisingall national electrotechnical committees {IEC National Committees). The object of the IEC is to prometeinternational co-operation on all questions concerning standardisation in the electrical and electronic fields. Tothis end and in addition to other activities, the IEC publishes lnternational Standards. Their preparation isentrusted to technical committees; any IEC National Committee interested in the subject dealt with mayparticipate in this preparatory work. lnternational, governmental and non-governmental organisations liaisingwith the IEC also participate in this preparation. The IEC collaborates closely with the lnternationalOrganisation for Standardisation {ISO) in accordance with conditions determined by agreement between the two organisations.
2) The formal decisions or agreements of the IEC on technical matters express, as nearly as possible, aninternational consensus of opinion on the relevant subjects since each technical committee has representationfrom all interested National Committees.
3) The documents produced have the form of recommendations for international use and are published in the formof standards, technical specifications, technical reports or guides and they are accepted by the NationalCommittees in that sense.
4) In order to promete international unification, IEC National Committees undertake to apply IEC lnternationalStandards transparently to the maximum extent possible in their national and regional standards. Anydivergence between the IEC Standard and the corresponding national or regional standard shall be clearlyindicated in the latter.
5) The IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for anyequipment declared to be in conformity with one of its standards.
6) Attention is drawn to the pdssibility that sorne of the elements of this lnternational Standard may be the subject of patent rights. The IEC shall not be held responsible for identifying any or all such patent rights.
lnternational Standard IEC 61850-7-3 has been prepared by IEC technical committee 57: Power system control and associated communications.
The text of this standard is based on the following documents:
FDIS Report on voting
57/618/FDIS 57/635/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 2.
61850-7-3 © IEC:2003(E) -7-
IEC 61850 consists of the following parts, under the general title Communication networks and systems in substations.
Part 1: lntroduction and overview
Part 2: Glossary 1
Part 3: General requirements
Part 4: System and project management
Part 5: Communication requirements for functions and device models 2
Part 6: Configuration description language for communication in electrical substations related to I EDs
1
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
Part 7-4: Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes
Part 8-1: Specific communication service mapping (SCSM) - Mappings to MMS (ISO/IEC 9506-1 and ISO/IEC 9506-2) and to ISO/IEC 8802-3 1
Part 9-1: Specific communication service mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
Part 9-2: Specific communication service mapping (SCSM) - Sampled values over ISO/IEC 8802-3
Part 1 O: Conformance testing 1
The content of this part of IEC 61850 is based on existing or emerging standards and applications. In particular the definitions are based upon:
• the specific data types defined in IEC 60870-5-101 and IEC 60870-5-103;
• the common class definitions from the Utility Communication Architecture 2.0: GenericObject Mode/s for Substation & Feeder Equipment (GOMSFE) (IEEE TR 1550).
The committee has decided that the contents of this publication will remain unchanged until 2005. At this date, the publication will be
reconfirmed;
withdrawn;
replaced by a revised edition, or
amended.
A bilingual version of this standard may be issued at a later date.
1 Under consideration.
2 To be published.
-8- 61850-7-3 © IEC:2003(E)
INTRODUCTION
This document is part of a set of specifications, which details layered substation communication architecture. This architecture has been chosen to provide abstract definitions of classes and services such that the specifications are independent of specific protocol stacks and objects. The mapping of these abstract classes and services to communication stacks is outside the scope of IEC 61850-7-x and may be found in IEC 61850-8-x (station bus) and IEC 61850-9-x (process bus).
IEC 61850-7-1 gives an overview of this communication architecture. This part of IEC 61850 defines common attribute types and common data classes related to substation applications. These common data classes are used in IEC 61850-7-4. To define compatible data classes, the attributes of the instances of data shall be accessed using services defined in IEC 61850-7-2.
This part is used to specify the abstract common data class definitions. These abstract definitions shall be mapped into concrete object definitions that are to be used for a particular protocol (for example MMS, ISO 9506).
f 61850-7-3 © IEC:2003(E) -9-·•
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS -
1 Scope
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
This part of IEC 61850 specifies common attribute types and common data classes related to substation applications. In particular it specifies:
• common data classes for status information,
• common data classes for measured information,
• common data classes for controllable status information,
• common data classes for controllable analogue set point information,
• common data classes for status settings,
• common data classes for analogue settings and
• attribute types used in these common data classes.
This international standard is applicable to the description of device models and functions of substations and feeder equipment.
This international standard may also be applied, for example, to describe device models and functions for:
• substation to substation information exchange,
• substation to control centre information exchange,
• power plant to control 'centre information exchange,
• information exchange for distributed generation, or
• information exchange for metering.
2 Normative references
The following referenced documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies.
IEC 61850-2, Communication networks and systems in substations - Part 2: Glossary 3
IEC 61850-7-1, Communication networks and systems in substations - Part 7-1: Basiccommunication structure for substation and feeder equipment - Principies and models
IEC 61850-7-2, Communication networks and systems in substations - Part 7-2: Basiccommunication structure for substation and feeder equipment - Abstract communicationservice interface (ACSI)
IEC 61850-7-4, Communication networks and systems in substations - Part 7-4: Basiccommunication structure for substation and feeder eqúipment - Compatible logical nodeclasses and data classes
ISO 1000, SI units and recommendations for the use of their mu/tiples and of certain other units
3 Under consideration.
llt _______ 1E_c_&_1_as_o_-1_-4_1_0
INTERNATIONAL
STANDARD
Edition 1. O 2007 -08
Communication networks and systems for power utility automation -
Part 7-410: Hydroelectric power plants -Communication for monitoring and
control
INTERNATIONAL
ELECTROTECHNICAL
COMMISSION
ICS 33.200
PRICE CODE x e
ISBN 2-8318-9254-6
-2- 61850-7-410 © IEC:2007(E)
CONTENTS
FOREWORD ........................................................................................................................... 6
INTRODUCTION ..................................................................................................................... 8
1 Scope ............................................................................................................................... 9
2 Normative references ....................................................................................................... 9
3 Terms and definitions ..................................................................................................... 1 O
4 Abbreviations ................................................................................................................. 1 O
5 Basic concepts for hydropower plant control and supervision ......................................... 11
5.1 Functionality of a hydropower plant ....................................................................... 11
5.2 Principies for water control in a river system ......................................................... 11
5.2.1 General ..................................................................................................... 11
5.2.2 Principies for electrical control of a hydropower plant ................................ 12
5.3 Logical structure of a hydropower plant ................................................................. 13
6 Modelling concepts and examples .................................................................................. 19
6.1 The concept of Logical Devices ............................................................................. 19
6.2 Logical nodes for sensors, transmitters, supervising and monitoring functions ....... 19
6.3 Address strings ..................................................................................................... 20
6.4 Naming of logical nodes ........................................................................................ 21
6.5 Recommended naming structure for automatic control functions ........................... 21
6.6 Summary of logical nodes to be used in hydropower plants ................................... 22
6.6.1 General ..................................................................................................... 22
6.6.2 Group C - Control functions ...................................................................... 23
6.6.3 Grnup F - Functional blocks ...................................................................... 23
6.6.4 Group H - Hydropower specific logical nodes ............................................ 23
6.6.5 Group ! - Interface and archiving ............................................................... 24
6.6.6 Group K - Mechanical and non-electrical primary equipment.. ................... 25
6.6. 7 Group L - Physical devices and common logical nodes ............................. 25
6.6.8 Group M - Metering and measurement.. .................................................... 25
6.6.9 Group P - Protection functions .................................................................. 25
6.6.1 O Group R - Protection related functions ...................................................... 26
6.6.11 Group S - Supervision and monitoring ....................................................... 26
6.6.12 Group T - Transducers a.nd instrument transformers ................................. 27
6.6.13 Group X- Switchgear ................................................................................ 27
6.6.14 Group Y - Power transformers .................................................................. 27
6.6.15 Group Z - Power system equipment .......................................................... 28
7 Logical Node Classes ..................................................................................................... 28
7 .1 Abbreviations and definitions u sed in Logical Nade tables ..................................... 28
7 .1.1 lnterpretation of Logical Node tables ......................................................... 28
7 .1.2 Abbreviated terms u sed in Attribute Na mes ............................................... 29
7 .2 Logical Nodes representing functional blocks LN group F ..................................... 30
7 .2.1 Modelling remarks ..................................................................................... 30
7.2.2 LN: Counter Name: FCNT .......................................................................... 30
7.2.3 LN: Curve shape description Name: FCSD ................................................ 30
7.2.4 LN: Generic Filter Name: FFIL ................................................................... 31
7.2.5 LN: Control function output limitation Name: FLIM ..................................... 31
7.2.6 LN: PID regulator Name: FPID ................................................................... 32
61850-7-410 © IEC:2007(E) -3-
7.2.7 LN: Ramp function Name: FRMP ............................................................... 33
7.2.8 LN: Set-point control function Name: FSPT ................................................ 34
7.2.9 LN: Action at over threshold Name: FXOT ................................................. 35
7.2.1 O LN: Action at under threshold Name: FXUT ............................................... 35
7.3 Hydropower sp·ecific Logical Nodes LN group H .................................................... 36
7.3.1 Modelling remarks ..................................................................................... 36
7.3.2 LN: Turbine - generator shaft bearing Name: HBRG ................................. 36
7.3.3 LN: Combinator Name: HCOM ................................................................... 36
7.3.4 LN: Hydropower dam Name: HDAM ........................................................... 37
7.3.5 LN: Dam leakage supervision Name: HDLS ............................................... 37
7.3.6 LN: Gate position indicator Name: HGPI .................................................... 37
7.3.7 LN: Dam gate Name: HGTE ....................................................................... 38
7.3.8 LN: lntake gate Name: HITG ...................................................................... 38
7.3.9 LN: Joint control Name: HJCL .................................................................... 39
7.3.10 LN: Leakage supervision Name: HLKG ...................................................... 40
7.3.11 LN: Water level indicator Name: HLVL ....................................................... 40
7.3.12 LN: Mechanical brake Name: HMBR .......................................................... 41
7.3.13 LN: Needle control Name: HNDL ............................................................... 41
7.3.14 LN: Water net head data-Name: HNHD ..................................................... .41
7.3.15 LN: Dam over-topping protection Name: HOTP .......................................... 42
7.3.16 LN: Hydropower/water reservoir Name: HRES .......................................... .42
7.3.17 LN: Hydropower unit sequencer Name: HSEQ .......................................... .43
7.3.18 LN: Speed monitoring Name: HSPD .......................................................... 43
7.3.19 LN: Hydropower unit Name: HUNT ........................................................... 44
7.3.20 LN: Water control Name: HWCL ................................................................ 45
7.4 Logical Nodes for interface and archiving LN group l. ............................................ 45
7.4.1 Modelling remarks ..................................................................................... 45
7.4.2 LN: Safety alarm function Name: ISAF ...................................................... 46
7.5 Logical Nodes for mechanical and non-electric primary equipment LN group K ........................................................................................................................... 46
7.5.1 Modelling remarks ..................................................................................... 46
7.5.2 LN: Fan Name: KFAN ................................................................................ 46
7.5.3 LN: Filter Name: KFIL .......................... : ..................................................... 47
7.5.4 LN: Pump Name: KPMP ............................................................................. 47
7.5.5 LN: Tank Name: KTNK ............................................................................. 48
7.5.6 LN: Valve control Name: KVLV .................................................................. 48 7.6 Logical Nodes for metering and measurement LN group M .................................... 49
7.6.1 Modelling remarks ..................................................................................... 49
7.6.2 LN: Environmental information Name: MENV ............................................. 49
7.6.3 LN: Hydrological information Name: MHYD .. : ............................................. 49 7.6.4 LN: DC measurement Name: MMDC ......................................................... 50
7.6.5 LN: Meteorological information Name: MMET ............................................ 50 7.7 Logical Nodes for protection functions LN group P ................................................ 51
7.7.1 Modelling remarks ..................................................................................... 51 7.7.2 LN: Rotor protection Name: PRTR ............................................................ 52 7.7.3 LN: Thyristor protection Name: PTHF ....................................................... 52
7.8 Logical nodes for protection related functions LN Group R .................................... 52 .8.1 Modelling remarks ..................................................................................... 52
7.8.2 LN: synchronising or synchro-check device Name: RSYN ......................... 52
-4- 61850-7-410 © IEC:2007(E)
