EN IEC 63380-2:2025 - EV Charging Station to EMS Data Model Mapping

Standard interface for connecting charging stations to local energy management systems - Part 2: Specific data model mapping

IEC 63380-2:2025 defines the secure information exchange between local energy management systems and electric vehicle charging stations. The local energy management systems communicate to the charging station controllers via the resource manager. This document maps the generic use case functions defined in IEC 63380-1 to specific data model. This edition of this document defines specifically SPINE Resources and ECHONET Lite Resources mapped from the high-level use case functions defined in IEC 63380-1.

Standardschnittstelle für das Verbinden von Ladestationen an lokale Energiemanagementsysteme - Teil 2: Spezifische Datenmodellzuordnung

Interface normale pour la connexion de bornes de charge aux systèmes locaux de gestion de l’énergie - Partie 2: Mise en correspondance avec des modèles de données spécifiques

L'IEC 63380-2:2025 définit l’échange sécurisé d’informations entre les systèmes locaux de gestion de l’énergie et les bornes de charge pour véhicules électriques. Les systèmes locaux de gestion de l’énergie communiquent avec les contrôleurs de charge par l’intermédiaire du gestionnaire des ressources. Le présent document met en correspondance les fonctions de cas d’utilisation générique définies dans l’IEC 63380-1 avec un modèle de données spécifique. La présente édition du présent document définit spécifiquement les ressources SPINE et ECHONET Lite mises en correspondance à partir des fonctions de cas d’utilisation définies dans l’IEC 63380-1.

Standardni vmesnik za povezovanje polnilnih postaj z lokalnimi sistemi za upravljanje energije - 2. del: Mapiranje posebnih podatkovnih modelov (IEC 63380-2:2025)

Ta del standarda IEC 63380 opredeljuje varno izmenjavo informacij med lokalnimi sistemi za upravljanje energije in polnilnimi postajami za električna vozila. Lokalni sistemi za upravljanje energije komunicirajo s krmilniki polnilnih postaj prek upravljalnika virov.
Ta dokument preslika splošne funkcije primerov uporabe, opredeljene v standardu IEC 63380-1, v določen podatkovni model. Ta izdaja tega dokumenta posebej opredeljuje vire SPINE in vire ECHONET Lite, preslikane iz funkcij primerov uporabe na visoki ravni, opredeljenih v standardu IEC 63380-1.

General Information

Status

Published

Publication Date

11-Sep-2025

ICS

29.240.99 - Other equipment related to power transmission and distribution networks

43.120 - Electric road vehicles

Technical Committee

CLC/TC 69X - Electrical systems for electric road vehicles

Drafting Committee

IEC/TC 69 - IEC_TC_69

Current Stage

6060 - Document made available - Publishing

Start Date

12-Sep-2025

Due Date

31-Jan-2024

Completion Date

12-Sep-2025

Directive

2014/94/EU - Directive 2014/94/EU of The European Parliament and of The Council of 22 October 2014 on the deployment of alternative fuels infrastructure

2023/1804 - Regulation (EU) 2023/1804 of the European Parliament and of the Council of 13 September 2023 on the deployment of alternative fuels infrastructure, and repealing Directive 2014/94/EU

2023/1804-1 - Regulation (EU) 2023/1804 of the European Parliament and of the Council of 13 September 2023 on the deployment of alternative fuels infrastructure, and repealing Directive 2014/94/EU

2023/1804-2 - Regulation (EU) 2023/1804 of the European Parliament and of the Council of 13 September 2023 on the deployment of alternative fuels infrastructure, and repealing Directive 2014/94/EU

Mandate

M/581 - Standardisation Request as regards communication exchange, electricity, and hydrogen supply for road, maritime transport and inland navigation in support of Directive 2014/94/EU and its planned revision under the ‘Fit for 55’package

Ref Project

SIST EN IEC 63380-2:2025 - Standard interface for connecting charging stations to local energy management systems - Part 2: Specific data model mapping (IEC 63380-2:2025)

Overview

EN IEC 63380-2:2025 (IEC 63380-2:2025) defines the specific data model mapping for a standard interface connecting electric vehicle (EV) charging stations to local energy management systems (EMS). Building on the functional use cases in IEC 63380-1, this part maps high‑level use case functions to concrete resources in SPINE and ECHONET Lite data models. Communication between EMS and charging‑station controllers is handled via a resource manager, enabling secure information exchange and interoperable local control of charging infrastructure.

Key technical topics and requirements

Data model mapping: Translation of IEC 63380-1 generic use case functions (UCFs) to specific SPINE and ECHONET Lite resources.
Resource manager architecture: EMS communicates to charging station controllers via a resource manager; resource discovery, binding and subscription sequences are specified.
Core use case functions covered (examples from the standard):
- UCF_Measurement / UCF_AC_Measurement
- UCF_Device_Configuration / UCF_Device_State
- UCF_Charging_Power_Limits / UCF_Power_Limit
- UCF_Load_Control / UCF_Setpoint
- UCF_Identification, UCF_Heartbeat, UCF_Incentive_Table, UCF_Session_Summary, UCF_Manufacturer_Information
Messaging and sequence diagrams: Detailed diagrams show discovery, read/write, subscription and notification flows for mapped resources.
Normative references and interoperability: Integrates with IEC 63380-1 (use cases) and IEC 63380-3 (communication protocol and cybersecurity aspects); references ISO 15118 series as relevant.
Security considerations: Secure exchange is a primary objective; protocol- and cybersecurity‑specific aspects are addressed in IEC 63380-3.

