IEC 63380-1:2025
(Main)Standard interface for connecting charging stations to local energy management systems - Part 1: General requirements, use cases and abstract messages
Standard interface for connecting charging stations to local energy management systems - Part 1: General requirements, use cases and abstract messages
IEC 63380-1:2025 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 specifies use cases, the sequences of information exchange and generic data models.
Interface normalisée pour la connexion des bornes de charge aux systèmes locaux de gestion de l’énergie – Partie 1 : Exigences générales, cas d’utilisation et messages abstraits
IEC 63380-1:2025 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 spécifie les cas d’utilisation, les séquences d’échange d’informations et les modèles de données génériques.
General Information
- Status
- Published
- Publication Date
- 16-Apr-2025
- Technical Committee
- TC 69 - Electrical power/energy transfer systems for electrically propelled road vehicles and industrial trucks
- Drafting Committee
- PT 63380 - TC 69/PT 63380
- Current Stage
- PPUB - Publication issued
- Start Date
- 17-Apr-2025
- Completion Date
- 09-May-2025
Overview
IEC 63380-1:2025 is an international standard published by the International Electrotechnical Commission (IEC) that establishes a secure and standardized interface for connecting electric vehicle (EV) charging stations to local energy management systems (EMS). This first part of the standard focused on general requirements, use cases, and abstract messaging aims to harmonize communication between charging station controllers and EMS via a resource manager. It defines the sequences of information exchange and generic data models necessary for effective, interoperable, and secure EV charging management.
By addressing scenarios related to charging coordination, energy consumption monitoring, and power optimization, IEC 63380-1:2025 facilitates the integration of EV charging infrastructure into local energy grids, promoting efficient energy use and grid stability.
Key Topics
General Requirements
IEC 63380-1:2025 outlines baseline requirements for secure and reliable communication between charging stations and EMS to enable interoperability.Use Cases and User Stories
The standard details practical scenarios such as coordinated EV charging, commissioning and configuration of charging stations, electricity measurement, and charging session summaries. It includes multiple actors like charging stations, EMS, and electric vehicles to define realistic interaction flows.Abstract Messaging and Data Models
Defines generic messaging sequences to support functions like charging status monitoring, power limitation, and bidirectional charging control. This abstraction allows smooth integration across diverse technologies.Technical Use Cases
Includes detailed descriptions to guide implementation of features like active power consumption limitation, overload protection, EV state of charge monitoring, self-consumption optimization, and dynamic bidirectional charging.Security and Interoperability
Emphasizes secure information exchange critical to protecting data confidentiality, integrity, and system resilience within connected EV and energy grids.
Applications
Smart Charging Infrastructure
IEC 63380-1:2025 supports deployment of smart EV charging systems where charging sessions can be coordinated based on grid conditions and energy availability to minimize peak loads and maximize efficiency.Local Energy Management
Integration with building or facility EMS enables optimized energy use, reducing grid stress and improving sustainability in residential, commercial, and industrial environments.Grid Load Balancing
Facilitates dynamic adjustment of EV charging based on real-time power consumption and grid constraints to avoid overload and ensure consistent power supply.Bidirectional Charging
Enables vehicle-to-grid (V2G) and vehicle-to-home (V2H) functionalities, allowing EV batteries to discharge energy back to the grid or local premises during peak demand.Data-Driven Energy Optimization
Provides frameworks for detailed measurement and monitoring, empowering operators to analyze consumption patterns and implement energy-saving strategies.
Related Standards
IEC 61851 Series - Standards for EV conductive charging systems covering electric vehicle supply equipment and charging modes.
ISO 15118 Series - Communication protocols for vehicle to grid (V2G) integration, complementing IEC 63380-1's focus on local energy management.
IEC 62955 - Standard for advanced metering infrastructure, relating to energy measurement aspects in EV charging.
IEC 61850 - Communication networks and systems in substations, relevant for integrating EMS and grid communication.
IEC 63110 - Protocols for management of electric vehicle charging and discharging infrastructure.
By establishing common frameworks and detailed use case descriptions, IEC 63380-1:2025 plays a critical role in enabling efficient, secure, and scalable EV charging solutions harmonized with local energy management systems. This fosters the broader adoption of electric mobility and the sustainable integration of renewable energy sources within power grids worldwide.
