iTeh Standards logo
EURUSD
Your shopping cart is empty.
CLC

CLC IEC/TS 61851-3-5:2023

(Main)

Electric vehicles conductive charging system - Part 3-5: DC EV supply equipment where protection relies on double or reinforced insulation - Pre-defined communication parameters and general application objects

Electric vehicles conductive charging system - Part 3-5: DC EV supply equipment where protection relies on double or reinforced insulation - Pre-defined communication parameters and general application objects

This part of IEC 61851-3 series (in a first step as Technical Specification for three-year period) together with part 1 of IEC61851-3, applies to communication for the conductive transfer of electric power between the supply network and a light electric road vehicle or a removable RESS or traction-battery of a light electric road vehicle, with a rated supply voltage up to 480 V a.c. or up to 400 V d.c. and a rated ìoutputî voltage up to 480 V a.c. or up to 200 V d.c.. Energy management system for control of power transfer between battery systems and voltage converter units specifies the communication for all devices that may take part in energy management control. Such energy control applications may be implemented in e.g. light electric vehicles, robots, offshore parks, isolated farms, etc. This part of IEC 61851-3 series provides specifications with regard to the pre-defined communication parameters and general application objects.

Konduktive Ladesysteme für Elektrofahrzeuge - Teil 3-5: Gleichstrom-Versorgungseinrichtungen für Elektrofahrzeuge mit Schutzwirkung durch doppelte oder verstärkte Isolierung - Vordefinierte Kommunikationsparameter und allgemeine Anwendungsobjekte

Système de charge conductive pour véhicules électriques - Partie 3-5 : Exigences relatives aux véhicules électriques légers - Paramètres de communication prédéfinis et objets à application générale

Sistemi za napajanje električnih vozil - 3-5. del: Oprema za napajanje električnih vozil z enosmernim tokom, kjer varnost zagotavlja dvojna ali ojačena izolacija - Vnaprej določeni komunikacijski parametri in splošni aplikacijski predmeti (IEC/TS 61851-3-5:2023)

Ta del skupine standardov IEC 61851-3 (v prvem koraku kot tehnične specifikacije za triletno obdobje) skupaj s 1. delom standarda IEC 61851-3 se uporablja za komuniciranje za konduktivni prenos električne energije med električnim omrežjem in lahkim električnim cestnim vozilom ali odstranjenim sistemom za shranjevanje energije z možnostjo ponovnega polnjenja ali pogonsko baterijo lahkega električnega vozila z nazivno izmenično napetostjo napajanja do 480 V ali enosmerno napetostjo do 400 V in nazivno izhodno izmenično napetostjo do 480 V oziroma izhodno enosmerno napetostjo do 200 V.
Sistem za upravljanje z energijo za nadzor prenosa moči med baterijskimi sistemi in pretvorniki napetosti določa komunikacijo med vsemi napravami, ki so lahko vključene v nadzor upravljanja z energijo. Tovrstne aplikacije za kontrolo energije je na primer mogoče izvesti v lahkih električnih vozilih, robotih, vetrnih parkih na morju, izoliranih vetrnih elektrarnah itd.
Ta del skupine standardov IEC 61851-3 podaja specifikacije v zvezi s predhodno določenimi parametri komunikacije in splošnimi aplikacijskimi objekti.

General Information

Status
Published
Publication Date
21-Dec-2023
ICS
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
22-Dec-2023
Completion Date
22-Dec-2023
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
Mandate
M/533 - [C(2015)1330] Standardisation request addressed to CEN, CENELEC and ETSI in support of the implementation of the Directive 2014/94/EU on the deployment of alternative fuels infrastructure
Ref Project
SIST-TS CLC IEC/TS 61851-3-5:2024 - Electric vehicles conductive charging system - Part 3-5: DC EV supply equipment where protection relies on double or reinforced insulation - Pre-defined communication parameters and general application objects (IEC/TS 61851-3-5:2023)
TS CLC IEC/TS 61851-3-5:2024TS CLC IEC/TS 61851-3-5:2024
PreviousNext
Technical specification
TS CLC IEC/TS 61851-3-5:2024
English language
176 pages
sale 10% off
Preview
sale 10% off
Preview
e-Library read for
1 day

Standards Content (Sample)