Practical applications and who uses it

This standard is intended for stakeholders implementing local smart‑charging and distributed energy management:

EV charging station manufacturers - implement device-side resource models (SPINE / ECHONET Lite).
Local EMS and building energy management vendors - integrate standardized resource mappings to control charging loads.
System integrators and software developers - implement discovery, binding, subscription and message flows defined by the standard.
Utilities, microgrid operators and fleet managers - enable local load control, demand response and meter telemetry interoperability.
Test labs, certification bodies and procurement teams - validate compliance and interoperability for smart charging deployments.

Adopting EN IEC 63380-2:2025 supports interoperable EV charging, streamlined integration of local energy management, and clearer mapping from high‑level use cases to deployable data models (SPINE and ECHONET Lite).

Related standards

IEC 63380-1: General requirements, use cases and abstract messages
IEC 63380-3: Communication protocol and cybersecurity specific aspects
ISO 15118 series (vehicle-to-grid / EV communication)

Standard

EN IEC 63380-2:2025 - BARVE

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202 pages

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Standards Content (Sample)

EN IEC 63380-2:2025 - BARVE

SLOVENSKI STANDARD
01-november-2025
Standardni vmesnik za povezovanje polnilnih postaj z lokalnimi sistemi za
upravljanje energije - 2. del: Mapiranje posebnih podatkovnih modelov (IEC 63380-
2:2025)
Standard interface for connecting charging stations to local energy management
systems - Part 2: Specific data model mapping (IEC 63380-2:2025)
Standardschnittstelle für das Verbinden von Ladestationen an lokale
Energiemanagementsysteme - Teil 2: Spezifische Datenmodellzuordnung (IEC 63380-
2:2025)
Interface normale pour la connexion de bornes de charge aux systèmes locaux de
gestion de l’énergie - Partie 2: Mise en correspondance avec des modèles de données
spécifiques (IEC 63380-2:2025)
Ta slovenski standard je istoveten z: EN IEC 63380-2:2025
ICS:
29.240.99 Druga oprema v zvezi z Other equipment related to
omrežji za prenos in power transmission and
distribucijo električne energije distribution networks
43.120 Električna cestna vozila Electric road vehicles
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

EUROPEAN STANDARD EN IEC 63380-2

NORME EUROPÉENNE
EUROPÄISCHE NORM September 2025
ICS 29.240.99; 43.120
English Version
Standard interface for connecting charging stations to local
energy management systems - Part 2: Specific data model
mapping
(IEC 63380-2:2025)
Interface normale pour la connexion de bornes de charge Standardschnittstelle für das Verbinden von Ladestationen
aux systèmes locaux de gestion de l'énergie - Partie 2: an lokale Energiemanagementsysteme - Teil 2: Spezifische
Mise en correspondance avec des modèles de données Datenmodellzuordnung
spécifiques (IEC 63380-2:2025)
(IEC 63380-2:2025)
This European Standard was approved by CENELEC on 2025-08-28. 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, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, the
Netherlands, Norway, Poland, Portugal, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland,
Türkiye and the United Kingdom.

European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique
Europäisches Komitee für Elektrotechnische Normung
CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels
© 2025 CENELEC All rights of exploitation in any form and by any means reserved worldwide for CENELEC Members.
Ref. No. EN IEC 63380-2:2025 E

European foreword
The text of document 69/1057/FDIS, future edition 1 of IEC 63380-2, prepared by TC 69 "Electrical
power/energy transfer systems for electrically propelled road vehicles and industrial trucks" was
submitted to the IEC-CENELEC parallel vote and approved by CENELEC as EN IEC 63380-2:2025.
The following dates are fixed:
• latest date by which the document has to be implemented at national (dop) 2026-09-30
level by publication of an identical national standard or by endorsement
• latest date by which the national standards conflicting with the (dow) 2028-09-30
document have to be withdrawn
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CENELEC shall not be held responsible for identifying any or all such patent rights.
This document has been prepared under a standardization request addressed to CENELEC by the
European Commission. The Standing Committee of the EFTA States subsequently approves these
requests for its Member States.
Any feedback and questions on this document should be directed to the users’ national committee. A
complete listing of these bodies can be found on the CENELEC website.
Endorsement notice
The text of the International Standard IEC 63380-2:2025 was approved by CENELEC as a European
Standard without any modification.
In the official version, for Bibliography, the following notes have to be added for the standard indicated:
IEC 63402-1:2025 NOTE Approved as EN IEC 63402-1:2025 (not modified)
ISO 15118-2 NOTE Approved as EN ISO 15118-2
ISO 15118-20 NOTE Approved as EN ISO 15118-20
Annex ZA
(normative)
Normative references to international publications
with their corresponding European publications
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements 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.
NOTE 1 Where 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.cencenelec.eu.
Publication Year Title EN/HD Year
IEC 63380-1 - Standard interface for connecting charging EN IEC 63380-1 -
stations to local energy management systems -
Part 1: General requirements, use cases and
abstract messages
IEC 63380-3 - Standard interface for connecting charging EN IEC 63380-3 -
stations to local energy management systems -
Part 3 Communication protocol and
cybersecurity specific aspects