7.9 Logical Nodes for supervision and monitoring LN group S ..................................... 54
7.9.1 Modelling remarks ..................................................................................... 54
7.9.2 LN: temperature supervision Name: STMP ............................................... 54
7.9.3 LN: vibration supervision Name: SVBR ..................................................... 54
7.1 O Logical Nodes for instrument transformers and sensors LN group T ...................... 55
7 .10.1 Modelling remarks ..................................................................................... 55
7.10.2 LN: Angle sensor Name: TANG ................................................................ 55
7.10.3 LN: Axial displacement sensor Name: TAXD ............................................. 55
7.10.4 LN: Distance sensor Name: TDST ............................................................ 56
7.10.5 LN: Flow sensor Name: TFLW .................................................................. 56
7.10.6 LN: Frequency sensor Name: TFRQ ......................................................... 56
7.10.7 LN: Humidity sensor Name: THUM ........................................................... 57
7.10.8 LN: Level sensor Name: TLEV .................................................................. 57
7.10.9 LN: Magnetic field sensor Name: TMGF ................................................... 57
7.10.10LN: Movement sensor Name: TMVM ......................................................... 57
7.10.11 LN: Position indicator Name: TPOS .......................................................... 58
7.10.12LN: Pressure sensor Name: TPRS ............................................................ 58
7.10.13LN: Rotation transmitter Name: TRTN ...................................................... 58
7.10.14LN: Sound pressure sensor Name: TSND ................................................. 59
7.10.15LN: Temperature sensor Name: TTMP ...................................................... 59
7.10.16LN: Mechanical tension /stress sensor Name: TTNS ................................. 59
7.10.17LN: Vibration sensor Name: TVBR ............................................................ 60
7.10.18LN: Water pH sensor Name: TWPH .......................................................... 60
7.11 Logical Nodes for power system equipment LN group Z ........................................ 60
7 .11.1 Modelling remarks ..................................................................................... 60
7.11.2 LN:, Neutral resistor Name: ZRES ............................................................. 60
7.11.3 LN: Semiconductor rectifier controller Name: ZSCR ................................... 61
7.11.4 LN: Synchronous machine Name: ZSMC .................................................. 61
8 Data name semantics ..................................................................................................... 63
9 Common data classes .................................................................................................... 76
9.1 General ................................................................................................................. 76
. 9.2 Device ownership and operator (DOO) .................................................................. 76
9.3 Maintenance and operational tag (T AG) ................................................................ 76
9.4 Operational restriction (RST) ................................................................................. 77
1 O Data attribute semantics ................................................................................................. 77
Annex A (informative) Algorithms u sed in logical nodes for automatic control ...................... 80
Bibliography ............................................................................ .' ............................................. 86
Figure 1 - Structure of a hydropower plant ........................................................................... 11
Figure 2 - Principies for the joint control function .................................................................. 13
Figure 3 - Water control functions ........................................................................................ 14
Figure 4 -Water flow control of a turbine .... : ......................................................................... 15
Figure 5 - Typical turbine control system .............................................................................. 16
Figure 6 - Excitation system ................................................................................................. 17
Figure 7 -Electrical protections of a generating unit.. ........................................................... 18
61850-7-410 © IEC:2007(E) -5-
Figure 8 - Conceptual use of transmitters ............................................................................. 19
Figure 9 - Logical Device Name ........................................................................................... 20
Figure 10 - Example of naming structure, in a pumped storage plant, based on IEC 61346-1 ......................................................................................................................... 20
Figure A.1 - Example of curve based on an indexed gate position providing water flow ........ 80
Figure A.2 - Example of curve based on an indexed guide vane position (x axis) vs net head (y axis) giving an interpolated Runner Blade position (Z axis) ...................................... 81
Figure A.3 - Example of a proportional-integral-derivate controller ....................................... 82
Figure A.4 - Example of a Power stabilisation system .......................................................... 83
Figure A.5 - Example of a ramp generator ............................................................................ 83
Figure A.6 - Example of an interface with a set-point algorithm ............................................ 84
Figure A. 7 - Example of a physical connection to a set-point device ..................................... 85
Table 1 - Example of Logical Device over-current protection ................................................ 19
Table 2 - recommended LN prefixes ..................................................................................... 22
Table 3 - Logical nodes for control functions ........................................................................ 23
Table 4 - Logical nodes representing functional blocks ......................................................... 23
Table 5 - Hydropower specific logical nodes ......................................................................... 23
Table 6 - Logical nodes for interface and archiving .............................................................. 24
Table 7 - Logical nodes for mechanical and non-electric primary equipment.. ....................... 25
Table 8 - Logical nodes for physical devices and common LN .............................................. 25
Table 9 - Logical nodes for metering and measurement ....................................................... 25
Table 1 O - Logical no des for protections ............................................................................... 26
Table 11 - Logical nodes for protection related functions ...................................................... 26
Table 12 - Logical nodes for supervision and monitoring ...................................................... 26
Table 13 - Logical nodes for sensors .................................................................................... 27
Table 14 - Logical nodes for switchgear ............................................................................... 27
Table 15 - Logical nodes for power transformers .................................................................. 27
TaQle 16 - Logical nodes for power system equipment ......................................................... 28
Table 17 - lnterpretation of Logical Node tables ................................................................... 28
Table 18 - Conditional attributes in FPID .............................................................................. 32
Table 19 - Description of data .............................................................................................. 63
Table 20 - Semantics of data attributes ................................................................................ 78
-6- 61850-7-410 © IEC:2007(E)
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS FOR POWER UTILITY AUTOMATION
Part 7-41 O: Hydroelectric power· planta -Communication for monitoring and control
FOREWORD
1) The lnternational Electrotechnical Commission (IEC) is a worldwide organization for standardization comprising all national electrotechnical committees (IEC National Committees). The object of IEC is to prometeinternational co-operation on all questions concerning standardization in the electrical and electronic fields. Tothis end and in addition to other activities, IEC publishes lnternational Standards, Technical Specifications, Technical Reports, Publicly Available Specifications (PAS) and Guides (hereafter referred to as "IEC Publication(s)'). Their preparation is entrusted to technical committees; any IEC National Committee interested in the subject dealt with may participate in this preparatory work. lnternational, governmental and nongovernmental organizations liaising with the IEC also participate in this preparation. IEC collaborates closelywith the lnternational Organization for Standardization (ISO) in accordance with conditions determined by agreement between the two organizations.
2) The formal decisions or agreements of IEC on technical matters express, as nearly as possible, an internationalconsensus of opinion on the relevant subjects since each technical committee has representation from allinterested IEC National Committees.
3) IEC Publications have the form of recommendations for international use and are accepted by IEC National Committees in that sense. While all reasonable efforts are made to ensure that the technical content of IECPublications is accurate, IEC cannot be held responsible for the way in which they are used or for anymisinterpretation by any end user.
4) In arder to promete international uniformity, IEC National Committees undertake to apply IEC Publications transparently to the maximum extent possible in their national and regional publications. Any divergencebetween any IEC Pub)ication and the corresponding national or regional publication shall be clearly indicated in the latter.
5) IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for any equipment declared to be in conformity with an IEC Publication.
6) AII users should ensure that they have the lates! edition of this publication.
7) No liability shall attach to IEC or its directors, employees, servants or agents including individual experts andmembers of its technical committees and IEC National Committees for any personal injury, property damage or other damage of any nature whatsoever, whether direct or indirect, or for costs (including legal fees) andexpenses arising out of the publication, use of, or reliance upen, this IEC Publication or any other IECPublications.
8) Attention is drawn to the Normative references cited in this publication. Use of the referenced publications isindispensable for the corree! application of this publication.
9) Attention is drawn to the possibility that sorne of the elements of this IEC Publication may be the subject ofpatent rights. IEC shall not be held responsible for identifying any or all such patent rights.
lnternational Standard IEC 61850-410 has been prepared by IEC technical committee 57: Power systems management and associated information exchange.
lt has been decided to amend the general title of the I E C 61850 series to Communication networks and systems for power utility automation. Henceforth, new editions within the IEC 61850 series will adopt this new general title.
The text of this standard is based on the following documents:
FDIS Report on voting
57/886/FDIS 57/905/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
61850-7-410 © IEC:2007(E) -7-
This publication has been drafted in accordance with the 1S0/IEC Directivas, Part 2.
A list of all parts of the IEC 61850 series, under the general title Communication networks and systems for power utility automation, can be found on the IEC website.
The committee has decided that the contents of this publication will remain unchanged until the maintenance result date indicated on the IEC web site under "http://webstore.iec.ch" in the data related to the specific publication. At this date, the publication will be
• reconfirmed,
withdrawn,
replaced by a revised edition, or
amended.
A bilingual version of this publication may be issued at a later date.
-8- 61850-7-410 © IEC:2007(E)
INTRODUCTION
The present standard includes all additional logical nodes, not included in IEC 61850-7-4:2003, required to represent the complete control and monitoring system of a hydropower plant.
Most of the Logical Nodes in IEC 61850-7-410 that are of general use, Logical Nodes the names of which do not start with the letter "H", will be transferred to the future Edition 2 of IEC 61850-7-4. In the same manner, all Common Data Classes specified in IEC 61850-7-410 will be transferred to future Edition 2 of IEC 61850-7-3.
Once future Editions 2 of IEC 61850-7-3 and IEC 61850-7-4 are published, IEC 61850-7-410 will be revised to include only those Logical Nodes that are specific to hydropower use.
Before Edition 2 of IEC 61850-7-410 is published, there will be a period where the Common Data Class (CDC) and Logical Node (LN) specifications will overlap with IEC 61850-7-3 (future Edition 2) and IEC 61850-7-4 (future Edition 2). During this time, the specifications in IEC 61850-7-3 (future Edition 2) and IEC 61850-7-4 (future Edition 2) will apply.
61850-7-410 © IEC:2007(E) -9-
1 Scope
COMMUNICATION NETWORKS ANO SYSTEMS FOR POWER UTILITY AUTOMATION -
Part 7-410: Hydroelectrlc power planta -Communication for monitoring and control
IEC 61850-7-410 is part of the IEC 61850 series. This part of IEC 61850 specifies the additional common data classes, logical nodes and data objects required for the use of IEC 61850 in a hydropower plant.
The Logical Nodes and Data Objects defined in this part of IEC 61850 belong to the following fields of use:
• Electrical functions. This group includes LN and DO used for various control functions,essentially related to the excitation of the generator. New LN and DO defined within thisgroup are not specific to hydropower plants; they are more or less general for all types oflarger power plants.
• Mechanical functions. This group includes functions related to the turbine andassociated equipment. The specifications of this document are intended for hydropowerplants, modifications might be required for application to other types of generating plants.Sorne more generic functions are though defined under Logical Node group K.
• Hydrological functions. This group of functions includes objects related to water flow,control and management of reservoirs and dams. Although specific for hydropower plants,the LN and DO d�fined here can also be used for other types of utility water managementsystems.
• Sensors. A power plant will need sensors providing measurements of other than electricaldata. With a few exceptions, such sensors are of general nature and not specific forhydropower plants.
NOTE AII Logical Nodes with names not starting with the letter 'H" will be included in a future edition 2 of IEC 61850-7-4. When that document is published, the Logical Nodes in IEC 61850-7-4 (Edition 2) will take precedence over Logical Nodes with the same name in this part IEC 61850-7-410.
2 Normativa references
The following referenced documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies:
IEC 61850-2, Communication networks and systems in substations - Part 2: G/ossary
IEC 61850-5, Communication networks and systems in substations - Part 5: Communication requirements for functions and device mode/s
IEC 61850-6, Communication networks and systems in substations - Part 6: Configuration description language for communication in e/ectrica/ substations related to IEDs
IEC 61850-7-2:2003, Communication networks and systems in substations - Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication services interface (ACS/)
- 10- 61850-7-410 © IEC:2007(E)
IEC 61850-7-3:2003, Communication networks and systems in substations - Part 7-3: Basiccommunication structure for substation and feeder equipment - Common data c/asses
IEC 61850-7-4:2003, Communication networks and systems in substations - Part 7-4: Basiccommunication structur� for substation and feeder equipment - Compatible /ogical node
classes
INTERNATIONAL
STANDARD
IEC
61850-8-1
First edition
2004-05
Communication networks and systems in substations -
Part 8-1: Specific Communication Service Mapping (SCSM) -Mappings to MMS (ISO 9506-1 and ISO 9506-2) and to ISO/IEC 8802-3
© IEC 2004 - Copyright - all rights reserved
No part of thls publication may be reproduced or utilized in any form or by any means, electronic or mechanical, includlng photocopylng and microfilm, wlthout permission in writing from the publisher.