SLOVENSKI STANDARD
01-marec-2024
Sistemi za napajanje električnih vozil - 3-5. del: Oprema za napajanje električnih
vozil z enosmernim tokom, kjer varnost zagotavlja dvojna ali ojačena izolacija -
Vnaprej določeni komunikacijski parametri in splošni aplikacijski predmeti (IEC/TS
61851-3-5:2023)
Electric vehicles conductive charging system - Part 3-5: DC EV supply equipment where
protection relies on double or reinforced insulation - Pre-defined communication
parameters and general application objects (IEC/TS 61851-3-5:2023)
Konduktive Ladesysteme für Elektrofahrzeuge - Teil 3-5: Gleichstrom-
Versorgungseinrichtungen für Elektrofahrzeuge mit Schutzwirkung durch doppelte oder
verstärkte Isolierung – Vordefinierte Kommunikationsparameter und allgemeine
Anwendungsgegenstände (IEC/TS 61851-3-5:2023)
Système de charge conductive pour véhicules électriques - Partie 3-5 : Exigences
relatives aux véhicules électriques légers - Paramètres de communication prédéfinis et
objets à application générale (IEC/TS 61851-3-5:2023)
Ta slovenski standard je istoveten z: CLC IEC/TS 61851-3-5:2023
ICS:
43.120 Električna cestna vozila Electric road vehicles
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

TECHNICAL SPECIFICATION CLC IEC/TS 61851-3-5

SPÉCIFICATION TECHNIQUE
TECHNISCHE SPEZIFIKATION December 2023
ICS 43.120
English Version
Electric vehicles conductive charging system - Part 3-5: DC EV
supply equipment where protection relies on double or reinforced
insulation - Pre-defined communication parameters and general
application objects
(IEC/TS 61851-3-5:2023)
Système de charge conductive pour véhicules électriques - Konduktive Ladesysteme für Elektrofahrzeuge - Teil 3-5:
Partie 3-5 : Exigences relatives aux véhicules électriques Gleichstrom-Versorgungseinrichtungen für
légers - Paramètres de communication prédéfinis et objets Elektrofahrzeuge mit Schutzwirkung durch doppelte oder
à application générale verstärkte Isolierung - Vordefinierte
(IEC/TS 61851-3-5:2023) Kommunikationsparameter und allgemeine
Anwendungsgegenstände
(IEC/TS 61851-3-5:2023)
This Technical Specification was approved by CENELEC on 2023-12-04.

CENELEC members are required to announce the existence of this TS in the same way as for an EN and to make the TS available promptly
at national level in an appropriate form. It is permissible to keep conflicting national standards in force.

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
© 2023 CENELEC All rights of exploitation in any form and by any means reserved worldwide for CENELEC Members.
Ref. No. CLC IEC/TS 61851-3-5:2023 E

European foreword
This document (CLC IEC/TS 61851-3-5:2023) consists of the text of IEC/TS 61851-3-5:2023,
prepared by IEC/TC 69 "Electrical power/energy transfer systems for electrically propelled road
vehicles and industrial trucks”.
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 Technical Specification IEC/TS 61851-3-5:2023 was approved by
CENELEC as a European Technical Specification without any modification.

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/TS 61851-3-1 2023 Electric vehicles conductive charging system - -
- Part 3-1: DC EV supply equipment where
protection relies on double or reinforced
insulation - General rules and requirements
for stationary equipment
IEC/TS 61851-3-4 2023 Electric vehicles conductive charging system - -
- Part 3-4: DC EV supply equipment where
protection relies on double or reinforced
insulation - General definitions and
requirements for CANopen communication

Industrial communications subsystem based EN 50325-4 2002
on ISO 11898 (CAN) for controller-device
interfaces - Part 4: CANopen
CiA 302-2 2009 CANopen additional application layer - -
functions - Part 2: Network management

IEC TS 61851-3-5 ®
Edition 1.0 2023-07
TECHNICAL
SPECIFICATION
Electric vehicles conductive charging system –

Part 3-5: DC EV supply equipment where protection relies on double or

reinforced insulation – Pre-defined communication parameters and general

application objects
INTERNATIONAL
ELECTROTECHNICAL
COMMISSION
ICS 43.120 ISBN 978-2-8322-5770-8