IEC 63380-2 ®
Edition 1.0 2025-07
INTERNATIONAL
STANDARD
Standard interface for connecting charging stations to local energy
management systems -
Part 2: Specific data model mapping
ICS 29.240.99; 43.120 ISBN 978-2-8327-0581-0
IEC 63380-2:2025-07(en)
IEC 63380-2:2025 © IEC 2025
CONTENTS
FOREWORD . 12
INTRODUCTION . 14
1 Scope . 16
2 Normative references . 16
3 Terms, definitions and abbreviated terms . 16
3.1 Terms and definitions. 16
3.2 Abbreviated terms . 19
4 Overview . 19
4.1 General . 19
4.2 Reading the graphics . 20
4.2.1 General . 20
4.2.2 Hierarchy diagram . 20
4.2.3 Sequence diagram . 21
4.3 Finding the right information . 22
5 Use case function (UCF) details . 22
5.1 General . 22
5.2 Mapping to SPINE . 22
5.2.1 Concepts . 22
5.2.2 UCF_AC_Measurement . 39
5.2.3 UCF_Characteristics . 68
5.2.4 UCF_Charging_Power_Limits . 77
5.2.5 UCF_Consumption_Curve . 81
5.2.6 UCF_Device_Configuration. 91
5.2.7 UCF_Device_State . 101
5.2.8 UCF_EV_Connected . 106
5.2.9 UCF_Heartbeat . 107
5.2.10 UCF_Identification . 112
5.2.11 UCF_ Incentive_Table . 116
5.2.12 UCF_Load_Control . 129
5.2.13 UCF_Manufacturer_Information . 139
5.2.14 UCF_Maximum_Power_Limitation_Curve . 143
5.2.15 UCF_ Measurement . 152
5.2.16 UCF_ Power_Limit . 158
5.2.17 UCF_Session_Summary . 164
5.2.18 UCF_Setpoint . 173
5.3 Mapping to ECHONET Lite . 182
5.3.1 Concepts . 182
5.3.2 UCF_Device_State . 182
5.3.3 UCF_EV_Connected . 185
5.3.4 UCF_Load_Control . 187
5.3.5 UCF_Measurement . 189
5.3.6 UCF_Operation_Mode . 191
5.3.7 UCF_ Power_Limit . 195
Bibliography . 198