lntemational Electrotechnlcal Commisslon, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Switzer1and
Telephone: +41 22 919 02 11 Telefax: +41 22 919 03 00 E-mail: lnmall@lec.ch Web: www.iec.ch
Commission Electrotechnique lnternatlonale lnternational Electrotechnical Commission Me>t<,11yHapOAHaR 3neKTpOT8XHl!�8CKaR KOMl!CCl!R
PRICE CODE XF
For price, see current catalogue
-2- 61850-8-1 © IEC:2004(E)
CONTENTS
FOREWORD ........................................................................................................................... 8
INTRODUCTION ................................................................................................................... 10
1 Scope ............................................................................................................................. 11
2 Normative references ..................................................................................................... 11
3 Terms and definitions ..................................................................................................... 15
4 Abbreviations ................................................................................................................. 17
5 Overview ........................................................................................................................ 18
5.1 General ................................................................................................................. 18
5.2 IEC 61850 server object ........................................................................................ 20
5.3 MMS communication profiles ................................................................................. 20
5.4 Non-MMS communication profiles ......................................................................... 20
5.5 MMS objects being u sed ....................................................................................... 20
6 Communication stack ..................................................................................................... 21
6.1 Overview of the protocol usa ge ............................................................................. 21
6.2 Client/server services and communication profües ................................................ 22
6.3 GSE management and GOOSE services communication profiles ........................... 25
6.4 GSSE Service and communication profile .............................................................. 27
6.5 Time sync .............................................................................................................. 29
7 Objects of IEC 61850 ..................................................................................................... 30
7.1 Server ................................................................................................................... 30 7 .2 Logical device (LO) ............................................................................................... 30 7.3 Logical node (LN) .................................................................................................. 30
8 Mapping of IEC 61850-7-2 and IEC 61850-7-3 data attributes ........................................ 33
8.1 Mapping of Attributes specified in IEC 61850-7-2 .................................................. 33
8.2 Mapping of quality common data attribute type specified in IEC 61850-7-3 ............ 36 9 Server class model ......................................................................................................... 37
9.1 Server mapping ..................................................................................................... 37
9.2 Server class attributes ........................................................................................... 37
9.3 Server class service GetServerDirectory ............................................................... 38 10 Association model ................................................................... : ...................................... 40
10.1 Association relation to communication profiles ...................................................... 40 10.2 Two party association model for client/server communication profile ..................... 40
10.3 Two party association model for GSE management communication profile ............ 41 10.4 Two party association model for time sync ............................................................ 41 10.5 Multicast association model ..................................... ; ............................................. 42
11 Logical device model ...................................................................................................... 42
12 Logical node model ........................................................................................................ 42
12.1 Logical node class ................................................................................................. 42 12.2 Logical node class attributes ................................................................................. 42 12.3 Logical node class cervices ................................................ : .................................. 43
13 Data class model ............................................................................................................ 44
13.1 Data class ............................................................................................................. 44 13.2 Data class serví ces ............................................................................................... 45
61850-8-1 © IEC:2004(E) -3-
14 Data set class model ...................................................................................................... 46
14.1 Data set class ....................................................................................................... 46
14.2 Data set attributes ................................................................................................. 46
14.3 Data set services ................................................................................................... 47
15 Substitution model .. '. ....................................................................................................... 50
16 Setting group control class model ................................................................................... 50
16.1 Setting group control class definition ..................................................................... 50
16.2 Setting group control class services ...................................................................... 50
17 Reporting and logging class model ................................................................................. 51
17 .1 Report model. ........................................................................................................ 51
17 .2 Reporting services ................................................................................................ 53
17 .3 Log model ............................................................................................................. 56
18 Mapping of the generic substation event model (GSE) .................................................... 62
18.1 Generic object oriented substation event (GOOSE) ............................................... 62
18.2 Generic Substation State Event (GSSE) ................................................................ 71
19 Transmission of sampled values class model ................................................................. 81
20 Control class model ........................................................................................................ 81
20.1 Control service parameters .................................................................................... 81
20.2 Mapping of control objects ..................................................................................... 81
20.3 Mapping of control services ................................................................................... 83
20.4 Select. ................................................................................................................... 84
20.5 SelectwithValue ..................................................................................................... 84
20.6 Cancel ................................................................................................................... 85
20.7 Operate ..................... _ ............................................................................................ 85
20.8 AdditionalCauseDiagnosis in negative control service responses .......................... 87
20.9 CommandTermination ........................................................................................... 89
21 Time and time synchronization model ............................................................................. 89
22 Naming conventions ....................................................................................................... 89
23 File transfer .................................................................................................................... 89
23.1 File transfer model ................................................................................................ 89
. 23.2 File services .......................................................................................................... 91
24 Conformance .................................................................................................................. 94
24.1 Notation ................................................................................................................ 94
24.2 PICS ..................................................................................................................... 94
24.3 PICS Statement ................................................................................................... 107
25 Substation Configuration Language (SCL) .................................................................... 109
25.1 SCL file and SCL extensions ............................................................................... 109
Annex A (normative) Application protocol specification for GOOSE and GSE management ....................................................................................................................... 111
Annex B (informative) Multicast address selection ............................................................. 113
Annex C (normative) Overview of ISO/IEC 8802-3 trame structure for GSE management and GOOSE ................................................................................................... 114
Annex D (informative) SCL conformance ........................................................................... 117
Annex E (normative) Specialized CDCs for control service mapping .................................. 121
Annex F (informative) Time scales and epochs .................................................................. 128
Annex G (normative) Type extensions to ISO 9506-1 (2003) and ISO 9506-2 (2003) ......... 131
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Figure 1 - Overview of functionality and profiles ................................................................... 19
Figure 2 - OSI reference model and profiles ......................................................................... 21
Figure 3 - Recommended ordered list of functional constraints ............................................. 31
Figure 4 -Relationship of LCB attributes to IEC 61850-7-2 log definitions ............................ 56
Figure 5 - GetGoReference service primitives ...................................................................... 63
Figure 6 - GetGOOSEElementNumber service primitives ..................................................... 66
Figure 7 -Transmission time for events ............................................................................... 68
Figure 8 - SendGooseMessage message service primitives ................................................. 68
Figure 9 -Client state machi ne for GOOSE service .............................................................. 69
Figure 1 O -Server state machirie for GOOSE service ........................................................... 69
Figure 11 -GetGsReference service primitives .................................................................... 74
Figure 12 - GetGSSEDataOffset service primitives ............................................................... 76
Figure 13 - GSSE service primitives ..................................................................................... 78
Figure 14 - Client state machine for GSSE service ............................................................... 78
Figure 15 -Server state machine for GSSE service .............................................................. 79
Figur.e 1-6 --Mapping of ACSI GetFile to MMS FileOpen, FileRead, FileClose ....................... 91
Figure 17 - Mapping of ACSI SetFile service ........................................................................ 92
Figure C.1 -ISO/IEC 8802-3 frame format ......................................................................... 114
Figure C.2 -Virtual LAN tag ............................................................................................... 115
Table 1 - MMS objects and services in use within this SCSM ............................................... 21
Table 2 -Services requiring client/server Communication Profile ......................................... 22
Table 3 - Service and protocols for client/server communication A-Profile ............................ 23
Table 4 - Service and protocols for client/server TCP/IP T-Profile ........................................ 24
Table 5 -Service and protocols for client/server OSI T-Profile ............................................. 25
Table 6 -Services requiring GSE Management and GOOSE communication profile ............. 26
Table 7 - Service and protocols for GSE Management and GOOSE communication A-Profile ............................................................................................................................... 26
Table 8 -GOOSE/GSE T-Profile .......................................................................................... 26
Table 9 - Service requiring GSSE communication profile ...................................................... 27
Table 10 -Service and protocols for GSSE communication A-Profile .................................... 27
Table 11 -GSSE management T-Profile ............................................................................... 28
Table 12 - Time sync A-Profile ............................................................................................. 29
Table 13 -Time sync T-Profile ............................................................................................. 29
Table 14 -Mapping of ACSI data types .................................. : ............................................. 33
Table 15 -Encoding of IEC 61850-7-2 TimeQuality .............................................................. 36
Table 16 -Encoding of IEC 61850-7-3 quality .......... , ........................................................... 37
Table 17 - ServiceError mapping for GetServerDirectory for non-files .................................. 39
Table 18 -ServiceErrors mapping of ACSI GetServerDirectory for files ................................ 39
Table 19 - Association model versus communication profiles ............................................... 40
Table 20 -Associate service error mappings ........................................................................ 41
Table 21 -Release service error mappings .......................................................................... 41
Table 22 -GetNamedList classes for GetLogicalNodeDirectory service ................................ 43
61850 -8-1 © IEC:2004(E) -5-
Table 23 - MMS AccessResult mapping to ASCI ServiceError ............................................. .44
Table 24 - Mapping of GetDataValues service parameters ................................................... 45
Table 25 - Mapping of SetDataValues service parameters .................................................... 45
Table 26 - Mapping of GetDataDirectory service parameters ................................................ 46
Table 27 - ServiceError Mappings for GetDataDirectory service ........................................... 46
Table 28 - Mapping of GetDataSetValues service parameters .............................................. 47
Table 29 - Mapping of SetDataSetValues service parameters .............................................. 47
Table 30 - Mapping of CreateDataSet service parameters ................................................... .48
Table 31 - ServiceError mapping for CreateDataSet.. .......................................................... .48
Table 32 - Mapping of DeleteDataSet service parameters .................................................... 48
Table 33 - ServiceError mapping for DeleteDataSet ............................................................ .49
Table 34 - Mapping of GetDataSetDirectory service parameters .......................................... .49
Table 35 - ServiceError mapping for GetDataSetDirectory .................................................... 49
Table 36 - Mapping of ACSI ServiceError for SelectActiveSG ............................................... 50
Table 37 - Mapping of BRCB to MMS type definition ............................................................ 51
Table 38 - Mapping of OptFlds within Bitstring ..................................................................... 52
Table 39 - M-apping of URCB to MMS type definition ............................................................ 52
Table 40 - Order of AccessResults for variablelistName re port.. .......................................... 53
Table 41 - Definition of an MMS log control block ................................................................. 57
Table 42 - Mapping of val u es for LogEna ............................................................................. 57
Table 43 - Mapping of ACSI LogEntries ................................................................................ 58
Table 44 - General mappings of ACSI log model services .................................................... 60
Table 45 - Mapping Óf QuerylogByTime request parameters ............................................... 61
Table 46 - Mapping of response parameters ........................................................................ 61
Table 47 - ServiceError mappings for Log services .............................................................. 61
Table 48 - Mapping of QuerylogAfter request parameters .................................................... 61
Table 49 - Log conformance requirements ........................................................................... 62
Table 50 - MMS TypeDescription definition for GCB MMS structure ..................................... 62
Table 51 - DstAddress structure ........................................................................................... 63
Table 52 - Mapping of GetGoReference service ................................................................... 64
Table 53 - GetGoReference ................................................................................................. 64
Table 54 - Mapping of GetGOOSEElementNumber service .................................................. 66
Table 55 - GetGOOSEElementNumber ................................................................................. 67
Table 56 - GOOSE service parameter mapping .................................................................... 70
Table 57 - MMS TypeDescription Definition for GSSE control block MMS structure .............. 71
Table 58 - Mapping of LSentData ......................................................................................... 72
Table 59 - Definition of integer values of PhslD .................................................................... 73
Table 60 - Definition of double- bit GSSE values ................................................................... 73
Table 61 - Mapping of GetGsReference service ................................................................... 74
Table 62 - GetGsReference .................................................................................................. 75
Table 63 - Mapping of GetGOOSEElementNumber service .................................................. 76
Table 64 - GetGSSEDataOffset ............................................................................................ 77
Table 65 - GSSE service ...................................................................................................... 79
-6- 61850-8-1 © IEC:2004(E)
Table 66 - Mapping of test values to bit-pair values ............................................ ,. ................. 80
Table 67 - Control service parameters .................................................................................. 81
Table 68 - Mapping of IEC 61850-7-2 control model to MMS control components ................. 82
Table 69 - Mapping of control services ................................................................................. 83
Table 70 - Select service parameter mapping ....................................................................... 84
Table 71 - SelectwithValue service parameter mapping ........................................................ 84
Table 72 - Select, Oper and Cancel AccessResult specification ........................................... 85
Table 73 - Cancel service parameter mapping ...................................................................... 85
Table 74 - Operate service parameter mapping .................................................................... 86
Table 75 - Control with TimeActivation service parameter mapping ...................................... 86
Table 76 - Definition of LastApplError variable structure ....................................................... 87
Table 77 - Mapping of ACSI AddCause val u es ..................................................................... 88
Table 78 - Mapping of ACSI file class to MMS file object.. .................................................... 89
Table 79 - Reserved file suffixes .......................................................................................... 90
Table 80 - Mapping of ACSI GetFile service parameters ...................................................... 92
Table 81 - Mapping of ACSI SetFile parameters ................................................................... 93
Table 82 - Mapping of ACSI DeleteFile service .................................................................... 93
Table 83 - Mapping of ACSI GetFileAttributeValues parameters ........................................... 94
Table 84 - Mapping of ACSI ListOfDirectoryEntry ................................................................. 94
Table 85 - PICS for A-Profile support ................................................................................... 95
Table 86 - PICS for T-Profile support ................................................................................... 95
Table 87 - MMS lnitiateRequest general parameters ............................................................ 96
Table 88 - MMS lnitíateResponse general parameters ......................................................... 96
Table 89 - MMS service supported conformance table ......................................................... 97
Table 90 - MMS Parameter CBB ........................................................................................ 100
Table 91 - GetNamelist conformance statement.. .............................................................. 100
Table 92 - AlternateAccessSelection conformance statement.. ........................................... 101
Table 93 - VariableAccessSpecification conformance statement ........................................ 101
Table 94 - VariableSpecification conformance statement.. .................................................. 102
Table 95 - Read conformance statement.. .......................................................................... 102
Table 96 - Write conformance statement ............................................................................ 102
Table 97 - lnformationReport conformance statement ........................................................ 103
Table 98 - GetVariableAccessAttributes conformance statement.. ...................................... 103
Table 99 - DefineNamedVariablelist conformance statement.. ........................................... 103
Table 100 -GetNamedVariablelistAttributes conformance statement. ................................. 104
Table 101 - DeleteNamedVariablelist conformance statement.. ......................................... 104
Table 102 - ReadJournal conformance statement.. ............................................................. 105
Table 103 - JournalEntry conformance statement.. ............................................................. 105
Table 104 - lnitializeJournal conformance statement .......................................................... 106
Table 105 - FileDirectory conformance statement.. ............................................................. 106
Table 106 - FileOpen conformance statement .................................................................... 106
Table 107 - FileRead conformance statement .................................................................... 107
Table 108 - FileClose conformance statement.. .................................................................. 107
61850-8-1 © IEC:2004(E) -7-
Table 109 - GOOSE conformance statement.. .................................................................... 108
Table 110- GSSE conformance statement.. ....................................................................... 108
Table 111 - Allowed P-Type definitions for client/server addressing ................................... 109
Table 112 - Definitions for GSE SCL .................................................................................. 11 O
Table B.1 - Recommended multicast addressing example .................................................. 113
Table C.1 - Default virtual LAN IDs and priorities ............................................................... 115
Table C.2 - Assigned E thertype values ............................................................................... 116
Table D.1 - SCL conformance degrees ............................................................................... 117
Table D.2 - Supported ACSI services for SCL.2 and SCL.3 ................................................ 117
Table D.3 - Additional MMS services for SCL.2 and SCL.3 ................................................. 118
Table D.4 - Definition of SCL control block ......................................................................... 118
Table E.1 - Name space attributes ..................................................................................... 121
Table E.2 - Extended common data class controllable single point.. ................................... 122
Table E.3 - Extended common data class controllable double point.. .................................. 122
Table E.4 - Extended common data class controllable integer status .................................. 123
Table E.5 - Extended common data class binary controlled step position information ......... 123
Table E.6 - Extended common data class integer controlled step position information ........ 124
Table E.7- Extended common data class controllable analogue set point information ........ 124
Table E.8 - SBOw .............................................................................................................. 125
Table E.9 - Oper ................................................................................................................ 125
Table E.10 - Cancel ........................................................................................................... 126
Table E.11 - ctlVal ............................................................................................................. 126
Table E.12 - Conditibns for attribute inclusion .................................................................... 126
Table E.13 - Semantics of data attributes ........................................................................... 127
Table F.1 - Relationships between timescales .................................................................... 129
Table F.2 - Examples of timescale correspondence ............................................................ 130
-8- 61850-8-1 © IEC:2004(E)
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS
Part 8-1: Specific Communication Service Mapping (SCSM) -Mappings to MMS (ISO 9506-1 and ISO 9506-2)
and to ISO/IEC 8802-3
FOREWORD
1) The lnternational Electrotechnical Commission (IEC) is a worldwide organization for standardization comprisingall national electrotechnical committees (IEC National Committees). The object of IEC is to promote international co-operation on all questions concerning standardization in the electrical and electronic fields. Tothis end and in addition to other activities, IEC publishes lnternational Standards, Technical Specifications,Technical Reports, Publicly Available Specifications (PAS) and Guides (hereafter referred to as 'IECPublication(s)'). Their preparation is entrusted to technical committees; any IEC National Committee interestedin the subject dealt with may participate in this preparatory work. lnternational, governmental and nongovernmental organizations liaising with the IEC also participate in this preparation. IEC collaborates closelywith the lnternational Organization for Standardization (ISO) in accordance with conditions determined byagreement between the two organizations.