Frequently Asked Questions
IEC 63380-1:2025 is a standard published by the International Electrotechnical Commission (IEC). Its full title is "Standard interface for connecting charging stations to local energy management systems - Part 1: General requirements, use cases and abstract messages". This standard covers: IEC 63380-1:2025 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 specifies use cases, the sequences of information exchange and generic data models.
IEC 63380-1:2025 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 specifies use cases, the sequences of information exchange and generic data models.
IEC 63380-1:2025 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.
You can purchase IEC 63380-1:2025 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 IEC standards.
Standards Content (Sample)
IEC 63380-1 ®
Edition 1.0 2025-04
INTERNATIONAL
STANDARD
NORME
INTERNATIONALE
Standard interface for connecting charging stations to local energy management
systems –
Part 1: General requirements, use cases and abstract messages
Interface normalisée pour la connexion des bornes de charge aux systèmes
locaux de gestion de l’énergie –
Partie 1 : Exigences générales, cas d’utilisation et messages abstraits
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IEC 63380-1 ®
Edition 1.0 2025-04
INTERNATIONAL
STANDARD
NORME
INTERNATIONALE
Standard interface for connecting charging stations to local energy management
systems –
Part 1: General requirements, use cases and abstract messages
Interface normalisée pour la connexion des bornes de charge aux systèmes
locaux de gestion de l’énergie –
Partie 1 : Exigences générales, cas d’utilisation et messages abstraits
INTERNATIONAL
ELECTROTECHNICAL
COMMISSION
COMMISSION
ELECTROTECHNIQUE
INTERNATIONALE
ICS 29.240.99, 43.120 ISBN 978-2-8327-0343-4
– 2 – IEC 63380-1:2025 © IEC 2025
CONTENTS
FOREWORD . 13
INTRODUCTION . 15
1 Scope . 17
2 Normative references . 17
3 Terms, definitions, and abbreviated terms . 17
3.1 Terms and definitions . 17
3.2 Abbreviated terms. 19
4 Scenarios and user stories . 20
4.1 General . 20
4.2 Stakeholders . 21
4.3 User stories . 21
4.4 Use case actors. 23
4.4.1 General. 23
4.4.2 Charging station . 23
4.4.3 Energy management system (EMS) . 23
4.4.4 Electric vehicle (EV) . 24
4.5 Mapping of user stories to use cases . 24
5 Technical use cases . 25
5.1 Overview . 25
5.1.1 General. 25
5.1.2 Wording . 25
5.1.3 Reading the graphics . 26
5.2 Charging station commissioning and configuration . 26
5.2.1 General. 26
5.2.2 Scenario overview . 26
5.2.3 Scenario implementation requirements . 27
5.2.4 Scenario details . 27
5.2.5 Scenarios and use case functions . 28
5.3 Coordinated EV charging . 29
5.3.1 General. 29
5.3.2 Scenario overview . 30
5.3.3 Scenario implementation requirements . 31
5.3.4 Scenario flow. 32
5.3.5 Scenario details . 33
5.3.6 Scenarios and use case functions . 42
5.3.7 Dependencies to other use cases . 42
5.4 EV charging electricity measurement . 43
5.4.1 General. 43
5.4.2 Scenario overview . 43
5.4.3 Scenario implementation requirements . 44
5.4.4 Scenario details . 44
5.4.5 Scenarios and use case functions . 46
5.4.6 Dependencies to other use cases . 46
5.5 EV charging summary . 46
5.5.1 General. 46
5.5.2 Scenario overview . 47
5.5.3 Scenario implementation requirements . 47
5.5.4 Scenario details – Scenario 1 – EMS sends charging session summary
to charging station . 47
5.5.5 Scenarios and use case functions . 48
5.5.6 Dependencies to other use cases . 48
5.6 EV commissioning and configuration . 49
5.6.1 General. 49
5.6.2 Scenario overview . 49
5.6.3 Scenario implementation requirements . 50
5.6.4 Scenario details . 51
5.6.5 Scenarios and use case functions . 56
5.6.6 Dependencies to other use cases . 56
5.7 EV state of charge . 56
5.7.1 General. 56
5.7.2 Scenario overview . 57