Figure 1 – Overview of resources within IEC 63380-2 . 20
IEC 63380-2:2025 © IEC 2025
Figure 2 – Actor overview example . 21
Figure 3 – Example communication sequence diagram . 21
Figure 4 – Actor overview example . 34
Figure 5 – Pre-scenario communication – Detailed discovery sequence diagram . 37
Figure 6 – Pre-scenario communication – Binding sequence diagram . 38
Figure 7 – Pre-scenario communication – Subscription sequence diagram . 39
Figure 8 – Messaging sequence for UCF_AC_Measurement . 40
Figure 9 – UCF_AC_Measurement: Request Measurement/ Measurement
communication sequence diagram . 41
Figure 10 – UCF_AC_Measurement: Request Electrical Connection Data (Electrical
Connection Data communication sequence diagram) . 59
Figure 11 – Actor "Device " overview . 67
Figure 12 – Actor "EMS" overview . 68
Figure 13 – Messaging sequence for UCF_Characteristics . 68
Figure 14 – UCF_Characteristics: Request Characteristics/Characteristics
communication sequence diagram . 69
Figure 15 – Actor "Device" overview . 76
Figure 16 – Actor "EMS" overview . 76
Figure 17 – Messaging sequence for UCF_Charging_Power_Limits . 77
Figure 18 – UCF_Charging_Power_Limits: Request Power Limits (Power Limits
communication sequence diagram) . 77
Figure 19 – Actor "Device" overview . 80
Figure 20 – Actor "EMS" overview . 81
Figure 21 – Messaging sequence for UCF_Consumption_Curve . 82
Figure 22 – SPINE sequence diagram for Request Consumption Curve and
Consumption Curve . 83
Figure 23 – Actor "Device" overview . 90
Figure 24 – Actor "EMS" overview . 91
Figure 25 – Messaging sequence for UCF_Device_Configuration . 91
Figure 26 – UCF_Device Configuration: Request Device Configuration (Device
Configuration Data communication sequence diagram) . 92
Figure 27 – UCF_Device Configuration: Notify Device Configuration Data
communication sequence diagram . 97
Figure 28 – UCF_Device Configuration: Write Device Configuration communication
sequence diagram . 98
Figure 29 – Actor "Device" overview . 100
Figure 30 – Actor "EMS" overview . 101
Figure 31 – Messaging sequence for UCF_Device_State . 101
Figure 32 – SPINE sequence diagram for Device State . 102
Figure 33 – Actor "Device" overview . 105
Figure 34 – Actor "EMS" overview . 105
Figure 35 – Actor "Device" overview . 106
Figure 36 – Actor "EMS" overview . 107
Figure 37 – Messaging sequence for UCF_Heartbeat . 107
Figure 38 – UCF_Heartbeat communication sequence diagram . 108
Figure 39 – Actor "Device" overview . 111
IEC 63380-2:2025 © IEC 2025
Figure 40 – Actor "EMS" overview . 112
Figure 41 – Messaging sequence for UCF_Identification . 113
Figure 42 – UCF_Identification communication sequence diagram . 113
Figure 43 – Actor "Device" overview . 115
Figure 44 – Actor "EMS" overview . 116
Figure 45 – Messaging sequence for UCF_Incentive_Table . 116
Figure 46 – SPINE sequence diagram for Read Incentive Table and Incentive Table . 117
Figure 47 – SPINE sequence diagram for Write Incentive Table . 123
Figure 48 – Actor "Device" overview . 128
Figure 49 – Actor "EMS" overview . 129
Figure 50 – Messaging sequence for UCF_Load_Control . 129
Figure 51 – SPINE sequence diagram for Request Load Constraints and Load
Constraints . 130
Figure 52 – SPINE sequence diagram for Load Constraints . 136
Figure 53 – SPINE sequence diagram for Load Control . 137
Figure 54 – UCF_Load_Control Actor "Device" overview. 138
Figure 55 – UCF_Load_Control Actor "EMS" overview . 138
Figure 56 – Messaging sequence for UCF_ Manufacturer_Information . 139
Figure 57 – SPINE sequence diagram for Request Manufacturer Data and
Manufacturer Data . 139
Figure 58 – Actor "Device" overview . 142
Figure 59 – Actor "EMS" overview . 143
Figure 60 – Messaging sequence for UCF_ Maximum_Power_Limitation_Curve . 143
Figure 61 – SPINE sequence diagram for Request Max Power Limitation Curve and
Max Power Limitation Curve . 144
Figure 62 – SPINE sequence diagram for Update Max Power Limitation Curve . 149
Figure 63 – Actor "Device" overview . 151
Figure 64 – Actor "EMS" overview . 152
Figure 65 – Messaging sequence for UCF_Measurement. 152
Figure 66 – SPINE sequence diagram for Request Measurement and Measurement . 153
Figure 67 – Actor "Device" overview . 157
Figure 68 – Actor "EMS" overview . 157
Figure 69 – Messaging sequence for UCF_Power_Limit . 158
Figure 70 – UCF_Power_Limit: Read Active Power Limit (Current Active Power Limit
communication sequence diagram) . 158
Figure 71 – UCF_Power_Limit: Notify Current Active Power Limit communication
sequence diagram . 161
Figure 72 – Actor "Device" overview . 163
Figure 73 – Actor "EMS" overview . 163
Figure 74 – Messaging sequence for UCF_Session_Summary . 165
Figure 75 – SPINE sequence diagram for Request Session Summary and Session
Summary . 165
Figure 76 – SPINE sequence diagram for Write Session Summary . 170
Figure 77 – Actor "Device" overview . 173
Figure 78 – Actor "EMS" overview . 173
IEC 63380-2:2025 © IEC 2025
Figure 79 – Messaging sequence for UCF_Setpoint . 174
Figure 80 – SPINE sequence diagram for Request Setpoint and Setpoint . 174
Figure 81 – SPINE sequence diagram for Change Setpoint . 180
Figure 82 – Actor "Device" overview . 181
Figure 83 – Actor "EMS" overview . 181
Figure 84 – ECHONET Lite frame format . 182
Figure 85 – ECHONET Lite sequence diagram for Request Device State and Device
State . 183
Figure 86 – ECHONET Lite sequence diagram for EV Connected . 186
Figure 87 – ECHONET Lite sequence diagram for Load Control . 187
Figure 88 – ECHONET Lite sequence diagram for Request Measurement and
Measurement . 190
Figure 89 – Messaging sequence for UCF_Operation_Mode . 191
Figure 90 – ECHONET Lite sequence diagram for Request Device State and Device
State . 192
Figure 91 – ECHONET Lite sequence diagram for Power Limit . 195

