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SIST EN 61400-25-2:2016

(Main)

Wind turbines - Part 25-2: Communications for monitoring and control of wind power plants - Information models

Wind turbines - Part 25-2: Communications for monitoring and control of wind power plants - Information models

The focus of the IEC 61400-25 series is on the communications between wind power plant
components such as wind turbines and actors such as SCADA systems. Internal
communication within wind power plant components is outside the scope of the IEC 61400-25
series.
The IEC 61400-25 series is designed for a communication environment supported by a clientserver
model. Three areas are defined, that are modelled separately to ensure the scalability
of implementations:
1) wind power plant information models,
2) information exchange model, and
3) mapping of these two models to a standard communication profile.
The wind power plant information model and the information exchange model, viewed
together, constitute an interface between client and server. In this conjunction, the wind power
plant information model serves as an interpretation frame for accessible wind power plant
data. The wind power plant information model is used by the server to offer the client a
uniform, component-oriented view of the wind power plant data. The information exchange
model reflects the whole active functionality of the server. The IEC 61400-25 series enables
connectivity between a heterogeneous combination of client and servers from different
manufacturers and suppliers.
As depicted in Figure 1, the IEC 61400-25 series defines a server with the following aspects:
– information provided by a wind power plant component, for example “wind turbine rotor
speed” or “total power production of a certain time interval”, is modelled and made
available for access;
– services to exchange values of the modelled information defined in IEC 61400-25-3;
– mapping to a communication profile, providing a protocol stack, to carry the exchanged
values from the modelled information (IEC 61400-25-4).
The IEC 61400-25 series only defines how to model the information, information exchange
and mapping to specific communication protocols. The standard excludes a definition of how
and where to implement the communication interface, the application program interface and
implementation recommendations. However, the objective of the standard is that the
information associated with a single wind power plant component (such as a wind turbine) is
accessible through a corresponding logical device.
IEC 61400-25-2 specifies the information model of devices and functions related to wind
power plant applications. In particular, it specifies the compatible logical node names, and
data names for communication between wind power plant components. This includes the
relationship between logical devices, logical nodes and data. The names defined in the
IEC 61400-25 series are used to build the hierarchical object references applied for
communicating with components in wind power plants.
This part of IEC 61400-25 specifies common attribute types and common data classes related
to wind turbine applications. In particular it specifies common data classes for:
• setpoint value,
• status value,
• alarm,
• command,
• event counting,
• state timing,
• alarm set status.
Devices implementing the information model of this part choose one or more logical nodes as
required by the application.
NOTE 1 The IEC 61400-25 series focuses on the common, non-vendor-specific information. Those information
items that tend to vary greatly between vendor-specific implementations can for example be specified in bilateral
agreements or by user groups.
NOTE 2 This part does not provide tutorial material.

Windenergieanlagen - Teil 25-2: Kommunikation für die Überwachung und Steuerung von Windenergieanlagen - Informationsmodelle

Eolienne - Partie 25-2: Communications pour la surveillance et la commande des centrales éoliennes - Modèles d’information

L'IEC 61400-25-2:2015 spécifie le modèle d'information des dispositifs et des fonctions liés aux applications des centrales éoliennes. Elle spécifie notamment les noms de noeud logique compatible et les noms de données utilisés dans la communication entre les composants des centrales éoliennes, y compris la relation entre les dispositifs logiques, les noeuds logiques et les données. Les noms définis dans la série IEC 61400-25 sont utilisés pour établir les références à un objet hiérarchique s'appliquant dans le cadre de la communication avec les composants des centrales éoliennes. Cette nouvelle édition comporte les changements importants suivants par rapport à l'édition précédente:
- l'harmonisation avec de nouvelles éditions de la série IEC 61850,
- la réduction de l'écart entre les normes et la simplification par un référencement amélioré,
- l'extension des objets de données pour fonctionnement des réseaux intelligents,
- l'extension et l'amélioration de la sémantique pour les objets de données existants, etc.

Sistemi generatorjev vetrne turbine - 25-2. del: Komunikacije za spremljanje in nadzor vetrnih elektrarn - Informacijski modeli