5.7.3 Scenario implementation requirements . 57
5.7.4 Scenario details : Scenario 1 – Monitor EV's state of charge . 57
5.7.5 Scenarios and use case functions . 58
5.8 Limitation of active power consumption . 58
5.8.1 General. 58
5.8.2 Detailed background information and rules . 59
5.8.3 State machine . 62
5.8.4 Scenario overview . 64
5.8.5 Scenario implementation requirements . 65
5.8.6 Scenario details . 65
5.8.7 Scenarios and use case functions . 69
5.8.8 Dependencies to other use cases . 69
5.8.9 Further information and rules . 69
5.9 Monitoring of active power consumption . 70
5.9.1 General. 70
5.9.2 Scenario overview . 70
5.9.3 Scenario implementation requirements . 71
5.9.4 Scenario details . 71
5.9.5 Scenarios and use case functions . 74
5.10 Optimization of self-consumption during EV charging . 75
5.10.1 General. 75
5.10.2 Scenario overview . 75
5.10.3 Scenario implementation requirements . 75
5.10.4 Scenario details . 76
5.10.5 Dependencies to other use cases . 78
5.11 Overload protection by EV charging current curtailment . 79
5.11.1 General. 79
5.11.2 Derivation of the time limits for the involved units . 79
5.11.3 Further information. 80
5.11.4 Scenario overview . 80
5.11.5 Scenario implementation requirements . 80
5.11.6 Scenario details . 81
5.11.7 Scenarios and use case functions . 82
5.11.8 Dependencies to other use cases . 83
– 4 – IEC 63380-1:2025 © IEC 2025
5.12 Basic EV charging/discharging . 84
5.12.1 General. 84
5.12.2 Scenario overview . 84
5.12.3 Scenario implementation requirements . 85
5.12.4 Scenario details . 85
5.12.5 Scenarios and use case functions . 88
5.12.6 Dependencies to other use cases – EV commissioning and
configuration . 88
5.13 Dynamic bidirectional EV charging . 89
5.13.1 General. 89
5.13.2 Dynamic mode . 90
5.13.3 Scenario overview . 90
5.13.4 Scenario implementation requirements . 91
5.13.5 Scenarios and use case functions . 91
5.13.6 Scenarios and use case functions . 96
5.13.7 Dependencies to other use cases . 97
5.13.8 Further information and rules . 97
6 Generic use case functions (UCF) . 98
6.1 General . 98
6.2 Concepts . 98
6.3 UCF_AC_Measurement ─ Generic description . 98
6.3.1 General. 98
6.3.2 Measurement . 100
6.3.3 Electrical connection data . 107
6.4 UCF_Characteristics ─ Generic description . 112
6.4.1 General. 112
6.4.2 Characteristics. 113
6.5 UCF_Charging_Power_Limits ─ Generic description . 113
6.5.1 General. 113
6.5.2 Electrical connection parameters . 114
6.5.3 Electrical connection permitted values . 114
6.6 UCF_Consumption_Curve ─ Generic description . 115
6.6.1 General. 115
6.6.2 Consumption curve . 116
6.7 UCF_Device_Configuration ─ Generic description . 120
6.7.1 General. 120
6.7.2 Device configuration – Key value description . 121
6.7.3 Device configuration data . 121
6.7.4 Write device configuration data . 122
6.8 UCF_Device_State ─ Generic description . 123
6.8.1 General. 123
6.8.2 Device state . 124
6.9 UCF_EV_Connected ─ Generic description . 125
6.9.1 General. 125
6.9.2 Information content . 125
6.10 UCF_Heartbeat ─ Generic description . 125
6.10.1 General. 125
6.10.2 Heartbeat . 126
6.11 UCF_Identification ─ Generic description . 126
6.11.1 General. 126
6.11.2 Identification . 126
6.12 UCF_Incentive_Table ─ Generic description . 127
6.12.1 General. 127
6.12.2 Incentive table . 128
6.12.3 Write incentive table . 132
6.13 UCF_Load_Control ─ Generic description . 135
6.13.1 General. 135
6.13.2 Load constraints . 136
6.14 UCF_Manufacturer_Information ─ Generic description . 138
6.14.1 General. 138
6.14.2 Manufacturer data . 138
6.15 UCF_Maximum_Power_Limitation_Curve ─ Generic description . 139
6.15.1 General. 139
6.15.2 Maximum power limitation curve . 140
6.15.3 Update maximum power limitation curve ─ Time series data . 142
6.16 UCF_Measurement ─ Generic description . 142
6.16.1 General. 142
6.16.2 Measurement . 143