Table 1 – Presence indication description . 27
Table 2 – Example table for cardinality indications on elements and list items . 29
Table 3 – Content of an example table . 33
Table 4 – Content of measurementDescriptionListData read at actor EMS – Use case
"Monitoring of Power Consumption", "EV Charging Electricity Measurement" . 41
Table 5 – Content of measurementConstraintListData read at actor EMS . 42
Table 6 – Content of measurementListData read at actor EMS . 42
Table 7 – Content of measurementDescriptionListData reply or notify at actor device –
Power, non-phase specific – Use case "Monitoring of Power Consumption" . 42
Table 8 – Content of measurementDescriptionListData reply or notify at actor device –
Power, non-phase specific – Use case "EV Charging Electricity Measurement" . 43
Table 9 – Content of measurementDescriptionListData reply or notify at actor device –
Power, phase-specific – Use case "Monitoring of Power Consumption" . 43
Table 10 – Content of measurementConstraintsListData reply or notify at actor device
– Power, non-phase specific – Use case "Monitoring of Power Consumption" . 44
Table 11 – Content of measurementConstraintsListData reply or notify at actor device
– Power, non-phase specific – Use case "EV Charging Electricity Measurement" . 44
Table 12 – Content of measurementConstraintsListData reply or notify at actor device
– Power, phase specific – Use case "Monitoring of Power Consumption" . 45
Table 13 – Content of measurementConstraintsListData reply or notify at actor device
– Power, phase specific – Use case "Monitoring of Power Consumption" . 46
Table 14 – Content of measurementListData reply or notify at actor device – Power,
non-phase specific – Use case "Monitoring of Power Consumption" . 46
Table 15 – Content of measurementListData reply or notify at actor device – Power,
non-phase-specific – Use case "EV Charging Electricity Measurement" . 47
Table 16 – Content of measurementDescriptionListData reply or notify at actor device
– Energy consumed – Use case "Monitoring of Power Consumption" . 47
Table 17 – Content of measurementDescriptionListData reply or notify at actor device
– Energy produced – Use case "Monitoring of Power Consumption" . 48
Table 18 – Content of measurementDescriptionListData reply or notify at actor device
– Use case "EV Charging Electricity Measurement" . 48
IEC 63380-2:2025 © IEC 2025
Table 19 – Content of measurementConstraintsListData reply or notify at actor device
– Energy consumed – Use case "Monitoring of Power Consumption" . 49
Table 20 – Content of measurementConstraintsListData reply or notify at actor device
– Energy produced – Use case "Monitoring of Power Consumption" . 49
Table 21 – Content of measurementConstraintsListData reply or notify at actor device
– Use case "EV Charging Electricity Measurement" . 50
Table 22 – Content of measurementListData reply or notify at actor device – Energy
consumed – Use case "Monitoring of Power Consumption" . 50
Table 23 – Content of measurementListData reply or notify at actor device – Energy
produced – Use case "Monitoring of Power Consumption" . 51
Table 24 – Content of measurementListData reply or notify at actor device – Use case
"EV Charging Electricity Measurement". 51
Table 25 – Content of measurementDescriptionListData reply or notify at actor device
– Current – Use case "Monitoring of Power Consumption" . 52
Table 26 – Content of measurementDescriptionListData reply or notify at actor device
– Current – Use case "EV Charging Electricity Measurement" . 52
Table 27 – Content of measurementConstraintsListData reply or notify at actor device
– Current – Use case "Monitoring of Power Consumption" . 53
Table 28 – Content of measurementConstraintsListData reply or notify at actor device
– Current – Use case "EV Charging Electricity Measurement" . 54
Table 29 – Content of measurementListData reply or notify at actor device – Current –
Use case "Monitoring of Power Consumption" . 55
Table 30 – Content of measurementListData reply or notify at actor device – Current –
Use case "EV Charging Electricity Measurement" . 55
Table 31 – Content of measurementDescriptionListData reply or notify at actor device
– Voltage – Use case "Monitoring of Power Consumption" . 56
Table 32 – Content of measurementConstraintsListData reply or notify at actor device
– Voltage – Use case "Monitoring of Power Consumption" . 56
Table 33 – Content of measurementListData reply or notify at actor device – Voltage –
Use case "Monitoring of Power Consumption" . 57
Table 34 – Content of measurementDescriptionListData reply or notify at actor device
– Frequency – Use case "Monitoring of Power Consumption" . 57
Table 35 – Content of measurementConstraintsListData reply or notify at actor device
– Frequency – Use case "Monitoring of Power Consumption" . 58
Table 36 – Content of measurementListData reply or notify at actor device –
Frequency – Use case "Monitoring of Power Consumption" . 58
Table 37 – Content of electricalConnectionParameterListData read at actor EMS . 59
Table 38 – Content of electricalConnectionDescriptionListData read at actor EMS . 59
Table 39 – Content of electricalConnectionDescriptionListData reply or notify at actor
device – Use case "Monitoring of Power Consumption" . 60
Table 40 – Content of electricalConnectionDescriptionListData reply or notify at actor
device – Use case "EV Charging Electricity Measurement" . 60
Table 41 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Power, non-phase specific . 61
Table 42 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Power, non-phase specific – Use case "EV Charging Electricity
Measurement". 61
Table 43 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Power, phase-specific . 62
IEC 63380-2:2025 © IEC 2025
Table 44 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Energy consumed – Use case "Monitoring of Power
Consumption" . 62
Table 45 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Energy produced – Use case "Monitoring of Power
Consumption" . 63
Table 46 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Use case "EV Charging Electricity Measurement" . 63
Table 47 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Current – Use case "Monitoring of Power Consumption" . 64
Table 48 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Current – Use case "EV Charging Electricity Measurement" . 64
Table 49 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Voltage – Use case "Monitoring of Power Consumption" . 65
Table 50 – Content of electricalConnectionParameterDescriptionListData reply or
notify at actor device – Frequency – Use case "Monitoring of Power Consumption" . 66
Table 51 – Actor naming for "Device" . 66