Skupina standardov IEC 61400-25 se osredotoča na komunikacije med komponentami vetrnih elektrarn, kot so vetrne turbine, in elementi, kot so sistemi SCADA. Komunikacije znotraj komponent vetrnih elektrarn niso zajete v skupini standardov IEC 61400-25.
Skupina standardov IEC 61400-25 je zasnovana za komunikacijsko okolje, ki ga podpira model odjemalec-strežnik. Opredeljena so tri področja, ki so oblikovana posebej, da se zagotovi nadgradljivost uporabljenih različic:
1) informacijski modeli vetrnih elektrarn,
2) model za izmenjavo informacij,
3) preslikava teh dveh modelov v standardni komunikacijski profil.
Informacijski model vetrne elektrarne in model za izmenjavo informacij skupaj sestavljata vmesnik med odjemalcem in strežnikom. Informacijski model vetrne elektrarne se uporablja kot okvir za interpretacijo dostopnih podatkov vetrne elektrarne. Strežnik uporablja informacijski model vetrne elektrarne, da odjemalcu ponuja enoten pregled podatkov vetrne elektrarne, ki je osredotočen na komponente elektrarne. Model za izmenjavo informacij predstavlja aktivne funkcije strežnika. Skupina standardov IEC 61400-25 omogoča povezljivost med raznolikimi odjemalci in strežniki različnih proizvajalcev in dobaviteljev.
Kot prikazuje slika 1, skupina standardov IEC 61400-25 opredeljuje strežnik z naslednjimi vidiki:
– informacija, ki jo posreduje komponenta vetrne elektrarne, na primer »hitrost rotorja vetrne turbine« ali »skupna proizvodnja energije v določenem časovnem intervalu«, se modelira in postane dostopna;
– storitve za izmenjavo vrednosti modelirane informacije so opredeljene v standardu IEC 61400-25-3;
– preslikava v komunikacijski profil, kar zagotavlja sklad protokolov za prenos izmenjanih vrednosti iz modelirane informacije (IEC 61400-25-4).
Skupina standardov IEC 61400-25 opredeljuje samo način modeliranja informacij, izmenjavo informacij in preslikavo v določen komunikacijski protokol. Standard ne določa, kako in kje je treba izvesti komunikacijski vmesnik, programski vmesnik in priporočila za izvajanje. Vendar je cilj standarda omogočiti dostop do informacij posamezne komponente vetrne elektrarne (na primer vetrne turbine) prek ustrezne logične naprave.
Standard IEC 61400-25-2 določa informacijski model naprav in funkcij, povezanih z aplikacijami vetrnih elektrarn. Določa zlasti imena združljivih logičnih vozlišč in imena podatkov za komunikacijo med komponentami vetrne elektrarne. Sem spada razmerje med logičnimi napravami, logičnimi vozlišči in podatki. Imena, določena v skupini standardov IEC 61400-25, se uporabljajo za izdelavo hierarhičnih sklicev na predmete, ki se uporabljajo za komunikacijo s komponentami v vetrnih elektrarnah.
Ta del standarda IEC 61400-25 določa običajne vrste atributov in običajne razrede podatkov, povezane z uporabo vetrnih turbin. Določa zlasti običajne razrede podatkov za:
• vrednost nastavitvene točke,
• vrednost stanja,
• alarm,
• ukaz,
• štetje dogodkov,
• časovno načrtovanje stanj,
• stanje nastavitve alarma.
Naprave, v katerih se uporablja informacijski model, opisan v tem delu, izberejo enega ali več logičnih vozlišč, kot zahteva aplikacija.
OPOMBA 1: Skupina standardov IEC 61400-25 se osredotoča na skupne informacije, ki niso vezane na določenega prodajalca. Te elemente informacij, ki se običajno zelo razlikujejo glede na uporabo, značilno za določenega prodajalca, je mogoče na primer določiti v dvostranskih pogodbah ali s strani skupin uporabnikov.
OPOMBA 2: V tem delu izobraževalno gradivo ni na voljo.

General Information

Status
Published
Publication Date
06-Mar-2016
ICS
27.180 - Wind turbine energy systems
Technical Committee
IEHT - Electrotechnics - Hydraulic turbins
Current Stage
6060 - National Implementation/Publication (Adopted Project)
Start Date
26-Nov-2015
Due Date
31-Jan-2016
Completion Date
07-Mar-2016
Mandate
M/490 - Standardisation mandate to the European Standardisation Organisations (ESOs) to support European Smart Grid deployment
Ref Project
EN 61400-25-2:2015 - Wind turbines - Part 25-2: Communications for monitoring and control of wind power plants - Information models

Relations

Replaces
SIST EN 61400-25-2:2007 - Wind turbines -- Part 25-2: Communications for monitoring and control of wind power plants - Information models
Effective Date
22-Oct-2013
Replaces
SIST EN 61400-25-2:2007 - Wind turbines -- Part 25-2: Communications for monitoring and control of wind power plants - Information models
Effective Date
29-Jan-2023
Revised
SIST EN 61400-25-2:2007 - Wind turbines -- Part 25-2: Communications for monitoring and control of wind power plants - Information models
Effective Date
06-May-2014
Replaces
SIST EN 61400-25-2:2007 - Wind turbines -- Part 25-2: Communications for monitoring and control of wind power plants - Information models
Effective Date
07-Jun-2022

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2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.Sistemi generatorjev vetrne turbine - 25-2. del: Komunikacije za spremljanje in nadzor vetrnih elektrarn - Informacijski modeliEolienne - Partie 25-2: Communications pour la surveillance et la commande des centrales éoliennes - Modèles d’informationWind turbines - Part 25-2: Communications for monitoring and control of wind power plants - Information models27.180Sistemi turbin na veter in drugi alternativni viri energijeWind turbine systems and other alternative sources of energyICS:Ta slovenski standard je istoveten z:EN 61400-25-2:2015SIST EN 61400-25-2:2016en01-april-2016SIST EN 61400-25-2:2016SLOVENSKI
STANDARDSIST EN 61400-25-2:20071DGRPHãþD