6.17 UCF_Power_Limit . 144
6.17.1 Generic description . 144
6.17.2 Additional information . 146
6.18 UCF_Operation_Mode ─ Generic description . 146
6.18.1 General. 146
6.18.2 Current operation mode ─ Operation mode description . 147
6.18.3 Send operation mode ─ Operation mode description . 147
6.19 UCF_Session_Summary ─ Generic description . 147
6.19.1 General. 147
6.19.2 Session summary. 148
6.19.3 Session summary write ─ Charging summary data . 150
6.20 UCF_Setpoint ─ Generic description. 151
6.20.1 General. 151
6.20.2 Setpoint . 152
Bibliography . 154
Figure 1 – Overview of the IEC 63380 series . 20
Figure 2 – Communication scope of the IEC 63380 series . 21
Figure 3 – Sources of information for an EMS. 24
Figure 4 – Charging station commissioning and configuration – High-level use case
functionality overview. 26
Figure 5 – Charging station commissioning and configuration – Scenario overview . 26
Figure 6 – Charging station commissioning and configuration – Scenario 1 overview . 27
Figure 7 – Charging station commissioning and configuration – Scenario 2 overview . 28
Figure 8 – Coordinated EV charging – High-level use case functionality overview . 29
Figure 9 – Charging session example . 30
Figure 10 – Coordinated EV charging – Scenario overview . 31
Figure 11 – Coordinated EV charging – Scenario flow . 32
– 6 – IEC 63380-1:2025 © IEC 2025
Figure 12 – Energy demand example . 33
Figure 13 – Maximum power limitation curve example . 35
Figure 14 – Incentive table example with consideration of the P curve from
max
scenario 2. 37
Figure 15 – Incentive table example (single incentive slot) for different tiers . 38
Figure 16 – Charging plan curve example . 39
Figure 17 – EV Charging electricity measurement – High-level use case functionality
overview . 43
Figure 18 – EV charging electricity measurement – Scenario overview. 44
Figure 19 – EV charging current overview . 44
Figure 20 – EV charging power overview . 45
Figure 21 – EV charged energy overview . 45
Figure 22 – EV charging summary – High-level use case functionality overview . 47
Figure 23 – EV charging summary – Scenario overview . 47
Figure 24 – Charging session summary . 48
Figure 25 – EV commissioning and configuration – High-level use case functionality
overview . 49
Figure 26 – EV commissioning and configuration – Scenario overview . 50
Figure 27 – EV commissioning and configuration – Scenario 1 overview . 51
Figure 28 – EV commissioning and configuration – Scenario 2 overview . 52
Figure 29 – EV commissioning and configuration – Scenario 3 overview . 53
Figure 30 – EV Commissioning and Configuration – Scenario 4 overview . 53
Figure 31 – EV commissioning and configuration – Scenario 5 overview . 54
Figure 32 – EV commissioning and configuration – Scenario 6 overview . 55
Figure 33 – EV commissioning and configuration – Scenario 7 overview . 55
Figure 34 – EV commissioning and configuration – Scenario 8 overview . 56
Figure 35 – EV state of charge – High-level use case functionality overview . 57
Figure 36 – EV state of charge – Scenario overview. 57
Figure 37 – Monitor EV's state of charge. 57
Figure 38 – Limitation of active power consumption – High-level use case functionality
overview . 59
Figure 39 – State machine after connection establishment . 63
Figure 40 – Limitation of active power consumption – Scenario overview . 65
Figure 41 – Monitoring of active power consumption – High-level use case functionality
overview . 70
Figure 42 – Monitoring of active power consumption – Scenario overview . 71
Figure 43 – Optimization of self-consumption during EV charging – High-level use case
functionality overview. 75
Figure 44 – Optimization of self-consumption during EV Charging – Scenario overview . 75
Figure 45 – Optimization of self-consumption during EV charging – Scenario 1
overview . 76