Table 52 – Actor naming for "EMS" . 67
Table 53 – Content of electricalConnectionCharacteristicListData read at actor EMS –
use cases "Limitation of Active Power Consumption", "Dynamic Bidirectional EV
Charging, scenario 3" . 69
Table 54 – Content of electricalConnectionCharacteristicListData reply or notify at
actor device – Use case "Limitation of Power Consumption" . 70
Table 55 – Content of electricalConnectionCharacteristicListData reply or notify at
actor device – Use case "Dynamic Bidirectional EV Charging" . 73
Table 56 – Actor naming for "Device" . 75
Table 57 – Actor naming for "EMS" . 76
Table 58 – Information content for electricalConnectionParameterDescriptionListData
read at actor EMS . 78
Table 59 – Information content for electricalConnectionPermittedValueSetListData
read at actor EMS . 78
Table 60 – Information content for electricalConnectionParameterDescriptionListData
reply at actor device – Use case "EV Commissioning and Configuration" . 79
Table 61 – Information content for electricalConnectionPermittedValueSetListData
reply at actor device – Use case "EV Commissioning and Configuration" . 79
Table 62 – Information content for timeSeriesDescriptionListData read at actor EMS –
Use case "Coordinated EV Charging", scenario 1 . 83
Table 63 – Information content for timeSeriesDescriptionListData read at actor EMS –
Use case "Coordinated EV Charging", scenario 4 . 83
Table 64 – Information content for timeSeriesDescriptionListData read at actor EMS –
Use case "Dynamic Bidirectional EV Charging", scenario 2 . 84
Table 65 – Information content for timeSeriesListData read at actor EMS (all cases) . 84
Table 66 – Information content for timeSeriesDescriptionListData reply at actor device
– Use case "Coordinated EV Charging" . 84
Table 67 – Information content for timeSeriesDescriptionListData reply at actor device
– Use case "Dynamic Bidirectional EV Charging" . 85
Table 68 – Information content for timeSeriesListData reply at actor device – Use case
"Coordinated EV Charging" . 85
Table 69 – Information content for timeSeriesListData reply at actor device – Use case
"Dynamic Bidirectional EV Charging" . 88
IEC 63380-2:2025 © IEC 2025
Table 70 – Actor naming for "Device" . 90
Table 71 – Content of deviceConfigurationKeyValueDescriptionListData read at actor
EMS . 92
Table 72 – Content of deviceConfigurationKeyValueListData read at actor EMS . 92
Table 73 – Content of deviceConfigurationKeyValueDescriptionListData reply or notify
at actor device – failsafeConsumptionActivePowerLimit – Use case "Limitation of
Power Consumption" . 93
Table 74 – Content of deviceConfigurationKeyValueDescriptionListData reply or notify
at actor device – failsafeDurationMinimum – Use case "Limitation of Power
Consumption" . 93
Table 75 – Content of deviceConfigurationKeyValueDescriptionListData reply or notify
at actor device – Use case "EV Commissioning and Configuration". 94
Table 76 – Content of deviceConfigurationKeyValueDescriptionListData reply or notify
at actor device – Use case "Dynamic Bidirectional EV Charging" . 94
Table 77 – Content of deviceConfigurationKeyValueListData reply or notify at actor
device – Use case "Limitation of Power Consumption" . 95
Table 78 – Content of deviceConfigurationKeyValueListData reply or notify at actor
device – Use case "EV Commissioning and Configuration" . 96
Table 79 – Content of deviceConfigurationKeyValueListData reply or notify at actor
device – Use case "Dynamic Bidirectional EV Charging" . 96
Table 80 – Content of deviceConfigurationKeyValueListData write at actor EMS – Use
case "Limitation of Power Consumption" for Failsafe Duration Minimum . 97
Table 81 – Content of deviceConfigurationKeyValueListData write at actor EMS – Use
case "Limitation of Power Consumption" for Failsafe Duration Minimum . 98
Table 82 – Actor naming for "Device" . 99
Table 83 – Actor naming for "EMS" . 100
Table 84 – Information content for deviceDiagnosisStateData reply at actor EMS – use
cases "Overload Protection by EV Charging Current Curtailment", "Optimization of
Self-Consumption during EV Charging" . 102
Table 85 – Information content for deviceDiagnosisStateData reply at actor device –
Use case "EV Commissioning and Configuration" . 102
Table 86 – Information content for deviceDiagnosisStateData reply at actor device –
Use case "Coordinated EV Charging" . 103
Table 87 – Information content for deviceDiagnosisStateData reply at actor EMS –
Use case "Coordinated EV Charging" . 103
Table 88 – Information content for deviceDiagnosisStateData reply at actor device –
Use case "Charging station Commissioning and Configuration" . 103
Table 89 – Resource Names for UCF_Device_State, Actor "Device" . 104
Table 90 – Content of deviceDiagnosisHeartbeatData read at actor device or EMS . 108
Table 91 – Content of deviceDiagnosisHeartbeatData reply or notify at actor device or
EMS – Use case "Limitation of Power consumption" . 109
Table 92 – Content of deviceDiagnosisHeartbeatData reply or notify at actor EMS –
Use case "Coordinated EV Charging" . 109
Table 93 – Content of deviceDiagnosisHeartbeatData reply or notify at actor EMS –
Use case "Overload Protection by EV Charging Current Curtailment", at actor device –
Use case " Optimization of Self-Consumption During EV Charging" . 110
Table 94 – Actor naming for "Device" . 111
Table 95 – Actor naming for "EMS" . 112
Table 96 – Information content for identificationListData read at actor EMS . 113
IEC 63380-2:2025 © IEC 2025
Table 97 – Information content for identificationListData reply or notify at actor device
– Use case "EV Commissioning and Configuration" . 114
Table 98 – Information content for incentiveTableDescriptionData read at actor EMS . 117
Table 99 – Information content for incentiveTableConstraintsData read at actor EMS . 118
Table 100 – Information content for incentiveTableData read at actor EMS . 118
Table 101 – Information content for incentiveTableDescriptionData reply at actor
device Use case "Coordinated EV Charging" . 118
Table 102 – Information content for incentiveTableConstraintsData reply at actor
device – Use case "Coordinated EV Charging" . 121
Table 103 – Information content for incentiveTableData reply at actor device use case
"Coordinated EV Charging" . 121
Table 104 – Information content for incentiveTableDescriptionData write at actor EMS
–Use case "Coordinated EV Charging" . 124
Table 105 – Information content for incentiveTableData write at actor EMS use case –
"Coordinated EV Charging" . 126
Table 106 – Resource Names for UCF_Incentive_Table actor "Device" . 128
Table 107 – Information content for loadControlLimitDescriptionListData read at actor
EMS . 130
Table 108 – Information content for l
...