2) The formal decisions or agreements of IEC on technical matters express, as nearly as possible, an internationalconsensus of opinion on the relevan! subjects since each technical committee has representation from allinterested IEC National Committees.
3) IEC Publications have the form of recommendations for international use and are accepted by IEC National Committees -in that sense. While all reasonable efforts are made to ensure that the technical content of IECPublications is accurate, IEC cannot be held responsible for the way in which they are used or for any misinterpretation by any end user.
4) In order to promote international uniformity, IEC National Committees undertake to apply IEC Publications transparently to the maximum extent possible in their national and regional publications. Any divergencebetween any IEC Publication and the corresponding national or regional publication shall be clearly indicated in the latter.
5) IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for any equipment declared to be in conformity with an IEC Publication.
6) AII users should ensure that they have the lates! edition of this publication.
7) No liability shall attach to IEC or its directors, employees, servants or agents including individual experts and members of its technical committees and IEC National Committees for any personal injury, property damage or other damage of any nature whatsoever, whether direct or indirect, or for costs (including legal fees) and expenses arising out of the publication, use of, or reliance upon, this IEC Publication or any other IEC Publications.
8) Attention is drawn to the Normative references cited in this publication. Use of the referenced publications isindispensable for the corree! application of this publication.
9) Attention is drawn to the possibility that sorne of the elements of this IEC Publication may be the subject of patent rights. IEC shall not be held responsible for identifying any or all such patent rights.
lnternational Standard IEC 61850-8-1 has been prepared by IEC technical committee 57: Power systems management and associated information exchange.
The text of this standard is based on the following documents:
FDIS Report on voting
57/692/FDIS 57/712/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 2.
61850-8-1 © IEC:2004(E) -9-
IEC 61850 consists of the following parts, under the general title Communication networks and systems in substations:
Part 1:
Part 2:
Part 3:
Part 4:
Part 5:
Part 6:
Part 7-1:
Part 7-2:
Part 7-3:
Part 7-4:
Part 8-1:
Part 9-1:
Part 9-2:
Part 10:
lntroduction and overview
Glossary
General requirements
System and project management
Communication requirements for functions and device models
Configuration description language for communication in electrical substations related to IEDs
Basic communication structure for substation and feeder equipment - Principies and models
Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Basic communication structure for substation and feeder equipment - Common data classes
Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes
Specific- Communication Service Mapping (SCSM) - Mappings to MMS (ISO 9506-1 and ISO 9506-2) and to ISO/IEC 8802-3
Specific Communication Service Mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
Specific Communication Service Mapping (SCSM) - Sampled values over ISO/IEC 8802-3
Conformance testing 1
This document specifies in Annex E specialized CDCs (Common Data Classes) based on CDCs defined in IEC 61850-7-3:2003.
The committee has decided that the contents of this publication will remain unchanged until 2005. At this date, the publication will be
. reconfirmed;
withdrawn;
replaced by a revised edition, or
amended.
A bilingual version of this document may be issued at a later date.
1 Under consideration.
-10- 61850-8-1 © IEC:2004(E)
INTRODUCTION
This document is part of a set of specifications which details layered substation communication architecture.
This part of IEC 61850 is intended to provide inter-device operation of a variety of substation and feeder devices to achieve interoperability providing detailed information on how to create and exchange concrete communication messages that implement abstract services and models specified in IEC 61850-7-4, IEC 61850-7-3, and IEC 61850-7-2.
The mapping allows for data exchange over ISO/IEC 8802-3 Local Area Networks between all kinds of substation devices. Sorne of the protocol stacks used within this document are routable. Therefore the actual communications path may not be restricted to the LAN. Data exchange consists of real-time monitoring and control data, including measured values, to name just a few.
NOTE This part of IEC 61850 does not provide tutorial material. lt is recommended that IEC 61850-5 and IEC 61850-7-1 be read in conjunction with IEC 61850-7-2.
61850-8-1 © IEC:2004(E) - 11 -
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS -
Part 8-1: Specific Communication Service Mapping (SCSM) -Mappings to MMS (ISO 9506-1 and ISO 9506-2)
and to ISO/IEC 8802-3
1 Scope
This part of IEC 61850 specifies a method of exchanging time-critica! and non-time-critica! data through local-area networks by mapping ACSI to MMS and ISO/IEC 8802-3 trames.
MMS services and protocol are specified to operate over full OSI and TCP compliant communications profiles. The use of MMS allows provisions for supporting both centralized and distributed architectures. This standard includes the exchange of real-time data indications, control operations, report notification.
This part of IEC 61850 specifies the mapping of the objects and services of the ACSI (Abstract Communication Service Interface, IEC 61850-7-2) to MMS (Manufacturing Message Specification, ISO 9506) and ISO/IEC 8802-3 trames.
This standard also specifies the mapping of time-critica! information exchanges to non-MMS protocol. The protocol semantics are defined in IEC 61850-7-2. This standard contains the protocol syntax, definition, mapping to ISO/IEC 8802-3 trame formats, and any relevant procedures specific to the use of ISO/IEC 8802-3.
This mapping of ACSI to MMS defines how the concepts, objects, and services of the ACSI are to be implemented using MMS concepts, objects, and services. This mapping allows interoperability across functions implemented by different manufacturers.
This part of the standard defines a standardized method of using the ISO 9506 services to implement the exchange of data. For those ACSI services, defined in IEC 61850-7-2 that are not mapped to MMS, this part defines additional protocols. This standard describes real substation devices with respect to their externa! visible data and behaviour using an object oriented approach. The objects are abstract in nature and may be used to a wide variety of applications. The use of this mapping goes far beyond the application in the substation communications.
This part of IEC 61850 provides mappings for the services and objects specified within IEC 61850-7-2, IEC 61850-7-3, and IEC 61850-7-4.
2 Normative references
The following referenced documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies.
IEC 60874-10-1:1997, Connectors for optical fibres and cables - Part 10-1: Detail specification for fibre optic connector type BFOC/2,5 terminated to multimode fibre type A 1
IEC 60874-10-2:1997, Connectors for optical fibres and cables - Part 10-2: Detail specification for fibre optic connector type BFOC/2,5 terminated to single-mode fibre type B1
-12 - 61850-8-1 © IEC:2004(E)
IEC 60874-10-3:1997, Connectors for optical fibres and cables - Part 10-3: Detailspecification for fibre optic connector type BFOC/2, 5 for single and multimode fibre
IEC 61850-2, Communication networks and systems in substations - Part 2: Glossary
IEC 61850-5, Communication networks and systems in substations - Part 5: Communicationrequirements for functions and device models
IEC 61850-7-1, Communication networks and systems in substations - Part 7-1: Basiccommunication structure for substation and feeder equipment - Part 7-1: Principies andmodels
IEC 61850-7-2, Communication networks and systems in substations - Part 7-2: Basiccommunication structure for substation and feeder equipment - Abstract communicationservice interface (ACSJ)
IEC 61850-7-3, Communication networks and systems in substations - Part 7-3: Basiccommunication structure for substation and feeder equipment - Common data classes
IEC 61850-7-4, Communication networks and systems in substations - Part 7-4: Basiccommunication structure for substation and feeder equipment - Compatible logical nodeclasses and data classes
IEC 61850-9-1, Communication networks and systems in substations - Part 9-1: Specific
Communication Service Mapping (SCSM) - Sampled values over serial unidirectionalmultidrop point to point link
IEC 61850-9-2, Communication networks and systems in substations - Part 9-2: SpecificCommunication Service Mapping (SCSM) - Sampled values over ISOIIEC 8802-3
ISO/IEC 7498-1 :1994, lnformation technology - Open Systems lnterconnection - BasicReference Model: The Basic Model
ISO/IEC 7498-3:1997, lnformation technology - Open Systems lnterconnection - BasicReference Model: Naming and addressing
ISO/IEC 8072:1996, lnformation technology - Open systems interconnection - Transportservice
ISO/IEC 8073:1997, lnformation technology - Open Systems lnterconnection - Protocol forproviding the connection-mode transport service definition
ISO/IEC 8326:1996, lnformation processing system - Open Systems lnterconnection -
Session service definition
ISO/IEC 8327-1:1997, lnformation technology- Open Systems lnterconnection - Connectionoriented session protocols: Protocol specification
ISO/IEC 8348:2002, lnformation technology - Open Systems lnterconnection - Networkservice definition
ISO/IEC 84 73-1: 1998, lnformation technology - Protocol for providing the connectionlessmode network service: Protocol specification
61850-8-1 © IEC:2004(E) -13-
ISO/IEC 8473-2:1996, lnformation technology - Protoco/ for providing the connection/essmode network service - Part 2: Provision of the underlying service by an ISOIIEC 8802subnetwork
ISO/IEC 8602:1995, lnformation technology - Protocol for providing the OSI connectionlessmode transport service
ISO/IEC 8649:1996, lnformation technology - Open Systems lnterconnection - Servicedefinition for the Associated Control Service Element
ISO/IEC 8650-1 :1996, lnformation techno/ogy - Open Systems lnterconnection - Connectionoriented protoco/ for the Association Control Service Element: Protoco/ specification
ISO/IEC 8802-2:1998, lnformation technology- Telecommunications and information exchange between systems - Local and metropolitan area networks - Specific requirements - Part 2: Logical link control
ISO/IEC 8802-3:2001, lnformation technology - Te/ecommunications and information exchange between systems - Local and metropolitan area networks - Specific requirements - Part 3: Carrier sense mu/tiple access with col/ision detection (CSMAICD) access method and physica/ /ayer specifications
ISO/IEC 8822:1994, lnformation techno/ogy - Open Systems lnterconnection - Presentationservice definition
ISO/IEC 8823-1 :1994, lnformation technology - Open Systems lnterconnection - Connectionoriented presentation protocol: Protocol specification
ISO/IEC 8824-1:1999, lnformation technology - Abstract Syntax Notation One (ASN. 1): Specification of basie notation Amendment 1 (2000) Amendment 2 (2000)
ISO/IEC 8825-1:2000, lnformation techno/ogy - ASN.1 encoding rules: Specification of Basic
Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)
ISO/IEC 8877:1992, lnformation technology - Telecommunications and information exchangebetween systems - Interface connector and contact assignments for ISDN Basic AccessInterface /ocated at reference points S and T
ISO/IEC 9542:1988, lnformation processing systems - Telecommunications and information exchange between systems - End system to lntermediate system routeing exchange protocol for use in conjunction with the Protocol for providing the connectionless-mode network service (ISO 8473)
ISO/IEC 9548-1:1996, lnformation techno/ogy- Open Systems lnterconnection - Connection/ess Session protocol: Protocol specification
ISO/IEC 9576-1 :1995, lnformation techno/ogy- Open Systems lnterconnection - Connection/ess Presentation protocol: Protocol specification
ISO/IEC 10035-1 :1995, lnformation techno/ogy - Open Systems lnterconnection - Connectionless protoco/ for the Association Control Service E/ement: Protocol specification Amendment 1 (1998)
•·
-14 - 61850-8-1 © IEC:2004(E)
ISO/IEC ISP 10608-1: 1992, lnformation technology - lnternationa/ Standardized Profi/eTAnnnn - Connection-mode Transport Service over Connectionless-mode Network Service -
Part 1: General overview and subnetwork-independent requirements
ISO/IEC ISP 10608-2:1.992, lnformation technology - lnternational Standardized Profi/e TAnnnn - Connection-mode Transport Service over Connectionless-mode Network Service -Part 2: TA51 profi/e including subnetwork-dependent requirements for CSMAICD Local Area Networks (LANs)
ISO/IEC ISP 11188-1: 1995, lnformation technology - lnternationa/ Standardized Profile -
Common upper /ayer requirements - Part 1: Basic connection oriented requirements
ISO/IEC ISP 11188-3: 1996, lnformation techno/ogy - lnternational Standardized Profile -
Common upper /ayer requirements - Part 3: Minima/ OSI upper /ayer ff;Jcilities
ISO 9506-1 :2003, Industrial automation systems - Manufacturing Message Specification -
Part 1: Service definition
ISO 9506-2:2003, Industrial automation systems - Manufacturing Message Specification -
Part 2: Protocol specification
ISO/ISP 14226-1: 1996, Industrial automation systems - lnternational Standardized ProfileAMM11: MMS General App/ications Base Profile - Part 1: Specification of ACSE,Presentation and Session protocols for use by MMS
ISO/ISP 14226-2:1996, Industrial automation systems - lnternational Standardized ProfileAMM11: MMS General App/ications Base Profile - Part 2: Common MMS requirements
ISO/ISP 14226-3: 1996, Industrial automation systems - lnternational Standardized Profi/eAMM11: MMS General App/ications Base Profi/e - Part 3: Specific MMS requirements
IEEE C37.111 :1999, IEEE Standard for Common Format for Transient Data Exchange (COMTRADE) for Power Systems
IEEE 754:1985, IEEE Standard for Binary Floating-Point Arithmetic
IEEE 802.1 Q:1998, IEEE Standards for Local and Metropo/itan Networks: Virtual Bridged Local Area Networks
RFC 542, File Transfer Protocol for the ARPA Network, IETF, availab/e at <http://www.ietf.org>
RFC 768, User Oatagram Protocol, IETF, avai/able at <http://www.ietf.org>
RFC 791, Internet Protoco/ - DARPA Internet Program Protoco/ Specification, IETF, availableat <http://www.ietf.org>
RFC 792, Internet Control Message Protoco/ - DARPA Internet Program ProtocolSpecification, IETF, available at <http://www.ietf.org>
RFC 793, Transmission Control Procedure - DARPA Internet Program Protocol Specification,IETF, avai/able at <http://www.ietf.org>