Figure 46 – Overload protection by EV charging current curtailment – High-level use
case functionality overview . 79
Figure 47 – Overload protection by EV charging current curtailment – Scenario
overview . 80
Figure 48 – Overload protection by EV charging current curtailment – Scenario 1
overview . 81
Figure 49 – Example for asymmetric versus symmetric charging curtailment . 81
Figure 50 – Basic EV charging/discharging – High-level use case functionality overview . 84
Figure 51 – Basic EV charging/discharging – Scenario overview . 85
Figure 52 – Basic EV charging/discharging – Scenario 1 overview . 86
Figure 53 – EMS monitors EV's state of charge – Scenario 2 overview . 86
Figure 54 – Basic EV Charging/Discharging – Scenario 3 overview . 87
Figure 55 – Basic EV charging/discharging – Scenario 4 overview . 87
Figure 56 – Basic EV Charging/Discharging – Scenario 5 overview . 88
Figure 57 – Dynamic bidirectional EV charging – High-level use case functionality
overview . 90
Figure 58 – Dynamic bidirectional EV charging – Scenario overview . 91
Figure 59 – Example of energy request dependencies . 94
Figure 60 ─ Messaging sequence for UCF_AC_Measurement . 99
Figure 61 – Messaging sequence for UCF_Characteristics . 112
Figure 62 – Messaging sequence for UCF_Charging_Power_Limits . 114
Figure 63 – Messaging sequence for UCF_Consumption_Curve . 115
Figure 64 – Messaging sequence for UCF_Device_Configuration . 120
Figure 65 – Messaging sequence for UCF_Device_State . 123
Figure 66 – Messaging sequence for UCF_Heartbeat . 125
Figure 67 – Messaging sequence for UCF_Identification. 126
Figure 68 – Messaging sequence for UCF_Incentive_Table . 127
Figure 69 – Messaging sequence for UCF_Load_Control . 135
Figure 70 – Messaging sequence for UCF_ Manufacturer_Information . 138
Figure 71 – Messaging sequence for UCF_ Maximum_Power_Limitation_Curve . 139
Figure 72 – Messaging sequence for UCF_Measurement . 142
Figure 73 – Messaging sequence for UCF_Power_Limit . 144
Figure 74 – Messaging sequence for UCF_Operation_Mode . 146
Figure 75 – Messaging sequence for UCF_Session_Summary . 148
Figure 76 – Messaging sequence for UCF_Setpoint . 151
Table 1 – User stories . 22
Table 2 – Mapping of user stories to use cases . 25
Table 3 – Presence indication description . 26
Table 4 – Charging station commissioning and configuration – Scenario
implementation requirements for actors . 27
Table 5 – Charging station commissioning and configuration – Scenarios and primary
use case functions (UCFs) . 28
Table 6 – Coordinated EV charging – Scenario implementation requirements for actors . 31
Table 7 – Coordinated EV charging – Scenarios and primary use case functions
(UCFs) . 42
Table 8 – EV charging electricity measurement – Scenario implementation
requirements for actors . 44
– 8 – IEC 63380-1:2025 © IEC 2025
Table 9 – EV charging electricity measurement – Scenarios and primary use case
functions (UCFs) . 46
Table 10 – EV charging summary – Scenario implementation requirements for actors . 47
Table 11 – EV charging summary – Scenarios and primary use case functions (UCFs) . 48
Table 12 – EV commissioning and configuration – Scenario implementation
requirements for actors . 51
Table 13 – EV commissioning and configuration – Scenarios and primary use case
functions (UCFs) . 56
Table 14 – EV state of charge – Scenario implementation requirements for actors . 57
Table 15 – EV state of charge – Scenarios and primary use case functions (UCFs) . 58
Table 16 – Charging station power limitation behaviour . 59
Table 17 – Limitation of active power consumption – Scenario implementation
requirements for actors . 65
Table 18 – Scenario 1 – Control active power consumption limit – Data point list . 66
Table 19 – Scenario 2 – Failsafe values – Data point list . 67
Table 20 – Scenario 3 – Heartbeat – Data point list. 68
Table 21 – Scenario 4 – Constraints – Data point list . 68