SIST EN 61400-25-2:2016



EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM
EN 61400-25-2
November 2015 ICS 27.180
Supersedes
EN 61400-25-2:2007
English Version
Wind turbines - Part 25-2: Communications for monitoring and control of wind power plants - Information models (IEC 61400-25-2:2015)
Eoliennes - Partie 25-2: Communications pour la surveillance et la commande des centrales éoliennes - Modèles d'information (IEC 61400-25-2:2015)
Windenergieanlagen - Teil 25-2: Kommunikation für die Überwachung und Steuerung von Windenergieanlagen - Informationsmodelle (IEC 61400-25-2:2015) This European Standard was approved by CENELEC on 2015-08-04. CENELEC members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the CEN-CENELEC Management Centre or to any CENELEC member.
This European Standard exists in three official versions (English, French, German). A version in any other language made by translation under the responsibility of a CENELEC member into its own language and notified to the CEN-CENELEC Management Centre has the same status as the official versions. CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus, the Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, the Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and the United Kingdom. European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique Europäisches Komitee für Elektrotechnische Normung CEN-CENELEC Management Centre: Avenue Marnix 17,
B-1000 Brussels © 2015 CENELEC All rights of exploitation in any form and by any means reserved worldwide for CENELEC Members.
Ref. No. EN 61400-25-2:2015 E SIST EN 61400-25-2:2016



EN 61400-25-2:2015 2
European foreword The text of document 88/539/FDIS, future edition 2 of IEC 61400-25-2, prepared by IEC TC 88 "Wind turbines" was submitted to the IEC-CENELEC parallel vote and approved by CENELEC as EN 61400-25-2:2015. The following dates are fixed:
• latest date by which the document has to be implemented at national level by publication of an identical national standard or by endorsement (dop) 2016-05-20 • latest date by which the national standards conflicting with the document have to be withdrawn (dow) 2018-08-04
This document supersedes EN 61400-25-2:2007. Attention is drawn to the possibility that some of the elements of this document may be the subject of patent rights. CENELEC [and/or CEN] shall not be held responsible for identifying any or all such patent rights. Endorsement notice The text of the International Standard IEC 61400-25-2:2015 was approved by CENELEC as a European Standard without any modification. SIST EN 61400-25-2:2016



EN 61400-25-2:2015 3
Annex ZA (normative)
Normative references to international publications with their corresponding European publications
The following documents, in whole or in part, are normatively referenced in this document and are indispensable for its application. For dated references, only the edition cited applies. For undated references, the latest edition of the referenced document (including any amendments) applies.
NOTE 1 When an International Publication has been modified by common modifications, indicated by (mod), the relevant EN/HD applies.
NOTE 2 Up-to-date information on the latest versions of the European Standards listed in this annex is available here: www.cenelec.eu.
Publication Year Title EN/HD Year IEC 61400-25-1 -
Wind turbines -- Part 25-1: Communications for monitoring and control of wind power plants - Overall description of principles and models EN 61400-25-1 -
IEC 61400-25 series
Wind turbines EN 61400-25 series
IEC 61400-25-3 2015
Wind turbines -- Part 25-3: Communications for monitoring and control of wind power plants - Information exchange models FprEN 61400-25-3 2015
IEC 61400-25-4 -
- -
IEC 61850-5 -
Communication networks and systems for power utility automation -- Part 5: Communication requirements for functions and device models EN 61850-5 -
IEC 61850-7-1 2011
Communication networks and systems for power utility automation -- Part 7-1: Basic communication structure - Principles and models EN 61850-7-1 2011
IEC 61850-7-2 2010
Communication networks and systems for power utility automation -- Part 7-2: Basic information and communication structure - Abstract communication service interface (ACSI) EN 61850-7-2 2010
IEC 61850-7-3 2010
Communication networks and systems for power utility automation -- Part 7-3: Basic communication structure - Common data classes EN 61850-7-3 2011
IEC 61850-7-4 2010
Communication networks and systems for power utility automation -- Part 7-4: Basic communication structure - Compatible logical node classes and data object classes EN 61850-7-4 2010
ISO 639 series
Codes for the representation of names of languages - series
ISO 3166 series
Codes for the representation of names of countries and their subdivisions - series
ISO 80000-1 -
Quantities and units -- Part 1: General EN ISO 80000-1 -
IEC/TS 61400-26-1 2011
Wind turbines - Part 26-1: Time-based availability for wind turbine generating systems - -
IEEE 754 -
IEEE Standard for Binary Floating-Point Arithmetic - -
SIST EN 61400-25-2:2016