RFC 826, An Ethernet Address Resolution Protoco/ or Converting Network Protocol Addresses to 48.bit Ethernet Address for Transmission on Ethernet Hardware, IETF, availab/e at <http://www.ietf.org>
61850-8-1 © IEC:2004(E) -15-
RFC 894, A Standard for the Transmission of IP datagrams over Ethernet Networks, IETF, available at <http://www.ietf.org>
RFC 919, Broadcasting Internet Datagrams, IETF, avai/able at <http://www.ietf.org>
RFC 922 Broadcasting Internet Datagrams in the presence of subnets, IETF, availab/e at <http://www.ietf.org>
RFC 950, Internet Standard Subnetting Procedure, IETF, avai/ab/e at <http://www.ietf.org>
RFC 959, File Transfer Protocol (FTP), IETF, available at <http://www.ietf.org>
RFC 1006 /SO transport services on top of TCP: Version 3, IETF, availab/e at <http://www. ietf. org>
RFC 1112, Host Extensions for IP Multicasting, IETF, avai/able at <http://www.ietf.org>
RFC 1122, Requirements for Internet Hosts - Communication Layers, IETF, available at <http://www.ietf.org>
RFC 1123, Requirements for Internet Hosts - Application and Support, IETF, available at <http://www.ietf.org>
RFC 2030, Simple Network Time Protocol (SNTP) Version 4, IETF, availab/e at <http://www. ietf. org>
INTERNATIONAL
STANDARD
Communication networks and systems in substations -
Part 9-1: Specific Communication Service Mapping (SCSM) -
IEC
61850-9-1
First edition
2003-05
Sampled values over serial unidirectional multidrop point to point link
© IEC 2003 - Copyright - all rights reserved
No part of thls publlcatlon may be reproduced or utilizad In any form or by any means, electronlc or mechanlcal, lncludlng photocopylng and microfilm, wlthout permlsslon In wrltlng from the publlsher.
lntematlonal Electrotechnlcal Commlsslon, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Swltzertand
Telephone: +41 22 919 02 11 Telefax: +41 22 919 03 00 E-mail: lnmall@lec.ch Web: www.lec.ch
Commlsslon Electrotechnlque lnternatlonale lnternatlonal Electrotechnlcal Commlsslon Me>t<AyHapOAH3R 3neKTPOT8XH"1�8CK8R KOM"1CC"1R
PRICE CODE U
For prlce, see current catalogue
-2- 61850-9-1 © IEC:2003(E)
CONTENTS
FOREWORD ...................... · .................................................................................................... 4
INTRODUCTION .................................................................................................................... 6
1 Scope ............................. : ................................................................................................ 7
2 Normative references ....................................................................................................... 8
3 Terms and definitions ....................................................................................................... 8
4 Abbreviations ................................................................................................................... 8
5 Principie of mapping to the serial unidirectional multidrop point to point link ..................... 9
5.1 Communication stack .............................................................................................. 9
5.1.1 Physical !ayer ............................................................................................. 1 O
5.1.2 Link layer ................................................................................................... 11
5.1.3 Network layer ............................................................................................. 12
5.1.4 Transport layer ........................................................................................... 12
5.1.5 Session !ayer ............................................................................................. 12
5.1.6 Presentation !ayer ...................................................................................... 12
5.1. 7 Application layer ......................................................................................... 12
5.2 Restrictions ............................................................................................................ 12
6 Mapping of common types ............................................................................................... 12
6.1 Object name .......................................................................................................... 12
6.2 Object reference .................................................................................................... 12
7 Mapping of the model for transmission of sampled values using multicast.. ...................... 13
7.1 Mapping of the multicast sampled values services .................................................. 13
7 .2 Mapping of the update of the sampled val u e buffer ................................................. 14
7.3 Additional definitions for the transmission of sampled analogue values ................... 14
7.3.1 Application layer functionality ..................................................................... 14
7.3.2 Presentation layer functionality ................................................................... 15
7.3.3 Transport layer functionality ....................................................................... 15
8 Mapping of the common data classes .............................................................................. 16
8.1 Overview ............................................................................................................... 16
8.2 Additional definitions for the mapping of the common data classes ......................... 16
Annex A (normative) Definition of data set instances and related multicast sampled val u e control instan ces .......................................................................................................... 19
Annex B (informative) Calculation of required bandwidth ....................................................... 22
Annex C (informative) Definitions of logical node instance names and data names related to the data sets .......................................................................................................... 24
Annex D (informative) Electronic transformers block diagram and configuration example ..... 28
61850-9-1 © IEC:2003(E) -3-
Figure 1 - Example for the use of the serial unidirectional multidrop point to point link ............ 7
Figure 2 - Communication stack ............................................................................................ 1 O
Figure 3 - Concatenation of several ASDU's into one APDU .................................................. 14
Figure A.1 - Data set for status indication .............................................................................. 20
Figure B.1 - Ethernet Frame Format ...................................................................................... 23
Figure C.1 - Contents of the universal data set based on the specification in IEC 60044-8 .... 27
Figure D.1 - Example for general block diagram of a single-phase electronic transformer ..... 28
Figure 0.2 - Example for electronic transformers configuration .............................................. 29
Table 1 - Mapping of the object reference ............................................................................. 13
Table 2 - Mapping of the multicast sampled value services .................................................... 13
Table 3 - Encoding for the transmission of sampled value buffer ........................................... 15
Table 4 - Extended common data class single point status information .................................. 16
Table 5 - Encoding of the common data class SPS u sed for the universal data set ................ 16
Table 6 - Encoding of the common data class MV ................................................................. 17
Table 7 - Encoding of common data class SPS used for the status indication group ............... 18
Table A.1 - Predefined multicast sampled value control block instances relating to the transmission of the Universal Data Set according to IEC 60044-8 ................................. 19
Table A.2 - Predefined multicast sampled value control block instances relating to the transmission of status indications .......................................................................................... 21
Table B.1 - Selection g'uide for Ethernet physical layer (receiving node) ................................. 22
Table B.2 - Selection guide for Ethernet physical layer (sending node) .................................. 22
Table C.1 - Definitions of logical instance name and data names related to the universal data set ... : .............................................................................................................. 24
Table C.2 - Definitions of logical instance name and data names related to the status indication data set ................................................................................................................. 26
-4- 61850-9-1 © IEC:2003(E)
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS-
Part 9-1: Specific Communication Service Mapping (SCSM) -Sampled values over serial unidirectional multidrop
point to point link
FOREWORD
1) The IEC (lnternational Electrotechnical Commission) is a worldwide organisation for standardisation comprisingali national electrotechnical committees (IEC National Committees). The object of the IEC is to prometeinternational co-operation on ali questions concerning standardisation in the electrical and electronic fields. Tothis end and in addition to other activities, the IEC publishes lnternational Standards. Their preparation isentrusted to technical committees; any IEC National Committee interested in the subject dealt with mayparticipate in this preparatory work. lnternational, governmental and non-governmental organisations liaisingwith the IEC also participate in this preparation. The IEC collaborates closely with the lnternational Organisationfor Standardisation (ISO) in accordance with conditions determined by agreement between the twoorganisations.
2) The formal decisions or agreements of the IEC on technical matters express, as nearly as possible, aninternational consensus of opinion on the relevant subjects since each technical committee has representationfrom ali interested National Committees.
3) The documents produced have the form of recommendations for international use and are published in the formof standards, technical specifications, technical reports or guides and they are accepted by the NationalCommittees in that sense.
4) In order to promete international unification, IEC National Committees undertake to apply IEC lnternationalStandards transparently
1 to the maximum extent possible in their national and regional standards. Any
divergence between !he IEC Standard and the corresponding national or regional standard shall be clearlyindicated in !he latter.
5) The IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for anyequipment declared to be in conformity with one of its standards.
6) Attention is drawn to the possibility that sorne of the elements of this lnternational Standard may be the subjectof patent rights. The IEC shall not be held responsible for identifying any or ali such patent rights.
lnternational Standard IEC 61850-9-1 has been prepared by IEC technical committee 57: Power system control and associated communications.
The text of this standard is based on the following documents:
FDIS Report on voting
57/619/FDIS 57/636/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 2.
61850-9-1 © IEC:2003(E) -5-
IEC 61850 consists of the following parts, under the general title Communication networks and systems in substations.
Part 1: lntroduction and overview
Part 2: Glossary 1
Part 3: General requirements
Part 4: System and project management
Part 5: Communication requirements for functions and devices models 2
Part 6: Configuration description language for communication in electrical substations related to IEDs 1
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
Part 7-4: Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes
Part 8-1: Specific communication service mapping (SCSM) - Mappings to MMS (ISO/IEC 9506-1 and ISO/IEC 9506-2) and to ISO/IEC 8802-3 1
Part 9-1: Specific communication service mapping (SCSM) - Sampled values over serial unidirectiona,i multidrop point to point link
Part 9-2: Specific communication service mapping (SCSM) - Sampled values over ISO/IEC 8802-3 1
Part 1 O: Conformance testing 1
The relationship between IEC 60044-8 and this standard is as follows:
IEC 60044-8 defines a merging unit as interface to electronic current and voltage transformers. Data objects provided by that merging unit are specified in IEC 60044-8. This standard specifies a serial communication interface between the merging unit and equipment using the digital output of the merging unit like protection or metering equipment. For the specification of that serial interface, a subset of the abstract communication services defined in IEC 61850-7-2 are mapped on an ISO/IEC 8802-3 based communication link.
The committee has decided that the contents of this publication will remain unchanged until 2005. At this date, the publication will be
• reconfirmed;• withdrawn;• replaced by a revised edition, or• amended.
A bilingual version of this standard may be issued at a later date .
1 Under consideration.
2 To be published.
-6-
INTRODUCTION
61850-9-1 © IEC:2003(E)
This part of IEC 61850 applies to electronic current and voltage transformers (ECT and EVT) with a digital output via a. merging unit, for use with electronic measuring instruments and electronic protective devices.
The transformer technology can be based on optical arrangements equipped with electronic components, on air core coils (with or without a built-in integrator) or, on iron core coils with integrated burden and used as a current to voltage converter, alone or equipped with electronic components.
For digital output, this standard takes into account a point to point connection from the merging unit to electronic measuring instruments and electronic devices.
This mapping allows interoperability between devices from different manufacturers.
This standard does not specify individual implementations or products, nor does it constrain the implementation of entities and interfaces within a computer system. This standard specifies the externally visible functionality of implementations.
Reading Guide
• The point to point transformer interface as defined here is based on the concepts describedin IEC 60044-8. This standard extends this concept and proposes an alternative link layerto provide a solution for transmitting sampled measured values via Ethernet basedinterfaces. For the definition and measurement of the accuracy, synchronisation methods,data rates etc. of the transformers, refer to IEC 60044-8.
• This document can best be understood if the reader is thoroughly familiar with Parts 7-1,7-2, 7-3 and 7-4 of this Standard.
• No explanations to the ACSI services are given in this part of the standard. For detailedinformation about the use of the ACSI services, refer to IEC 61850-7-2.