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Frequently Asked Questions

What is EN IEC 63380-2:2025?

EN IEC 63380-2:2025 is a standard published by CLC. Its full title is "Standard interface for connecting charging stations to local energy management systems - Part 2: Specific data model mapping". This standard covers: IEC 63380-2:2025 defines the secure information exchange between local energy management systems and electric vehicle charging stations. The local energy management systems communicate to the charging station controllers via the resource manager. This document maps the generic use case functions defined in IEC 63380-1 to specific data model. This edition of this document defines specifically SPINE Resources and ECHONET Lite Resources mapped from the high-level use case functions defined in IEC 63380-1.

What is the scope of EN IEC 63380-2:2025?

What ICS categories does EN IEC 63380-2:2025 belong to?

EN IEC 63380-2:2025 is classified under the following ICS (International Classification for Standards) categories: 29.240.99 - Other equipment related to power transmission and distribution networks; 43.120 - Electric road vehicles. The ICS classification helps identify the subject area and facilitates finding related standards.

Is EN IEC 63380-2:2025 a harmonized European standard?

EN IEC 63380-2:2025 is associated with the following European legislation: EU Directives/Regulations: 2014/94/EU, 2023/1804, 2023/1804-1, 2023/1804-2; Standardization Mandates: M/581. When a standard is cited in the Official Journal of the European Union, products manufactured in conformity with it benefit from a presumption of conformity with the essential requirements of the corresponding EU directive or regulation.

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You can purchase EN IEC 63380-2:2025 directly from iTeh Standards. The document is available in PDF format and is delivered instantly after payment. Add the standard to your cart and complete the secure checkout process. iTeh Standards is an authorized distributor of CLC standards.

SIST EN IEC 63380-2:2025の標準は、電気自動車の充電ステーションとローカルエネルギー管理システム（EMS）との間での安全な情報交換を定義しています。この標準は、IEC 63380-1における汎用的なユースケース機能を特定のデータモデルにマッピングすることで、充電ステーションコントローラーとの通信を実現します。この文書の強みは、SPINEリソースとECHONET Liteリソースに特化している点です。これにより、高度なユースケース機能に基づいた具体的なアプローチが提供され、エネルギー管理の効率性が向上します。特に、ローカルエネルギー管理システムが充電ステーションに対して効果的に情報を送信・受信できるようになることで、充電インフラストラクチャーの最適化が期待されます。さらに、EN IEC 63380-2:2025は、急速に進化する電動車のニーズに対応するため、充電ステーションの相互運用性を強化することに寄与しています。情報の標準化は、異なる機器やシステムがスムーズに連携できることを意味し、全体的なエネルギー管理の質を向上させるでしょう。このように、この標準は持続可能なエネルギー利用を促進するために不可欠な役割を果たします。

Die Norm EN IEC 63380-2:2025 legt einen wichtigen Grundstein für die sichere Informationsübertragung zwischen lokalen Energiemanagementsystemen und Ladestationen für Elektrofahrzeuge. Diese Spezifikation ist insbesondere relevant für die Entwicklung und Implementierung von Schnittstellen, die eine nahtlose Kommunikation zwischen den verschiedenen Systemen ermöglichen. Ein herausragendes Merkmal dieser Norm ist die klare Definition des Datenmodells, das spezifisch auf die Funktionalitäten des generischen Anwendungsfalls gemäß IEC 63380-1 abgestimmt ist. Der Fokus auf die Abbildung von SPINE-Ressourcen und ECHONET Lite-Ressourcen aus den hochgradigen Anwendungsfallfunktionen verdeutlicht die Bemühungen, die Interoperabilität zwischen unterschiedlichen Technologien und Anbietern zu fördern. Die Standardisierung bietet vielseitige Vorteile, unter anderem die Vereinheitlichung der Datenstrukturen, die dadurch zu einer effizienteren Implementierung von Energiemanagementsystemen führt. Diese Norm nimmt eine Schlüsselrolle ein, wenn es darum geht, die Integration von Elektrofahrzeug-Ladestationen in bestehende Energienetze zu optimieren und gleichzeitig die Anforderungen an Sicherheit und Datenschutz zu erfüllen. Durch die umfassende Abdeckung der erforderlichen Funktionen und deren Anwendungsbereiche bietet EN IEC 63380-2:2025 einen klaren Rahmen, der nicht nur den aktuellen Bedürfnissen der Branche Rechnung trägt, sondern auch zukünftige Entwicklungen im Bereich der Elektromobilität und des Energiemanagements antizipiert. Die Norm ist somit sowohl für Hersteller als auch für Betreiber von Ladestationen von erheblichem Interesse und unterstützt die weitere Verbreitung von Elektrofahrzeugen in einer zunehmend elektrifizierten Welt.