Table 22 – Limitation of active power consumption – Scenarios and primary use case
functions (UCFs) . 69
Table 23 – Monitoring of active power consumption – Scenario implementation
requirements for actors . 71
Table 24 – Scenario 1 – Monitor power consumption – Data point list . 72
Table 25 – Scenario 2 – Monitor consumed energy – Data point list. 72
Table 26 – Scenario 3 – Monitor current – Data point list . 73
Table 27 – Scenario 4 – Monitor voltage – Data point list. 73
Table 28 – Scenario 5 – Monitor frequency – Data point list . 74
Table 29 – Monitoring of active power consumption – Scenarios and primary use case
functions (UCFs) . 74
Table 30 – Optimization of self-consumption during EV charging – Scenario
implementation requirements for actors . 76
Table 31 – Optimization of self-consumption during EV charging – Scenarios and
primary use case functions (UCFs) . 78
Table 32 – Overload protection by EV charging current curtailment – Scenario
implementation requirements for actors . 81
Table 33 – Overload protection by EV charging current curtailment – Scenarios and
primary use case functions (UCFs) . 83
Table 34 – Basic EV charging/discharging – Scenario implementation requirements for
actors . 85
Table 35 – Basic EV charging/discharging – Scenarios and primary use case functions
(UCFs) . 88
Table 36 – Dynamic bidirectional EV charging – Scenario implementation requirements
for actors . 91
Table 37 – Scenario 1 – Control active power setpoint – Data point list . 92
Table 38 – Scenario 2 – Monitor energy requests – Data point list . 95
Table 39 – Scenario 3 – Monitor constraints – Data point list . 95
Table 40 – Scenario 4 – Configuration parameters – Data point list . 96
Table 41 – Dynamic bidirectional EV charging – Scenarios and primary use case
functions (UCFs) . 96
Table 42 – Information content for measurement description at actor charging station
for power (use case "monitoring of active power consumption") . 100
Table 43 – Information content for measurement description at actor charging station
for power (use case "ev charging electricity measurement") . 100
Table 44 – Information content for measurement constraints at actor charging station
for power (use cases "monitoring of active power consumption" and "EV charging
electricity measurement") . 101
Table 45 – Information content for measurement data at actor charging station for
power (use case "monitoring of active power consumption") . 101
Table 46 – Information content for measurement data at actor charging station for
power (use case "EV charging electricity measurement") . 101
Table 47 – Information content for measurement description at actor charging station
for energy (use case "monitoring of active power consumption") . 102
Table 48 – Information content for measurement description at actor charging station
for energy (use case "EV charging electricity measurement") . 102
Table 49 – Information content for measurement constraints at actor charging station
for energy (use cases "monitoring of active power consumption" and "EV charging
electricity measurement") . 102
Table 50 – Information content for measurement data at actor charging station for
energy (use case "monitoring of active power consumption") . 103
Table 51 – Information content for measurement data at actor charging station for
energy (use case "EV charging electricity measurement") . 103
Table 52 – Information content for measurement description at actor charging station
for current (use cases "monitoring of active power consumption" and "EV charging
electricity measurement") . 104
Table 53 – Information content for measurement constraints at actor charging station
for current (use cases "monitoring of active power consumption" and "EV charging
electricity measurement") . 104
Table 54 – Information content for measurement data at actor
...