! 61850-9-1 © IEC:2003(E) -7-
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS -
Part 9-1: Specific Communication Service Mapping (SCSM) -Sampled values over serial unidirectional multidrop
point to point link
1 Scope
This part of IEC 61850 specifies the specific communication service mappings for the communication between bay and process level and it specifies a mapping on a serial unidirectional multidrop point to point link in accordance with IEC 60044-8. This part of IEC 61850 specifies a mapping of the abstract service for the transmission of sampled values (as defined in IEC 61850-7-2) on a serial unidirectional multidrop point to point link in accordance with IEC 60044-8. lt applies to the communication between merging units of electronic current (ECT) or voltage-transformers (EVT) and bay devices such as protection relays. lf higher requir:ements on sampling rate, further sampled measured value data sets in addition to the universal data set, inter-bay communication and synchronisation apply, these will be covered by IEC 61850-9-23. Figure 1 shows the schematics of this interface.
Line protection
Ethernet controller
Proprietary link
Ethernet controller
Merging unit
Bay controller
Ethernet controller
Serial unidirectional multidrop point to point link
Synchronisation, monitoring, test and configuration interfaces
Binary inputs
IEC 812/03
Figure 1 - Example for the use of the serial unidirectional multidrop point to point link
3 Under consideration.
-8- 61850-9-1 © IEC:2003(E)
2 Normative references
The fallawing referenced documents are indispensable far the applicatian af this dacument. Far dated references, anly the editian cited applies. Far undated references, the latest editian af the referenced dacument (including any amendments) applies.
IEC 60044-7: lnstrument Transformers - Part 7: Electronic voltage transformers
IEC 60044-8: lnstrument Transformers - Part 8: E/ectronic current transformers
IEC 60874-10-1:1997, Connectors for optical fibres and cables - Part 10-1: Detail specificationfor fibre optic connector type BFOC/2, 5 terminated to multimode fibre type A 1
IEC 61850-7-2: Communication networks and systems in substations - Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication serviceinterface (ACSI)
IEC 61850-7-3: Communication networks and systems in substations - Part 7-3: Basiccommunication structure for substation and feeder equipment - Common data classes
ISO/IEC 8802-3: /nformation technology - Telecommunications and information exchange between systems - Local and metropolitan area networks - Specific requirements - Part 3: Carrier sense mu/tiple access with collision detection (CSMAICD) access method and physical /ayer specifications
ISO/IEC 8825-1: lnformation techno/ogy - ASN.1 encoding rules: Specification of Basic EncodingRules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)
IEEE 802.1 Q-1998: IEEE Standards for Local and Metropolitan Area Networks: Virtual Bridged Local Area Networks
IEEE 802.3: lnformation Technology - Telecommunication and lnformation Exchange BetweenSystems - LANIMAN - Specific Requirements - Part 3: Carrier Sense Mu/tiple Access withCollision Detection (CSMAICD) Access Method and Physical Layer Specifications
INTERNATIONAL
S.TANDARD
IEC
61850-9-2
First edition
2004-04
Communication networks and systems in substations -
Part 9-2: Specific Communication Service Mapping (SCSM) -Sampled values over 1SO/IEC 8802-3
© IEC 2004 - Copyright - all rights reserved
No part of this publication may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying and mi_crofilm, without permission in writing from the publisher.
lntemational Electrotechnical Commission, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Switzerland
Telephone: +41 22 919 02 11 Telefax: +41 22 919 03 00 E-mail: inmail@iec.ch Web: www.iec.ch
DI Commisslon Electrotechnlque lnternatlonale lnternalional Electrotechnlcal Commission Me)t(,(lyHapOAH8R 3neKTpOTeXH11Y8CKaR KOMl1CCl1R
PRICE CODE U
For prlce, see current catalogue
-2- 61850-9-2 © IEC:2004(E)
CONTENTS
FOREWORD ........................................................................................................................... 4
INTRODUCTION ............... : ..................................................................................................... 6
1 Scope ............................................................................................................................... 7
2 Normative references ........................................................................................................ 7
3 Terms and definitions ....................................................................................................... 9
4 Abbreviations .................................................................................................................... 9
5 Communication stack ...................................................................................................... 1 O
5.1 Overview of the protocol usage .............................................................................. 1 O 5.2 ClienUserver services and communication profiles ................................................. 11 5.3 SV service and communication profile .................................................................... 13 5.4 Restrictions ........................................................................................................... 15
6 Mapping of IEC 61850-7-2 and IEC 61850-7-3 Data Attributes ......................................... 16
7 Mapping of IEC 61850-7-2 classes and services ............................................................. 16
7 .1 Classes of SV data sets ......................................................................................... 16 7.2 Definition of SV data sets ....................................................................................... 16
8 Mapping of the model for the transmission of sampled values ......................................... 16
8.1 Overview ............................................................................................................... 16 8.2 Mapping of the multicast sampled value control block class and services ............... 16 8.3 Mapping of t�e unicast sampled value control block class and services .................. 17 8.4 Mapping of the update of the sampled value buffer ................................................. 19 8.5 Additional definitions for the transmission of sampled values .................................. 19 8.6 Definitions for basic data types .............................................................................. 21
9 Conformance .................................................................................................................. 21
9.1 Notation ................................................................................................................. 21 9.2 PICS ...................................................................................................................... 21
1 O Substation Configuration language (SCL) ........................................................................ 23
Annex A (informative) 1SO/IEC 8802-3 frame format and ASN.1 basic encoding rules ............ 24
Annex B (informative) Process bus architectures .................................................................. 27
Annex C (informative) Multicast address selection ................................................................ 28
Figure 1 - OSI reference model and profiles .......................................................................... 10
Figure 2 - Structure of the tag header ................................................................................... 14
Figure 3 -Concatenation of severa! ASDU's into one frame ................................................... 19
Figure A. 1 -1SO/IEC 8802-3 frame format ........................................................................... 24
Figure A.2 - Basic encoding rules format .............................................................................. 25
Figure A.3 - Format of the tag octets .................................................................................... 25
Figure A.4 - Example for an ASN.1 coded APDU frame structure ............................................ 26
Figure 8.1 -Alternative process bus architectures ................................................................ 27
61850-9-2 © IEC:2004(E) -3-
Table 1 - Service requiring client/server communication profile ............................................. 11
Table 2 - Service and protocols for client/server communication A-Profile ............................. 12
Table 3 - Service and Protocols for Peer TCP/IP T-Profile ..................................................... 12
Table 4 - Service requiring SV communication profile ............................................................ 13
Table 5 - Service and protocols for SV communication A-Profile ............................................ 13
Table 6- SV T-Profile ........................................................................................................... 13
Table 7 - Default Virtual LAN IDs and priorities ..................................................................... 14
Table 8 -Assigned Ethertype values ...... : .............................................................................. 15
Table 9 - MMS TypeDescription definition for MSVCB MMS structure ....................................... 17
Table 10 - Mapping of multicast sampled value services ....................................................... 17
Table 11 - MMS TypeDescription definition for USVCB MMS Structure ..................................... 18
Table 12 - Mapping of unicast sampled value services .......................................................... 18
Table 13 -Encoding for the transmission of the sampled value buffer ................................... 20
Table 14 - Encoding_ for the basic data types ......................................................................... 21
Table 15 - PICS for A-Profile support ..................................................................................... 22
Table 16 - PICS for T-Profile support ..................................................................................... 22
Table 17 - SV conformance statement. .................................................................................. 22
Table 18 - Definitions for SV SCL .......................................................................................... 23
-4- 61850-9-2 © IEC:2004(E)
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS-
Part 9-2: Specific Communication Service Mapping (SCSM) -Sampled values over 1SO/IEC 8802-3
FOREWORD
1) The lnternational Electrotechnical Commission (IEC) is a worldwide organization for standardization comprisingall national electrotechnical commlttees (IEC National Committees). The object of IEC is to prometeinternational co-operation on all questions concerning standardization in the electrlcal and electronic fields. To this end and in addition to other activities, IEC publishes lnternational Standards, Technical Specifications,Technical Reports, Publicly Available Specifications (PAS) and Guides (hereafter referred to as "IEC Publication(s)"). Thelr preparation is entrusted to technical committees; any IEC National Committee interestedin the subject dealt with may participate in this preparatory work. lnternational, governmental and nongovernmental organizations liaising with the IEC also participate in this preparation. IEC collaborates closelywith the lnternational Organization for Standardization (ISO) in accordance with conditions determined byagreement between the two organizations.
2) The formal decisions or agreements of IEC on technical matters express, as nearly as possible, an internationalconsensus of opinion on the relevant subjects since each technical committee has representation from allinterested IEC National Committees.
3) IEC Publications have the form of recommendations for international use and are accepted by IEC NationalCommittees in that sense. While all reasonable efforts are made to ensure that the technical content of IECPublications is accurate, IEC cannot be held responsible for the way in which they are used or for anymisinterpretation by any end usar.
4) In order to promete international uniformity, IEC Natlonal Committees undertake to apply IEC Publicationstransparently to the m�ximum extent possible in their national and regional publications. Any divergencebetween any IEC Publication and the corresponding national or regional publication shall be clearly indicated inthe latter.
5) IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for anyequipment declared to be in conformity with an IEC Publication.
6) AII users should ensure that they have the latest edition of this publication.
7) No liability shall attach to IEC or its directors, employees, servants or agents including individual experts andmembers of its technical committees and IEC National Committees for any personal injury, property damage orother damage of any nature whatsoever, whether direct or indirect, or for costs (including legal fees) andexpenses arising out of the publication, use of, or reliance upon, this IEC Publication or any other IECPublications.
8) Attention is drawn to the Normative references cited in this publication. Use of the referenced publications isindispensable for the correct application of this publication.
9) Attention is drawn to the possibility that sorne of the elements of this IEC Publication may be the subject of patent rights. IEC shall not be heid responsible for identifying any or all such patent rights.
lnternational Standard IEC 61850-9-2 has been preparad by IEC technical committee 57: Power systems management and associated information exchange.
The text of this standard is based on the following documents:
FDIS Report on voting
57/690/FDIS 57/709/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 2.
61850-9-2 © IEC:2004(E) -5-
IEC 61850 consists of the following parts, under the general title Communication networks and systems in substations:
Part 1: lntroduction and overview
Part 2: Glossary
Part 3: General requirements
Part 4: System and project management
Part 5: Communication requirements for functions and device models
Part 6: Configuration description language for communication in electrical substations related to IEDs
Part 7-1: Basic communication structure for substation and feeder equipment - Principies and models
Part 7-2: Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Part 7-3: Basic communication structure for substation and feeder equipment - Common data classes
Part 7-4: Basic communication structure for substation and feeder equipment - Compatible logical node classes and data classes
Part 8-1: Specific Communication Service Mapping (SCSM) - Mappings to MMS (ISO 9506-1 and ISO 9506-2) and to 1SO/IEC 8802-3
Part 9-1: Specific Communication Service Mapping (SCSM) - Sampled values over serial unidirectiona,I multidrop point to point link
Part 9-2: Specific Communication Service Mapping (SCSM) - Sampled values over 1SO/IEC 8802-3
Part 1 O: Conformance testing 1
The committee has decided that the contents of this publication will remain unchanged until 2005. At this date, the publication will be
• reconfirmed;
• withdrawn;
• replaced by a revised edition, or
• amended.
A bilingual version of this document may be issued at a later date.
1 Under consideration.
-6- 61850-9-2 © IEC:2004(E)
INTRODUCTION
This part of IEC 61850 defines the SCSM for sampled values over ISO/IEC 8802-3. The intent of this SCSM definition is to supplement IEC 61850-9-1 to include the complete mapping of the sampled value model.
This part of IEC 61850 applies to electronic current and voltage transformers (ECT and EVT having a digital output), merging units, and intelligent electronic devices for example protection units, bay controllers and meters.
Process bus communication structures can be arranged in different ways as described in Annex B and IEC 61850-1. In addition to the transmission of sampled value data sets, which are directly connected to ISO/IEC 8802-3, a selection of IEC 61850-8-1 services are necessary to support the access to the SV control block. References to the relevant IEC 61850-8-1 services are provided in this SCSM. For less complex devices (for example merging units) the sampled value control block can be pre-configured, in which case there is no need to implement IEC 61850-8-1 services based on the MMS-Stack.
This document defines the mapping of sampled value class model (IEC 61850-7-2) to ISO/IEC 8802-3. This SCSM, in combination with IEC 61850-7 and IEC 61850-6, allows interoperability between devices from different manufacturers.
This standard does not specify individual implementations or products, nor does it constrain the implementation of entities and interfaces within a computer system. This standard specifies the externally visible functionality of implementations together with conformance requirements for such functionalities.
Reading Guide
• This document is an extended mapping specification of IEC 61850-9-1 and IEC 61850-8-1to cover sampled value transmission over ISO/IEC 8802-3.
• This document can best be understood if the reader is thoroughly familiar with IEC 61850-7-1, IEC 61850-7-2, IEC 61850-7-3 and IEC 61850-7-4.
• The ACSI services defined in IEC 61850-7-2 are not explained in this part of the standard.
61850-9-2 © IEC:2004(E) -7-
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS -
Part 9-2: Specific Communication Service Mapping (SCSM) -Sampled values over 1S0/IEC 8802-3
1 Scope
This part of IEC 61850 defines the Specific Communication Service Mapping (SCSM) for the transmission of sampled values according to the abstract specification in IEC 61850-7-2. The mapping is that of the abstract model on a mixed stack using direct access to an ISO/IEC 8802-3 link for the transmission of the samples in combination with IEC 61850-8-1.