SIST EN 61400-25-2:2016



IEC 61400-25-2 Edition 2.0 2015-06 INTERNATIONAL STANDARD NORME INTERNATIONALE Wind turbines –
Part 25-2: Communications for monitoring and control of wind power plants – Information models
Eoliennes –
Partie 25-2: Communications pour la surveillance et la commande des centrales éoliennes – Modèles d’information
INTERNATIONAL ELECTROTECHNICAL COMMISSION COMMISSION ELECTROTECHNIQUE INTERNATIONALE
ICS 27.180
ISBN 978-2-8322-2726-8
® Registered trademark of the International Electrotechnical Commission
Marque déposée de la Commission Electrotechnique Internationale ®
Warning! Make sure that you obtained this publication from an authorized distributor.
Attention! Veuillez vous assurer que vous avez obtenu cette publication via un distributeur agréé. SIST EN 61400-25-2:2016 colourinside



– 2 – IEC 61400-25-2:2015 © IEC 2015 CONTENTS FOREWORD . 6 INTRODUCTION . 8 1 Scope . 9 2 Normative references. 10 3 Terms and definitions . 12 4 Abbreviated terms . 12 5 General . 15 5.1 Overview of logical node classes . 15 5.2 Use of logical node classes . 17 5.3 Extensions of the information model . 18 6 Wind power plant logical node classes . 18 6.1 System specific logical nodes . 18 6.1.1 Wind power plant common logical node class . 18 6.1.2 LN: Logical node zero Name: LLN0 . 20 6.1.3 LN: Physical device information Name: LPHD . 20 6.2 Wind power plant specific logical nodes . 21 6.2.1 LN: Wind power plant general information Name: WPPD . 21 6.2.2 LN: Wind turbine general information Name: WTUR . 22 6.2.3 LN: Wind turbine rotor information Name: WROT . 22 6.2.4 LN: Wind turbine transmission information Name: WTRM . 23 6.2.5 LN: Wind turbine generator information Name: WGEN . 24 6.2.6 LN: Wind turbine converter information Name: WCNV . 25 6.2.7 LN: Wind turbine transformer information Name: WTRF . 26 6.2.8 LN: Wind turbine nacelle information Name: WNAC . 27 6.2.9 LN: Wind turbine yawing information Name: WYAW . 28 6.2.10 LN: Wind turbine tower information Name: WTOW . 29 6.2.11 LN: Wind power plant meteorological information Name: WMET . 30 6.2.12 LN: Wind power plant alarm information Name: WALM . 31 6.2.13 LN: Wind turbine availability information
Name: WAVL . 31 6.2.14 LN: Wind power plant active power control Name: WAPC . 32 6.2.15 LN: Wind power plant reactive power control Name: WRPC . 33 6.3 Data name semantic . 34 7 Common data classes . 47 7.1 Basic concepts for common data classes (CDC) . 47 7.1.1 Categories of common data classes . 47 7.1.2 Structure of common data classes . 48 7.2 Type definitions . 50 7.2.1 General . 50 7.2.2 BasicTypes . 50 7.2.3 CommonACSITypes . 50 7.2.4 ConstructedAttributeClasses . 51 7.2.5 Originator . 54 7.3 Wind power plant specific common data classes (CDC). 55 7.3.1 General . 55 7.3.2 Setpoint value (SPV) . 56 7.3.3 Status Value (STV) . 58 SIST EN 61400-25-2:2016



IEC 61400-25-2:2015 © IEC 2015 – 3 –
7.3.4 Alarm (ALM) . 58 7.3.5 Command (CMD) . 60 7.3.6 Event counting (CTE) . 61 7.3.7 State timing (TMS) . 63 7.3.8 Alarm Set Status (AST) . 65 7.4 Common data classes inherited from IEC 61850-7-3 . 65 7.4.1 CDCs from IEC 61850-7-3 (unchanged) . 65 7.4.2 CDCs from IEC 61850-7-3 (specialised) . 66 7.5 Common data class attribute semantics . 68 Annex A (informative)
Information model for statistical data
and historical statistical data . 73 A.1 General . 73 A.2 Model for statistical and historical statistical data . 73 A.3 Logical node extension for statistical data . 76 A.3.1 Data for calculation method for analogue and statistical analogue values . 76 A.3.2 Data name semantics . 76 A.4 Common data class for statistical data . 78 A.4.1 Object reference setting group common data class (ORG) . 78 Annex B (normative)
Value range for units and multiplier . 80 Annex C (normative)
Logical nodes for state log, analogue log and report information . 83 C.1 LN: Wind turbine state log information
Name: WSLG . 83 C.2 LN: Wind turbine analogue log information Name: WALG . 85 C.3 LN: Wind turbine report information Name: WREP . 88 Annex D (informative)
Wind power plant controller . 90 D.1 General . 90 D.2 Active power control functions . 91 D.3 Reactive power control functions . 94 Annex E (informative)
List of mandatory logical nodes and data . 97 E.1 General . 97 Annex F (informative)
Control authority management . 99 F.1 General . 99 F.2 Functional description . 99 F.2.1 Local mode . 99 F.2.2 Local mode at station level . 99 F.3 Logical Node representation . 100 F.3.1 Local mode . 100 F.3.2 Diagram description . 100 F.4 Local mode at station level . 101 F.4.1 General . 101 F.4.2 Diagram description . 101
Figure 1 – Conceptual communication model of the IEC 61400-25 series . 10 Figure 2 – Relationship of logical nodes . 15 Figure 3 – Use of instances of logical nodes . 18 Figure A.1 – Conceptual model of statistical and historical statistical data (1) . 74 Figure A.2 – Conceptual model of statistical and historical statistical data (2) . 75 SIST EN 61400-25-2:2016