La norme IEC 63380-1:2025 constitue un document essentiel pour la connexion des stations de recharge aux systèmes de gestion de l'énergie locaux. En définissant les exigences générales, les cas d'utilisation et les messages abstraits, cette norme offre un cadre robuste pour faciliter l'échange d'informations sécurisé entre ces deux systèmes fondamentaux. L'un des points forts de la norme IEC 63380-1:2025 est sa capacité à préciser des cas d'utilisation concrets, permettant ainsi une compréhension claire des scénarios d'application. Cela aide non seulement les développeurs à implémenter les solutions adéquates, mais aussi les gestionnaires d'énergie à garantir un fonctionnement optimisé des stations de recharge. De plus, la norme traite des séquences d'échange d'information, ce qui est crucial pour assurer que la communication entre les systèmes de gestion de l'énergie locaux et les contrôleurs des stations de recharge soit fluide et efficace. La norme met également en avant des modèles de données génériques qui facilitent l'interopérabilité entre divers systèmes et normes existants. Cette caractéristique est particulièrement pertinente dans le contexte actuel, où la transition vers des solutions d'énergie plus durables et la multiplication des véhicules électriques sont des enjeux majeurs. La capacité à standardiser ces échanges d'informations contribue à la création d'un écosystème plus intégré et harmonieux, propice à l'adoption des technologies liées à la mobilité électrique. En somme, la norme IEC 63380-1:2025 est non seulement pertinente, mais elle est également essentielle pour l'avenir des infrastructures de recharge électrique, en garantissant que les systèmes de gestion de l'énergie locaux et les stations de recharge puissent communiquer de manière sécurisée et efficace.
IEC 63380-1:2025 표준은 지역 에너지 관리 시스템과 전기차 충전소 간의 안전한 정보 교환을 정의하며, 이 표준은 충전소 컨트롤러와의 효과적인 통신을 위해 리소스 관리자(resource manager)를 통해 수행됩니다. 이 문서는 일반 요구사항, 사용 사례, 추상 메시지를 포함하여 지역 에너지 관리 시스템과 충전소 간의 통신 구조를 체계적으로 제시합니다. 이 표준의 강점 중 하나는 명확한 사용 사례의 정의입니다. 이는 실제 환경에서의 구현 시나리오를 통해 각 이해관계자가 요구 사항을 쉽게 이해하고 적용할 수 있도록 합니다. 또한, 정보 교환의 순서와 일반 데이터 모델을 구체적으로 명시하여, 다양한 시스템 간의 상호 운용성을 보장합니다. IEC 63380-1:2025는 전기차 충전 인프라의 지속 가능한 발전을 지원하며, 스마트 그리드와 통합된 환경에서의 응용 가능성을 높여줍니다. 이로 인해, 에너지 효율성을 극대화하고 충전소 운영의 최적화를 도모할 수 있습니다. 또한, 정보 보안을 고려한 설계 원칙은 시스템의 신뢰성을 더욱 강화합니다. 이러한 이유로 IEC 63380-1:2025 표준은 에너지 관리 시스템과 전기차 충전소 간의 효율적이고 안전한 통신을 위한 필수적인 문서로써, 현대 에너지 시장에서의 관련성과 중요성을 갖추고 있습니다.
IEC 63380-1:2025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間の標準化されたインターフェースに関する重要な文書です。この標準は、情報の安全な交換を定義し、エネルギー管理システムと充電ステーションのコントローラー間の通信におけるフレームワークを提供します。 本標準のスコープには、使用ケースの定義、情報交換の順序、および汎用データモデルの詳細が含まれています。これにより、異なるシステム間の相互運用性を促進し、効率的なエネルギー管理を実現するための基盤を提供します。標準化された情報交換により、充電インフラの運用が容易になり、エネルギーの利用効率を高めることが期待されます。 IEC 63380-1:2025の強みは、その包括的な使用ケースにあります。さまざまなシナリオに対する具体的な情報交換の手法が明示されているため、異なるシステムの間でのアプリケーション実装が容易です。また、汎用データモデルは、今後の技術革新や新しいビジネスモデルにも柔軟に対応できる設計がなされており、長期的な視点での適用が可能です。 この標準は、持続可能な交通手段の促進や再生可能エネルギーの統合においても重要な役割を果たします。地域エネルギー管理システムと充電ステーションの接続を標準化することで、エネルギーの最適利用と環境への負荷軽減に寄与するでしょう。そのため、IEC 63380-1:2025は、未来のエネルギー管理の革新にとって欠かせない要素であり、多様な利害関係者にとって価値ある指針を示しています。
The IEC 63380-1:2025 standard provides a comprehensive framework for the interface connecting charging stations to local energy management systems, emphasizing secure information exchange essential for the evolving landscape of electric vehicle (EV) infrastructure. This document delineates the general requirements, use cases, and abstract messages, making it a pivotal resource for stakeholders involved in the deployment and management of charging ecosystems. One of the significant strengths of IEC 63380-1:2025 is its focus on the secure communication protocols between local energy management systems and electric vehicle charging stations. By detailing how these systems communicate through the resource manager, the standard ensures that data