Each SCSM consists of three parts:
- a specification of the communication stack being used,
- the mapping of the abstract specifications of IEC 61850-7 on the real elements of the stackbeing used, and
- the implementation specification of functionality, that is not covered by the stack beingused.
2 Normative references
The following referencéd documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies.
IEC 60874-10-1, Connectors for optical fibres and cables - Part 10-1: Detail specification forfibre optic connector type BFOC/2, 5 terminated to multimode fibre type A 1
IEC 60874-10-2, Connectors for optical fibres and cables - Part 10-2: Detail specification forfibre optic connector type BFOC/2, 5 terminated to single-mode fibre type B 1
IEC 60874-10-3, Connectors for optical fibres and cables - Part 10-3: Detail specification forfibre optic adaptar type BFOC/2, 5 for single and multimode fibre
IEC 61850-7-1, Communication networks and systems in substations - Part 7-1: Basiccommunication structure for substation and feeder equipment - Part 7-1: Principies and models
IEC 61850-7-2, Communication networks and systems in. substations - Part 7-2: Basiccommunication structure for substation and feeder equipment - Abstract communicationservice interface (ACSI)
IEC 61850-7-3, Communication networks and systems in substations - Part 7-3: Basiccommunication structure for substation and feeder equipment - Common data classes
IEC 61850-7-4, Communication networks and systems in substations - Part 7-4: Basiccommunication structure for substation and feeder equipment - Compatible logical nodeclasses and data classes
IEC 61850-8-1, Communication networks and systems in substations - Part 8-1: SpecificCommunication Service Mapping (SCSM) - Mappings to MMS (ISO 9506-1 and ISO 9506-2) andto ISO/IEC 8802-3
-8- 61850-9-2 © IEC:2004(E)
IEC 61850-9-1, Communication networks and systems in substations - Part 9-1: Specific Communication Service Mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
ISO/IEC 7498-1 :1994, lnfbrmation technology - Open Systems lnterconnection - BasicReference Model: The Basic Model
ISO/IEC 8326: 1996, lnformation processing systems - Open Systems lnterconnection -
Session service definition
ISO/IEC 8327-1: 1997, lnformation technology - Open Systems lnterconnection - Connectionoriented session protocols: Protocol specification
ISO/IEC 8649:1996, lnformation technology - Open Systems lnterconnection - Servicedefinition for the Associated Control Service Element
ISO/IEC 8650-1:1996, /nformation technology - Open Systems lnterconnection - Connectionoriented protocol for the Association Control Service Element: Protocol specification
ISO/IEC 8802-3:2001, lnformation techno/ogy - Telecommunications and information exchange between systems - Local and metropolitan area networks - Specific requirements - Part 3: Carrier sense mu/tiple access with col/ision detection (CSMAICD) access method and physical /ayer specifications
ISO/IEC 8822:1994, lnformation technology - Open Systems lnterconnection - Presentation service definition
ISO/IEC 8823-1: 1994, lnformation technology - Open Systems lnterconnection - Connectionoriented presentation protocol: Protoco/ specification
ISO/IEC 8824-1:1999,, /nformation technology - Abstract Syntax Notation One (ASN. 1):Specification of basic notation Amendment 1 (2000) Amendment 2 (2000)
ISO/IEC 8825-1, lnformation technology - ASN.1 encoding rules: Specification of Basic Encoding Rules (BER), Canonical Encoding Rules (CER) and Distinguished Encoding Rules (DER)
ISO 9506-1 :2003, Industrial automation systems - Manufacturing Message Specification -
Part 1: Service definition
ISO 9506-2:2003, Industrial automation systems - Manufacturing Message Specification -
Part 2: Protocol specification
IEEE 754:1985, IEEE Standard for Binary Floating-Point Arithmetic
IEEE 802.1 Q:1998, IEEE Standards for Local and Metropolitan Area Networks: Virtual Bridged Local Area Networks
RFC 791, Internet Protocol; IETF, available at <http://www.ietf.org>
RFC 792, Internet Control Message Protocol; IETF, available at <http://www.ietf.org>
RFC 793, Transmission Control Procedure; IETF, available at <http://www.ietf.org>
RFC 826, An Ethernet Address Reso/ution Protocol or Converting Network Protocol Addresses to 48.bit Ethernet Address for Transmission on Ethernet Hardware; IETF, available at <http://www. ietf. org>
RFC 894, A Standard for the Transmission of IP datagrams over Ethernet Networks; IETF, available at <http://www. ietf. org>
61850-9-2 © IEC:2004(E) -9-
RFC 919, Broadcasting Internet Datagrams; IETF, available at <http://www.ietf.org>
RFC 1006 /SO transport services on top of TCP: Version 3; IETF, available at <http://www. ietf. org>
RFC 1112, Host Extensions for IP Mu/ticasting; IETF, avai/able at <http://www.ietf.org>
INTERNATIONAL
STANDARD
IEC
61850-10
First edition
2005-05
Communication networks and systems in substations -
Part 1 O: Conformance testing
© IEC 2005 - Copyright - all rights reserved
No part of this publication may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying and microfilm, without permission in writing from the publisher.
lntemational Electrotechnical Commission, 3, rue de Varembé, PO Box 131, CH-1211 Geneva 20, Switzeriand
Telephone: +41 22 919 02 11 Telefax: +41 22 919 03 00 E-mail: inmail@iec.ch Web: www.iec.ch
mCommlsslon Electrotechnlque lnternatlonale lnternatlonal Electrotechnical Commlsslon Me>K,llyHapOAHaA 3neKTpOT0XHl'1�0CKaA KOMl'1CCl'1A
PRICE CODE X
For prlce, see current catalogue
-2- 61850-10 © IEC:2005(E)
CONTENTS
FOREWORD ........................................................................................................................... 4
INTRODUCTION .............. .' ...................................................................................................... 6
1 Scope ............................................................................................................................... 7
2 Normative references ....................................................................................................... 7
3 Terms and definitions ....................................................................................................... 8
4 Abbreviated terms .......................................................................................................... 1 O
5 lntroduction to conformance testing ................................................................................ 11
5.1 General ................................................................................................................. 11
5.2 Conformance test procedures ................................................................................ 12
5.3 Quality assurance and testing ............................................................................... 12
5.3.1 General ..................................................................................................... 12
5.3.2 Quality plan ............................................................................................... 13
5.4 Testing .................................................................................................................. 14
5.4.1 General ..................................................................................................... 14
5.4.2 Use of SCL files ........................................................................................ 16
5.4.3 Device testing ............................................................................................ 16
5.5 Documentation of conformance test report ............................................................ 16
6 Device related conformance testing ................................................................................ 17
6.1 General guidelines ................................................................................................ 17
6.1.1 Test methodology ...................................................................................... 17
6·. 1.2 Test system architectures .......................................................................... 17
6.2 Conformance test procedures ................................................................................ 18
6.2.1 General ..................................................................................................... 18
6.2.2 Test procedure requirements ..................................................................... 18
6.2.3 Test structure ............................................................................................ 19
6.2.4 Test cases to test a server ........................................................................ 20
6.2.5 Acceptance criteria .................................................................................... 37
7 Performance tests .......................................................................................................... 38
7 .1 General ................................................................................................................. 38
7.2 Communications latency ........................................................................................ 38
7.2.1 Application domain .................................................................................... 38
7.2.2 Methodology .............................................................................................. 39
7.3 Time synchronisation and accuracy ...................................................................... .40
7.3.1 Application domain .................................................................................... 40
7.3.2 Methodology .............................................................................................. 40
7.3.3 Testing criteria .......................................................................................... 41
7.3.4 Performance .............................................................................................. 41
8 Additional tests ............................................................................................................... 41
Annex A (informative) Examples of test procedure template ................................................. 42
Bibliography .......................................................................................................................... 43
61850-1 O© IEC:2005(E) -3-
Figure 1 -Conceptual conformance assessment process ..................................................... 15
Figure 2 -Conceptual test system architecture ..................................................................... 18
Figure 3 -Test procedure format .......................................................................................... 19
Figure 4 - Performance testing (black box principie) ............................................................. 39
Figure 5 -Time synchronisation and accuracy test setup .................................................... .40
Table 1 - Positive test cases ............................ .-................................................................... 22
Table 2 - Negative test cases ............................................................................................... 22
Table 3 - Positive test cases ................................................................................................ 22
Table 4 - Negative test cases ............................................................................................... 23
Table 5 - Positive test cases ................................................................................................ 23
Table 6 - Negative test cases ............................................................................................... 24
Table 7 - Positive test cases ................................................................................................ 24
Table 8 - Negative test cases ............................................................................................... 25
Table 9 - Positive test cases ................................................................................................ 25
Table fO - Negative test cases ............................................................................................. 25
Table 11 - Positive test cases .............................................................................................. 26
Table 12 -Negative test cases ............................................................................................. 28
Table 13 - Positive test cases .............................................................................................. 28
Table 14 - Negative test cases ............................................................................................. 29
Table 15 - Positive test cases .............................................................................................. 29
Table 16 - Positive test cases .............................................................................................. 30
Table 17 - Negative test cases ............................................................................................. 30
Table 18 - Negative test cases ............................................................................................. 31
Table 19 - Positive test cases .............................................................................................. 31
Table 20 - Positive test cases .............................................................................................. 31
Table 21 - Negative test cases ....................................... : ..................................................... 32
Table 22 - Negative test cases ............................................................................................. 32
Table 23 - Positive test cases .............................................................................................. 32
Table 24 - Test cases for SBOes .......................................................................................... 33
Table 25 -Test cases for DOns ............................................................................................ 34
Table 26 -Test cases for SBOns .......................................................................................... 34
Table 27 - Test cases for DOes ............................................................................................ 35
Table 28 - Negative test cases ............................................................................................. 35
Table 29 - Positive test cases .............................................................................................. 36
Table 30 -Negative test cases ............................................................................................. 36
Table 31 - Positive test cases .............................................................................................. 36
Table 32 - Negative test cases ............................................................................................. 37
Table 33 - Combination test case ......................................................................................... 37
-4- 61850-1 O© IEC:2005(E)
INTERNATIONAL ELECTROTECHNICAL COMMISSION
COMMUNICATION NETWORKS ANO SYSTEMS IN SUBSTATIONS -
Part 1 O: Conformance testing
FOREWORD
1) The lnternational Electrotechnical Commission (IEC) is a worldwide organization for standardization comprisingall national electrotechnical committees (IEC National Committees). The object of IEC is to promoteinternational co-operation on all questions concerning standardization in the electrical and electronic fields. Tothis end and in addition to other activities, IEC publishes lnternational Standards, Technical Specifications,Technical Reports, Publicly Available Specifications (PAS) and Guides (hereafter referred to as "IEC Publication(s)"). Their preparation is entrusted to technical committees; any IEC National Committee interested in the subject dealt with may participate in this preparatory work. lnternational, governmental and nongovernmental organizations llaising with the IEC also participate in this preparation. IEC collaborates closely with the lnternational Organization for Standardization (ISO) in accordance with condilions determined byagreement between the two organizations.
2) The formal decisions or agreements of IEC on technical matters express, as nearly as possible, an internalionalconsensus of opinion on the relevant subjects since each technical committee has representation from all interested IEC National Committees.
3) IEC Publications have the form of recommendations for international use and are accepted by IEC NalionalCommittees in that sense. While all reasonable efforts are made to ensure that the technical content of IECPublicalions is accurate, IEC cannot be held responsible for the way in which they are used or for anymisinterpretation by any end user.
4) In order to promote international uniformity, IEC National Committees undertake to apply IEC Publicationstransparently to the maximum extent possible in their national and regional publications. Any divergencebetween any IEC Publication and the corresponding national or regional publicalion shall be clearly indicated in the latter.
5) IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for anyequipment declared to be in conformity with an IEC Publication.
6) AII users should ensure that they have the lates! edition of this publication.
7) No liability shall attach to IEC or its directors, employees, servants or agents including individual experts and members of its technical committees and IEC National Committees for any personal injury, property damage or other damage of any nature whatsoever, whether direct or indirect, or for costs (including legal fees) andexpenses arising out of the publicalion, use of, or reliance upon, this IEC Publication or any other IECPublications.
8) Attention is drawn to the Normativa references cited in this publication. Use of the referenced publications is indispensable for the correct application of this publication.
9) Attention is drawn to the possibility that sorne of the elements of this IEC Publication may be the subject ofpatent rights. IEC shall not be held responsible for idenlifying any or all such patent rights.
lnternational Standard IEC 61850-1 O has been prepared by IEC technical committee 57: Power systems management and associated information exchange.
The text of this standard is based on the following documents:
FDIS Report on voting
57/742/FDIS 57/749/RVD
Full information on the voting for the approval of this standard can be found in the report on voting indicated in the above table.
This publication has been drafted in accordance with the ISO/IEC Directives, Part 2.