– 4 – IEC 61400-25-2:2015 © IEC 2015 Figure D.1 – Conceptual structure of the wind power plant control functions . 90 Figure D.2 – Schematic illustration of the active
power limitation control function . 91 Figure D.3 – Schematic illustration of the gradient power control function . 92 Figure D.4 – Schematic illustration of the delta power control function . 92 Figure D.5 – Schematic illustration of a combined control –
including gradient, delta and active power limitation control . 93 Figure D.6 – Schematic illustration of the apparent power control function . 93 Figure D.7 – Schematic illustration of the reactive power control function . 94 Figure D.8 – Schematic illustration of the power factor control function . 95 Figure D.9 – Schematic illustration of the voltage control function
using reactive power control . 96 Figure F.1 – Local mode . 100 Figure F.2 – Local mode at station level . 101
Table 1 – System specific logical nodes . 15 Table 2 – Wind power plant general logical nodes . 16 Table 3 – Logical nodes for modelling a wind turbine . 16 Table 4 – Logical nodes for modelling a non-turbine device . 17 Table 5 – Wind power plant common logical node class . 19 Table 6 – Logical node zero class . 20 Table 7 – Physical device information class . 21 Table 8 – LN: Wind power plant general information (WPPD) . 21 Table 9 – LN: Wind turbine general information (WTUR) . 22 Table 10 – LN: Wind turbine rotor information (WROT) . 23 Table 11 – LN: Wind turbine transmission information (WTRM) . 24 Table 12 – LN: Wind turbine generator information (WGEN). 25 Table 13 – LN: Wind turbine converter information (WCNV) . 26 Table 14 – LN: Wind turbine transformer information (WTRF) . 27 Table 15 – LN: Wind turbine nacelle information (WNAC) . 28 Table 16 – LN: Wind turbine yawing information (WYAW) . 29 Table 17 – LN: Wind turbine tower information (WTOW) . 29 Table 18 – LN: Wind power plant meteorological information (WMET) . 30 Table 19 – LN: Wind power plant alarm information (WALM) . 31 Table 20 – LN: Wind turbine availability (WAVL) . 32 Table 21 – LN: Wind power plant active power control information (WAPC) . 33 Table 22 – LN: Wind power plant reactive power control information (WRPC) . 34 Table 23 – Data name semantic . 35 Table 24 – General table structure of a common data class (CDC) . 48 Table 25 – Common data class attributes . 49 Table 26 – Conditions for the presence of an attribute . 49 Table 27 – Basic types . 50 Table 28 – AnalogueValue . 51 Table 29 – TimeStamp type . 52 Table 30 – TimeQuality definition . 53 SIST EN 61400-25-2:2016



IEC 61400-25-2:2015 © IEC 2015 – 5 –
Table 31 – TimeAccuracy . 53 Table 32 – Quality . 54 Table 33 – Unit . 54 Table 34 – Originator . 55 Table 35 – Values for orCat . 55 Table 36 – Wind power plant specific common data classes. 56 Table 37 – CDC: Setpoint value (SPV) . 57 Table 38 – CDC: Status Value (STV) . 58 Table 39 – CDC: Alarm (ALM) . 59 Table 40 – CDC: Command (CMD) . 61 Table 41 – CDC: Event counting (CTE) . 62 Table 42 – CDC: State timing (TMS) . 64 Table 43 – CDC: Alarm Set Status (AST) . 65 Table 44 – Specialized common data classes . 66 Table 45 – Wind power plant device name plate
common data class specification WDPL . 67 Table 46 – Common data class attribute semantic . 68 Table A.1 – Description of Data . 77 Table A.2 – Object reference setting group common data class specification. 78 Table B.1 – SI units: base units . 80 Table B.2 – SI units: derived units . 80 Table B.3 – SI units: extended units . 81 Table B.4 – SI units: industry specific units. 81 Table B.5 – Multiplier . 82 Table C.1 – LN: Wind turbine state log information (WSLG) . 84 Table C.2 – LN: Wind turbine analogue log information (WALG) . 86 Table C.3 – LN: Wind turbine report information (WREP) . 89 Table E.1 – Mandatory system specific logical nodes . 97 Table E.2 – Mandatory wind turbine specific logical nodes . 97 Table E.3 – Mandatory wind power plant specific common data classes (CDC) . 97 Table E.4 – Mandatory common data classes inherited from IEC 61850-7-3 . 97 Table E.5 – Mandatory common data classes inherited
from IEC 61850-7-3 and specialised . 98
SIST EN 61400-25-2:2016