integrity and security are not compromised during information exchanges. This aspect is especially relevant as the demand for EV charging points expands and the need for robust, secure connections becomes more critical. The scope of IEC 63380-1:2025 includes well-defined use cases that cater to the diverse operational scenarios encountered in electric vehicle charging contexts. By specifying sequences of information exchange, the document provides practical guidance that can be adopted by developers and manufacturers in the EV sector, facilitating interoperability among various systems and devices. The emphasis on generic data models also allows for flexibility and adaptation to future technological advancements, ensuring that the standard remains relevant as new use cases emerge. Moreover, the standard's detailed approach to information flow enhances the overall efficiency of energy management, enabling optimized charging processes that contribute to grid stability and user experience. This makes IEC 63380-1:2025 an essential point of reference for industry professionals striving to improve energy management practices and operational coordination within charging networks. In conclusion, the IEC 63380-1:2025 standard stands out as a critical contribution to the field of electric mobility, laying down a strong foundation for secure and efficient communication between local energy management systems and charging stations. Its thorough approach to use cases, information exchange sequences, and generic data models ensures its relevance and applicability in the rapidly evolving electric vehicle charging landscape.
Die Norm IEC 63380-1:2025 definiert eine wichtige Grundlage für den sicheren Informationsaustausch zwischen lokalen Energiemanagementsystemen und Lade stationen für Elektrofahrzeuge. Der Fokus liegt auf der standardisierten Schnittstelle, die für die Interaktion zwischen diesen beiden Systemen notwendig ist. Ein herausragendes Merkmal dieser Norm ist der strukturierte Ansatz zur Definition von Anwendungsfällen, der die Sequenzen des Informationsaustauschs und generische Datenmodelle festlegt. Dies gewährleistet nicht nur eine klare Kommunikation zwischen den Lade stationen und den lokalen Energiemanagementsystemen, sondern fördert auch die Interoperabilität in verschiedenen Szenarien. Die Angabe von klaren Anwendungsfällen ermöglicht es Entwicklern und Ingenieuren, die Norm effizient zu implementieren und spezifische Lösungen für die jeweiligen Einsatzgebiete zu erstellen. Ein weiterer Stärke der IEC 63380-1:2025 ist die Sicherheit, die durch die definierte Informationsarchitektur erreicht wird. Da Sicherheitsbedenken bei der Vernetzung von Lade stationen oft im Vordergrund stehen, adressiert diese Norm diese Problematik proaktiv, indem sie sichere Kommunikationsprotokolle und Datenformate bereitstellt. Dies trägt zur Zuverlässigkeit und Robustheit der Systeme bei. Die Relevanz der IEC 63380-1:2025 kann nicht hoch genug eingeschätzt werden, insbesondere in einer Zeit, in der die Elektromobilität rasant an Bedeutung gewinnt. Durch die Standardisierung der Kommunikation zwischen Lade stationen und lokalen Energiemanagementsystemen unterstützt die Norm nicht nur die Integration erneuerbarer Energien, sondern trägt auch zur Effizienzsteigerung in der Nutzung von Ladeinfrastruktur bei. Daher ist diese Norm nicht nur ein technischer Leitfaden, sondern auch ein strategisches Werkzeug für die Entwicklung einer nachhaltigen Energiezukunft. Zusammenfassend bietet die IEC 63380-1:2025 eine umfassende und durchdachte Regulierung, die sowohl die technischen als auch die sicherheitstechnischen Anforderungen für die Verbindung von Lade stationen mit lokalen Energiemanagementsystemen adressiert und somit einen bedeutenden Beitrag zur Weiterentwicklung der Elektromobilität leistet.
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