61850-10 © IEC:2005(E) -5-
IEC 61850 consists of the following parts, under the general title Communication networks and systems in substations:
Part 1:
Part 2:
Part 3:
Part 4:
Part 5:
Part 6:
Part7-1:
Part 7-2:
Part 7-3:
Part 7-4:
Part 8-1:
Part 9-1:
Part 9-2:
Part 10:
lntroduction and overview
Glossary
General requirements
System and project management
Communication requirements for functions and device models
Configuration description language for communication in electrical substations related to IEDs
Basic communication structure for substation and feeder equipment - Principies and models
Basic communication structure for substation and feeder equipment - Abstract communication service interface (ACSI)
Basic communication structure for substation and feeder equipment - Common data classes
Basic communication structure for substation and feeder equipment - Compatible logical nade classes and data classes
Specific Communication Service Mapping (SCSM) - Mappings to MMS (ISO 9506-1 and ISO 9506-2) and to ISO/IEC 8802-3
Specific Communication Service Mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
Specific Communication Service Mapping (SCSM) - Sampled values over ISO/IEC 8802-3
Conformance testing
The committee has decided that the contents of this publication will remain unchanged until the maintenance result date indicated on the IEC web site under "http://webstore.iec.ch" in the data related to the specific publication. At this date, the publication will be
• reconfirmed;
• withdrawn;
• replaced by a revised edition, or
• amended.
A bilingual edition of this standard may be issued at a later date.
-6- 61850-1 O © IEC:2005(E)
INTRODUCTION
This part of IEC 61850 is part of a set of specifications which details a layered substation communication architecture.
This part of IEC 61850 defines:
• the methods and abstract test cases for conformance testing of devices used insubstation automation systems, and
• the metrics to be measured within devices according to the requirements defined inIEC 61850-5.
The intended readers are test system developers.
NOTE 1 Tests regarding EMC requirements and environmental condltions are subject to IEC 61850-3 and not included in this part of IEC 61850.
NOTE 2 lt is recommended that IEC 61850-5 and IEC 61850-7-1 be read first in conjunction with IEC 61850-7-2, IEC 61850-7-3, and IEC 61850-7-4.
NOTE 3 Abbreviations used in IEC-61-850-1 O are listad in Clause 4 or may be found in other parts of IEC 61850 that are relevant for conformance testlng.
61850-1 O © IEC:2005(E) -7-
1 Scope
COMMUNICATION NETWORKS AND SYSTEMS IN SUBSTATIONS -
Part 1 O: Conformance testing
This part of IEC 61850 specifies standard techniques for testing of conformance of implementations, as well as specific measurement techniques to be applied when declaring performance parameters. The use of these techniques will enhance the ability of the system integrator to integrate IEDs easily, operate IEDs correctly, and support the applications as intended.
NOTE 1 The role of the test facilities for conformance testing and certifying the results are beyond the scope of this part of IEC 61850.
NOTE 2 The test approach and test system design to test a client device is likely to be different across the broad range of clients. There are many possibilities to test clients. The client tests are beyond the scope of this part of IEC 61850. lt is intended to define client test requlrements durlng the malntenance of this part.
2 Normative references
The following referenced documents are indispensable for the application of this document. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies.
IEC 61850-2, Communication networks and systems in substations - Part 2: G/ossary
IEC 61850-4, Communication networks and systems in substations - Part 4: System andproject management
IEC 61850-5, Communication networks and systems in substations - Part 5: Communicationrequirements for functions and device models
IEC 61850-6, Communication networks and systems in substations - Part 6: Configurationdescription language for communication in e/ectrical substations related to IEDs
IEC 61850-7-1, Communication networks and systems in substations - Part 7-1: Basiccommunication structure for substation and feeder equipment - Principies and models
IEC 61850-7-2 , Communication networks and systems in substations - Part 7-2: Basiccommunication structure for substation and feeder equipment - Abstract communicationservice interface (ACSI)
IEC 61850-7-3, Communication networks and systems in substations - Part 7-3: Basiccommunication structure for substation and feeder equipment - Common data classes
IEC 61850-7-4 , Communication networks and systems in substations - Part 7-4: Basiccommunication structure for substation and feeder equipment - Compatible logical nodeclasses and data classes
IEC 61850-8-1, Communication networks and systems in substations - Part 8-1: Specificcommunication service mapping (SCSM) - Mappings to MMS (ISO 9506-1 and /SO 9506-2)and to ISO/IEC 8802-3
-8- 61850-10 © IEC:2005(E)
IEC 61850-9-1, Communication networks and systems in substations - Part 9-1: Specific Communication Service Mapping (SCSM) - Sampled values over serial unidirectional multidrop point to point link
IEC 61850-9-2, Communication networks and systems in substations - Part 9-2: Specific Communication Service Mapping (SCSM) - Sampled values over ISO/IEC 8802-3
1SO/IEC 9646-1, lnformation technology - Open Systems lnterconnection - Conformance testing methodology and framework - Part 1: General concepts
1SO/IEC 9646-2, lnformation technology - Open Systems lnterconnection - Conformance testing methodology and framework - Part 2: Abstract test suite specification
1SO/IEC 9646-4, lnformation technology - Open Systems lnterconnection - Conformance testing methodology and framework - Part 4: Test realization
1SO/IEC 9646-5, lnformation technology - Open Systems lnterconnection - Conformance testing methodology and framework - Part 5: Requirements on test laboratories and clients for the conformance assessment process
1SO/IEC 9646-6, lnformation technology - Open Systems lnterconnection - Conformance testing methoáology and framework - Part 6: Protocol profile test specification
TÉRMINOS USUALES
Este anexo presenta la interpretación de los términos usuales relacionados al tema y que
son utilizados en el informe.
1. IEDs. cualquier dispositivo electrónico utilizado en Subestaciones Eléctricas que
incorpora uno o mas procesadores con la capacidad de intercambiar datos y
efectuar secuencias de control desde o hacia una fuente externa. Ejemplos :
Reles de Proteccion, medidores , Equipos de Monitoreo de transformadores e
interruptores.
2. LAN . es la interconexión de varios IEDs , ordenadores, Switches, Routers. (LAN
es la abreviatura inglesa de Local Area Network o 'red de área local'). Su
extensión esta limitada físicamente a una Subestación o a un entorno de pocos
kilómetros. Su aplicación más extendida es la interconexión de ordenadores
personales y estaciones de trabajo en oficinas, fábricas, etc., para compartir
recursos e i,ntercambiar datos y aplicaciones. En definitiva, permite que dos o más
equipos se comuniquen
3. VPN . La Red Privada Virtual (RPV), en inglés Virtual Private Network (VPN), es
una tecnología de red que permite una extensión de la red local sobre una red
pública o no controlada, como por ejemplo Internet. Ejemplos comunes son, la
posibilidad de conectar dos o más sucursáles de una empresa utilizando como
vínculo Internet, permitir a los miembros del equipo de soporte técnico la conexión
desde su casa al centro de cómp_µto, o que un usuario pueda acceder a su equipo
doméstico desde un sitio remoto, como por ejemplo un hotel. Todo ello utilizando
la infraestructura de Internet.
4. TCP/IP. Es la familia de protocolos de internet � Es un conjunto de protocolos de
red en la que se basa Internet y que permiten la transmisión de datos entre redes
de computadoras. En ocasiones se la denomina conjunto de protocolos TCP/IP,
en referencia a los dos protocolos más importantes que la componen: Protocolo
de Control de Transmisión (TCP) y Protocolo de Internet (IP), que fueron los dos
primeros en definirse, y que son los más utilizados de la familia. Existen tantos
protocolos en este conjunto que llegan a ser más de 100 diferentes, entre ellos se
encuentra el popular HTTP (HyperText Transfer Protocol), que es el que se utiliza
para acceder a las páginas web, además de otros como el ARP (Address
183
Resolution Protocol) para la resolución de direcciones, el FTP (File Transfer
Protocol) para transferencia de archivos, y el SMTP (Simple Mail Transfer
Protocol) y el POP (Post Office Protocol) para correo electrónico, TELNET para
acceder a equipos remotos, entre otros.
5. IPV4, IPV6. IPv4 es la versión 4 del Protocolo IP (Internet Protocol). Esta fue la
primera versión del protocolo que se implementó extensamente, y forma la base
de Internet. IPv4 usa direcciones de 32 bits, limitándola a 232 = 4.294.967.296
direcciones únicas, muchas de las cuales están dedicadas a redes locales (LANs).
Por el crecimiento enorme que ha tenido del Internet (mucho más de lo que
esperaba, cuando se diseñó IPv4), combinado con el hecho de que hay
desperdicio de direcciones en muchos casos (ver abajo), ya hace varios años se
vio que escaseaban las direcciones IPv4. Esta limitación ayudó a estimular el
impulso hacia IPv6, que esta actualmente en las primeras fases de
implementación, y se espera que termine reemplazando a IPv4
6. Ethernet. es el nombre de una tecnología de redes de computadoras de área
local (LANs) basada en tramas de datos. El nombre viene del concepto físico de
ether. Ethernet define las características de cableado y señalización de nivel físico
y los formatos de trama del nivel de enlace de datos del modelo OSI. Ethernet se
refiere a las redes de área local y dispositivos bajo el estándar IEEE 802.3 que
define el protocolo CSMA/CD
7. DNP3. es un protocolo de adquisición de datos utilizado por las compañías
eléctricas, gas y agua con el fin de leer información de sus IEDs. Es diseñado
como un abierto, interoperable y simple protocolos para Sistemas Scada . Usa la
interrogación Maestra/Esclava para enviar y recibir información de IEDs.
8. UCVA 2.0. El Electric Power Research lnstitute (EPRI) desarrolló la suite de
protocolos conocida como "Utilities Communications Architecture versión 2" (UCA
2.0) . Este protocolo de adquisición de datos de IEDs es basado en la utilización
de Ethernet e incorpora la utilización de TCP/IP y MMS para las capas de
aplicación.
9. ICCP. También conocido como IEC 60870-6/TASE.2 . Es un protocolo de
intercambio de datos entre Centros de Control.
10. RTU. También conocido como UTR - Unidad Terminal Remota es un acrónimo
que define a un dispositivo basados en microprocesadores, el cual permite
obtener señales independientes de los procesos y enviar la información a un sitio
remoto donde se procese. Generalmente este sitio remoto es una sala de control
donde se encuentra un sistema central SCADA el cual permite visualizar las
184
variables enviadas por la UTR
11. Switch . en castellano "conmutador'', es un dispositivo electrónico de
interconexión de redes de ordenadores que opera en la capa 2 (nivel de enlace de
datos) del modelo OSI (Open Systems lnterconnection). Un conmutador
interconecta dos o más segmentos de red, funcionando de manera similar a los
puentes (bridges), pasando datos de un segmento a otro, de acuerdo con la
dirección MAC de destino de los datagramas en la red.
12. Router . en español enrutador, ruteador o encaminador es un dispositivo de
hardware para interconexión de redes de ordenadores que opera en la capa tres
(nivel de red). Un router es un dispositivo que permite asegurar el enrutamiento de
paquetes entre redes o determinar la ruta que debe tomar el paquete de datos.
13. Fibra Óptica. es un conductor de ondas en forma de filamento, generalmente de
vidrio, aunque también puede ser de materiales plásticos. La fibra óptica es capaz
de dirigir la luz a lo largo de su longitud usando la reflexión total interna.
Normalmente la 1oz es emitida por un láser o un LEO. Las fibras son ampliamente
utilizadas en telecomunicaciones, ya que permiten enviar gran cantidad de datos a
gran velocidad, mayor que las comunicaciones de radio y cable. También se
utilizan para redes locales. Son el medio de transmisión inmune a las
interferencias por excelencia
14. ICD. También llamado IED Configuration Description , Es el archivo que contiene'
las características de implementación del protocolo IEC 61850 en un IED.
15. SCD. Es el archivo que contiene la descripción de las comunicaciones lógicas
entre IEDs bajo el estándar IEC 61850.
16. GOOSE. es un acrónimo de Generic Object Orintated System Wide Events . Esta
reemplaza el convencional Cableado para que los IEDs intercambien información
entre ellos. En el momento que se detecta un evento (cambio de estado de un
Interruptor en un IED por ejemplo) , el IED usa una comunicación del tipo
Multicast (envío de información a múltiples destinos) para notificar a los otros IEDs
que se encuentran en el mismo BUS que ha ocurrido un evento
BIBLIOGRAFiA
[1] Kema lnc, "Substation Communications : Enabler of Automation" , United Telecom
Council - USA - Washington DC, 2006
[2] Electric Power Research lnstitute (EPRI), "Guidelines fer implementing Substation
Automation Using IEC 61850, the lntemational Power System lnformation Modeling
Standard", EPRI - California -USA, 2004
[3] John D. McDonald," Electric Power Substations Enginnering", Florida -USA , 2003.
[4] Douglas Proudfoot, "UCA and 61850 fer Dummies", Siemens Power Transmision and
Distribution , USA , 2002.
[5] Cobus Strauss , " Electrical Network automation and Communication Systems" ,
London , England , 2003.
[6] FIEE -UNI, "Curso Internacional - Sistemas Scada en Centros de Control de Energia
y Automatizacion de Subestaciones Electricas" , Lima , Peru , 2001.
[7] IEE1613 Standard Environmental and Testing Requirements fer Communication�
Networking Devices in Electric Power Substations , USA , 2002.
[8] IEEE , Recommended Practice fer Master/Remete Supervisory Control and Data
Adquisition (SCADA) Communications, USA , 1993.
[9] Ruggedcom , IEC 61850 Seminar: Ruggedcom The Communication Backbone fer IEC
6t850, Toronto , Canada , 2005.
[10] ABB, IEC 61850 el Nuevo Estandard en Automatizacion de Subestaciones, Santiago
de Chile , 2005.