– 6 – IEC 61400-25-2:2015 © IEC 2015 INTERNATIONAL ELECTROTECHNICAL COMMISSION ____________
WIND TURBINES –
Part 25-2: Communications for monitoring and
control of wind power plants – Information models
FOREWORD 1) The International Electrotechnical Commission (IEC) is a worldwide organization for standardization comprising all 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. To this end and in addition to other activities, IEC publishes International 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. International, governmental and non-governmental organizations liaising with the IEC also participate in this preparation. IEC collaborates closely with the International 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 international consensus 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 National Committees in that sense. While all reasonable efforts are made to ensure that the technical content of IEC Publications 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 divergence between any IEC Publication and the corresponding national or regional publication shall be clearly indicated in the latter. 5) IEC itself does not provide any attestation of conformity. Independent certification bodies provide conformity assessment services and, in some areas, access to IEC marks of conformity. IEC is not responsible for any services carried out by independent certification bodies. 6) All 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 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 is indispensable for the correct application of this publication. 9) Attention is drawn to the possibility that some 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. International Standard IEC 61400-25-2 has been prepared by IEC technical committee 88: Wind turbines.
The text of this standard is based on the following documents: FDIS Report on voting 88
...

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SIST EN IEC 61400-21-2:2023(Main)
Wind energy generation systems - Part 21-2: Measurement and assessment of electrical characteristics - Wind power plants (IEC 61400-21-2:2023)
EN IEC 61400-21-2:2023

IEC 61400-21-2 - Wind energy generation systems - Measurement and assessment of electrical characteristics - Wind power plants - has the following scope: IEC 61400-21-2 defines and specifies the quantities that shall be determined to characterize the electrical characteristics of grid-connected power plants (PP).
IEC 61400-21-2 defines the measurement and test procedures for quantifying the electrical characteristics as basis for the verification of compliance of PP, including:
- Power quality aspects
- Steady state operation
- Dynamic response (undervoltage and overvoltage fault ride-through)
- Disconnection from grid (Grid protection)
- Control performance
IEC 61400-21-2 defines a uniform functionality test and measurement procedure for the power plant controller (PPC), as a basis for the unit test of the power plant controller.
IEC 61400-21-2 defines the procedures for assessing compliance with electrical connection requirements, including the aggregation methods for power quality aspects such as voltage variations, flicker, harmonics and interharmonics.
IEC 61400-21-2 defines the procedures for measurement and fault recording for the verification of power plant electrical simulation models in relation to undervoltage and overvoltage ride through events.
These measurement procedures are valid for power plants, including the power plant controller and other connected equipment, necessary for the operation of the Power Plant. The measurement procedures are valid for any size of power plant connected to the point of connection (POC) at one connection point.
The procedures for assessing and verifying the compliance with grid connection requirements are valid for power plants in power systems with fixed frequency and a sufficient short-circuit power.
Out of the scope of this standard are:
- Multi park control, i.e. cluster management of several power plants (PP) or several connection points
- Compliance test and performance requirements, including pass or fail criteria
- Specific component test and validation of the PP equipment (switchgear, cables, transformers, etc.), which are covered by other IEC standards
- Wind power plant model validation, as defined in the IEC 61400-27-2
- Load flow calculation methods and load flow study guidelines
- Test and measurement of the communication interface and system of the PP as defined in the IEC 61400-25 series
NOTE
For the purposes of this document, the following terms for system voltage apply, based on IEC 60038
Low voltage (LV) refers to 100 V < Un ≤ 1 kV;
Medium voltage (MV) refers 106 to 1 kV < Un ≤ 35 kV;
High voltage (HV) refers to 35 kV < Un ≤ 230 kV;
Extra high voltage (EHV) refers to Un > 230 kV

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SIST EN IEC 61400-50-1:2023(Main)
Wind energy generation systems - Part 50-1: Wind measurement - Application of meteorological mast, nacelle and spinner mounted instruments (IEC 61400-50-1:2022)
EN IEC 61400-50-1:2022

IEC 61400-50-1:2022 specifies methods and requirements for the application of instruments to measure wind speed (and related parameters, e.g. wind direction, turbulence intensity). Such measurements are required as an input to some of the evaluation and testing procedures for wind energy and wind turbine technology (e.g. resource evaluation and turbine performance testing) described by other standards in the IEC 61400 series. This document is applicable specifically to the use of wind measurement instruments mounted on meteorological masts, turbine nacelles or turbine spinners which measure the wind at the location at which the instruments are mounted. This document excludes remote sensing devices which measure the wind at some location distant from the location at which the instrument is mounted (e.g. vertical profile or forward facing lidars).