The SIST EN IEC 63380-2:2025 standard provides a crucial framework for the secure exchange of information between local energy management systems and electric vehicle (EV) charging stations. Its primary focus on establishing a standardized interface is highly relevant in the context of the growing electric vehicle infrastructure, addressing the need for consistent communication protocols within this rapidly evolving sector. One of the significant strengths of this standard lies in its detailed mapping of generic use case functions from IEC 63380-1 to a specific data model. This structured approach not only enhances interoperability but also facilitates the integration of various systems, promoting the efficient operation of charging stations. By clearly defining SPINE Resources and ECHONET Lite Resources in conjunction with the high-level use case functions, the document assists developers and system integrators in ensuring compatibility among different components within local energy management systems. The scope of the EN IEC 63380-2:2025 standard extends to defining the roles of local energy management systems and charging station controllers, thereby supporting the efficient management of energy resources. With the increased push for sustainable energy solutions and the proliferation of electric vehicles, this standard's emphasis on secure information exchange equips stakeholders with the necessary tools to streamline operations and enhance user experience. The relevance of this standard cannot be overstated, especially as cities and countries move towards an electrified transportation future. By facilitating standardized communication between charging infrastructure and energy management systems, the EN IEC 63380-2:2025 plays a pivotal role in ensuring that electric vehicle owners can access reliable charging solutions while contributing to optimized energy consumption across networks.

La norme SIST EN IEC 63380-2:2025 joue un rôle essentiel dans la définition de l'interface standard pour la connexion des stations de charge aux systèmes de gestion de l'énergie locaux. Son champ d'application se concentre sur l'échange d'informations sécurisé entre les systèmes de gestion de l'énergie locaux et les stations de charge pour véhicules électriques, garantissant ainsi une communication efficace et fiable. L'un des points forts de cette norme est sa capacité à standardiser les fonctions de cas d'utilisation génériques, telles que définies dans la norme IEC 63380-1, en les mappant à un modèle de données spécifique. Cela permet aux fabricants et aux opérateurs de mettre en œuvre des solutions plus cohérentes et interopérables, facilitant l'intégration des stations de charge dans divers systèmes de gestion de l'énergie. Cette édition précise la cartographie des ressources SPINE et des ressources ECHONET Lite, soutenant ainsi le développement d'une infrastructure de recharge plus intelligente et adaptative. De plus, la norme aborde la sécurité des échanges d'informations, un aspect crucial dans le contexte d'une dépendance croissante à l'électromobilité. La pertinence de la norme SIST EN IEC 63380-2:2025 s'étend au-delà de la simple standardisation technique; elle répond également aux exigences d'un marché en évolution rapide, où la nécessité de solutions énergétiques durables et connectées devient de plus en plus pressante. En fournissant un cadre de référence pour la communication entre les infrastructures de recharge et les systèmes de gestion de l'énergie, cette norme contribue à l'avancement de l'électromobilité et à la transition vers des systèmes énergétiques plus intelligents.

표준 EN IEC 63380-2:2025는 전기차 충전소와 지역 에너지 관리 시스템 간의 안전한 정보 교환을 정의합니다. 이 표준은 지역 에너지 관리 시스템이 자원 관리자를 통해 충전소 제어 장치와 통신하는 방식에 대한 명확한 지침을 제공합니다. IEC 63380-2:2025의 주요 강점은 IEC 63380-1에서 정의된 일반 사용 사례 기능을 특정 데이터 모델에 매핑하는 것입니다. 이 문서는 SPINE 리소스와 ECHONET Lite 리소스를 특히 정의하며, 이를 통해 고수준 사용 사례 기능을 구체화합니다. 이렇게 함으로써, 충전소와 에너지 관리 시스템 간의 통신 방법을 간소화하고 통합성을 높이는 데 기여합니다. 또한, 이 표준은 전력망과 전기차 인프라의 상호 작용을 촉진하여 지속 가능하고 효율적인 에너지 관리를 가능하게 합니다. 이는 전기차 충전소의 운영 효율성을 증대시키고, 다양한 지역 에너지 관리 시스템과의 호환성을 보장하는 데 매우 중요한 역할을 합니다. 결론적으로, EN IEC 63380-2:2025는 전기차 충전소와 지역 에너지 관리 시스템 간의 효율적이고 안전한 데이터 교환을 위한 필수적인 표준으로, 현대 에너지 관리 환경에서의 응용 가능성이 높아 주목받고 있습니다.