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SIST EN IEC 61400-12-2:2023(Main)
Wind energy generation systems - Part 12-2: Power performance of electricity producing wind turbines based on nacelle anemometry (IEC 61400-12-2:2022)
EN IEC 61400-12-2:2022

This part of IEC 61400-12 specifies a procedure for verifying the power performance
characteristics of a single electricity-producing, horizontal axis wind turbine that is not
considered to be a small wind turbine per IEC 61400-2. It is expected that this document be
used when the specific operational or contractual specifications do not comply with the
requirements set out in IEC 61400-12-1. The procedure can be used for power performance
evaluation of specific turbines at specific locations, but equally the methodology can be used
to make generic comparisons between different turbine models or different turbine settings.
The purpose of this document is to provide a uniform methodology of measurement, analysis,
and reporting of power performance characteristics for individual electricity producing wind
turbines utilising nacelle-anemometry methods. This document is intended to be applied only
to horizontal axis wind turbines of sufficient size that the nacelle-mounted anemometer does
not significantly affect the flow through the turbine’s rotor and around the nacelle and hence
does not affect the wind turbine’s performance. The intent of this document is that the methods
presented in this document be utilised when the requirements set out in IEC 61400-12-1 are
not feasible. This will ensure that the results are as consistent, accurate, and reproducible as
possible within the current state of the art for instrumentation and measurement techniques.
This document describes how to characterise a wind turbine’s power performance in terms of a
measured power curve and the estimated AEP. Guidance on uncertainty considerations relating
to the power performance of the sample of turbines tested relative to the power performance of
all turbines in a wind farm is provided. Guidance on the evaluation of the combined uncertainty
for the case where multiple turbines are tested is also provided.

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SIST EN IEC 61400-12:2022(Main)
Wind energy generation systems - Part 12: Power performance measurements of electricity producing wind turbines - Overview (IEC 61400-12:2022)
EN IEC 61400-12:2022

The IEC 61400 series of standards addresses wind energy generation technical requirements up to the point of interconnection with the utility grid system. Part 12 of the IEC 61400 series of standards comprises a sub-set of standards which are to be used in the evaluation and measurement of the power performance characteristics of wind turbines. The power performance characterisation of wind turbines of all types and sizes is covered.
Wind turbine power performance characteristics are determined from a measured power curve and an associated estimated annual energy production (AEP) and its uncertainty. The measured power curve, defined as the relationship between the wind speed and the wind turbine power output, is determined by collecting simultaneous measurements of meteorological variables (including wind speed), as well as wind turbine signals (including power output) at the test site for a period that is long enough to establish a statistically significant database over a range of wind speeds and under varying wind and atmospheric conditions. The AEP is calculated by applying the measured power curve to reference wind speed frequency distributions, assuming 100 % availability.
Part 12-0 provides a general introduction to the available options for power performance measurement and the contributing evaluations which are further detailed in the other parts of the IEC 61400-12 series. Although the -12 series also defines the specifications of the meteorological variables (and in particular wind speed) required for the power performance evaluation, the methods and procedures for measuring or otherwise acquiring the wind speed data are defined in the IEC 61400-50 wind measurement series of standards.
The evaluation of the wind turbine power performance characteristic according to this series of standards requires the measured power curve and derived energy production figures to be supplemented by an assessment of uncertainty sources and their combined effects. The basis of the uncertainty assessment is ISO/IEC Guide 98-3. The wind measurement uncertainty sources shall be identified and quantified from procedures described in the relevant wind measurement standards contained in the IEC 61400-50 series. The wind measurement uncertainties shall be propagated through to and combined with the other sources of uncertainty in the power curve and annual energy production using methods and assumptions described in the IEC 61400-12 series of standards.

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SIST EN IEC 61400-12-1:2022(Main)
Wind energy generation systems - Part 12-1: Power performance measurement of electricity producing wind turbines (IEC 61400-12-1:2022)
EN IEC 61400-12-1:2022

This part of IEC 61400 specifies a procedure for measuring the power performance
characteristics of a single wind turbine and applies to the testing of wind turbines of all types
and sizes connected to the electrical power network. In addition, this document defines a
procedure to be used to determine the power performance characteristics of small wind turbines
(as defined in IEC 61400-2) when connected to either the electric power network or a battery
bank. The procedure can be used for performance evaluation of specific wind turbines at
specific locations, but equally the methodology can be used to make generic comparisons
between different wind turbine models or different wind turbine settings when site-specific
conditions and data filtering influences are taken into account.
Considerations which can be of relevance to the assessment of uncertainty of power
performance tests on multiple turbines are presented in Annex R on an informative basis.
This document defines a measurement methodology that requires the measured power curve
and derived energy production figures to be supplemented by an assessment of uncertainty
sources and their combined effects. Uncertainty sources of wind measurements are assessed
from procedures described in the relevant wind measurement equipment standards while
uncertainty of the power curve and annual energy production are assessed by procedures in
this document.

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SIST EN IEC 61400-12-3:2022(Main)
Wind energy generation systems - Part 12-3: Power performance - Measurement based site calibration (IEC 61400-12-3:2022)
EN IEC 61400-12-3:2022

This part of IEC 61400 specifies a measurement and analysis procedure for deriving the wind
speed correction due to terrain effects and applies to the performance testing of wind turbines
of all types and sizes connected to the electrical power network as described in IEC 61400-12-1.
The procedure applies to the performance evaluation of specific wind turbines at specific
locations.

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SIST EN IEC 61400-12-5:2022(Main)
Wind energy generation systems - Part 12-5: Power performance - Assessment of obstacles and terrain (IEC 61400-12-5:2022)
EN IEC 61400-12-5:2022

This part of IEC 61400 specifies the procedures for assessing the significance of obstacles and
terrain variations on a proposed power performance measurement site and applies to the
performance testing of wind turbines of all types and sizes connected to the electrical power
network as described in other parts of the IEC 61400 series. The procedure applies to the
performance evaluation of specific wind turbines at specific locations.

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SIST EN IEC 61400-50:2022(Main)
Wind energy generation systems - Part 50: Wind measurement - Overview (IEC 61400-50:2022)
EN IEC 61400-50:2022

The IEC 61400 series of standards addresses wind energy generation technical requirements
up to the point of interconnection with the utility grid system. The IEC 61400-50 series of
standards comprises a sub-set of standards which specify the requirements for equipment and
methods to be used in the measurement of the wind.
Wind measurements are required as inputs to various tests and analyses specified in other usecase standards in the IEC 61400 series (e.g. power performance, resource assessment, noise
measurement). Whereas those other standards define use-cases for wind measurements, the
IEC 61400-50 series sets those wind measurement requirements which are independent of the
use-case. Its purpose is to ensure that wind measurements and the evaluation of uncertainties
in those measurements are carried out consistently across the wind industry and that wind
measurements are carried out such that the uncertainties can be quantified and that those
uncertainties are within an acceptable range.
This document provides a general introduction to the options that are available for wind
measurement, which are further detailed in the other parts of the IEC 61400-50 series.

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SIST EN IEC 61400-12-6:2022(Main)
Wind energy generation systems - Part 12-6: Measurement based nacelle transfer function of electricity producing wind turbines (IEC 61400-12-6:2022)
EN IEC 61400-12-6:2022

This part of IEC 61400-12 specifies a procedure for measuring the nacelle transfer function of
a single electricity-producing, horizontal axis wind turbine, which is not considered to be a small
wind turbine in accordance with IEC 61400-2. It is expected that this document be used when
a valid nacelle transfer function is needed to execute a power performance measurement
according to IEC 61400-12-2.
A wind speed measured on the nacelle or hub of a wind turbine is affected by the turbine rotor
(i.e. speeded up or slowed down wind speed). In IEC 61400-12-1, an anemometer is located on
a meteorological tower that is located between two and four rotor diameters upwind of the test
turbine. This location allows direct measurement of the "free" wind with minimum interference
from the test turbine's rotor. In the procedure of this document, the anemometer is located on
or near the test turbine's nacelle. In this location, the anemometer is measuring a wind speed
that is strongly affected by the test turbine's rotor and the nacelle. The procedure in this
document includes methods for determining and applying appropriate corrections for this
interference. However, note that these corrections inherently increase the measurement
uncertainty compared to a properly configured test conducted in accordance with
IEC 61400-12-1.
This document specifies how to characterise a wind turbine's nacelle transfer function. The
nacelle transfer function is determined by collecting simultaneous measurements of
nacelle-measured wind speed and free stream wind speed (as measured on a meteorological
mast) for a period that is long enough to establish a statistically significant database over a
range of wind speeds and under varying wind and atmospheric conditions. The procedure also
provides guidance on determination of measurement uncertainty including assessment of
uncertainty sources and recommendations for combining them.

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SIST EN IEC 61400-50-2:2022(Main)
Wind energy generation systems - Part 50-2: Wind measurement - Application of ground-mounted remote sensing technology (IEC 61400-50-2:2022)
EN IEC 61400-50-2:2022

Part 50 of IEC 61400 specifies methods and requirements for the application of instruments to measure wind speed (and related parameters, e.g. wind direction and turbulence intensity). Such measurements are required as an input to some of the evaluation and testing procedures for wind energy and wind turbine technology (e.g. resource evaluation and turbine testing) described by other standards in the IEC 61400 series. Part 50-2 is applicable specifically to the use of ground mounted remote sensing wind measurement instruments, i.e devices which measure the wind at some location generally above and distant from the location at which the instrument is mounted (e.g. sodars, vertical profiling lidars). This document specifically excludes other types of RSD such as forward facing or scanning lidars.

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