– 2 – IEC TS 61851-3-5:2023  IEC 2023
CONTENTS
FOREWORD . 12
INTRODUCTION . 14
1 Scope . 15
2 Normative references . 15
3 Terms and definitions . 15
4 Symbols and abbreviated terms . 15
5 Pre-defined communication objects . 16
5.1 General . 16
5.1.1 Overview . 16
5.1.2 Object 1000 : Device type . 16
h
5.1.3 Object 1001 : Error register. 17
h
5.1.4 Object 1003 : Pre-defined error field . 17
h
5.1.5 Object 1005 : COB-ID SYNC . 17
h
5.1.6 Object 1006 : Communication cycle period . 17
h
5.1.7 Object 1007 : Communication window length . 18
h
5.1.8 Object 1016 : Heartbeat consumer time . 18
h
5.1.9 Object 1017 : Heartbeat producer time . 18
h
5.1.10 Object 1018 : Identity . 18
h
5.1.11 Object 1029 : Error behaviour . 18
h
5.2 PDO communication . 19
6 General application objects for CANopen devices . 19
6.1 General . 19
6.2 Application objects produced by CANopen devices with NMT slave
functionality . 20
6.2.1 General . 20
6.2.2 Object 6000 : Supported virtual devices . 20
h
6.2.3 Object 6002 : Status word . 23
h
6.2.4 Object 6003 : Device capability . 25
h
6.2.5 Object 6004 : System date and time (optional) . 27
h
6.2.6 Object 6005 : Device unique part number (optional) . 28
h
6.2.7 Object 6006 : Device electronic production date (optional) . 28
h
6.2.8 Object 6007 : Device installation date (optional) . 29
h
6.2.9 Object 6008 : Device nominal voltage (optional, mandatory for active
h
devices) . 30
6.2.10 Object 6009 : Device alarm status . 32
h
6.2.11 Object 600A : Device alarm capability . 33
h
6.2.12 Object 600B : Device warning status (optional) . 35
h
6.2.13 Object 600C : Device warning capability (optional) . 37
h
6.2.14 Object 600E : Implemented specification versions . 39
h
6.2.15 Object 6020 : Device request dynamic voltage limitation . 41
h
6.2.16 Object 6022 : Device request dynamic current input limitation. 42
h
IEC TS 61851-3-5:2023  IEC 2023 – 3 –
6.2.17 Object 6023 : Device request dynamic current output limitation . 44
h
6.2.18 Object 6024 : Device maximum continuous input current . 46
h
6.2.19 Object 6025 : Device maximum continuous output current . 48
h
6.2.20 Object 6026 : Device maximum voltage . 49
h
6.2.21 Object 6027 : Device minimum voltage . 51
h
6.2.22 Object 6039 : Device actual external voltage (optional) . 52
h
6.2.23 Object 603A : Device peak input current . 54
h
6.2.24 Object 603B : Device peak input current time (optional) . 55
h
6.2.25 Object 603C : Device peak output current (optional) . 57
h
6.2.26 Object 603D : Device peak output current time (optional) . 58
h
6.2.27 Object 603E : Device actual current . 59
h
6.2.28 Object 6040 : Device actual voltage . 61
h
6.2.29 Object 6042 : Device internal temperature (optional) . 62
h
6.2.30 Object 6043 : Device time on (optional) . 64
h
6.2.31 Object 6044 : Device time standby (optional) . 64
h
6.2.32 Object 6045 : Device switch on counter (optional) . 65
h
6.2.33 Object 6060 : CANopen device measurement timing (optional) . 65
h
6.2.34 Object 6064 : Device maximum AUX continuous input current (optional) . 69
h
6.2.35 Object 6065 : Device maximum AUX continuous output current
h
(optional) . 70
6.2.36 Object 6066 : Device maximum AUX voltage (optional) . 72
h
6.2.37 Object 6067 : Device minimum AUX voltage (optional) . 73
h
6.2.38 Object 6070 : Device actual AUX current (optional) . 75
h
6.2.39 Object 6071 : Device actual AUX voltage (optional) . 77
h
6.2.40 Object 6072h: Device available output voltage . 78
6.2.41 Object 6073h: Device available output current . 79
6.2.42 Object 6074h: Device available input current (optional) . 81
6.3 Security . 82
6.3.1 General . 82
6.3.2 Object 6311h: Locking status . 83
6.4 Application objects consumed by CANopen devices with NMT slave
functionality (mandatory) . 84
6.4.1 General . 84
6.4.2 Object 6001 : Control word . 85
h
6.4.3 Object 6046 : Device set maximum voltage . 86
h
6.4.4 Object 6047 : Device set minimum voltage . 88
h
6.4.5 Object 604A : Device set maximum continuous input current . 89
h
6.4.6 Object 604B : Device set maximum continuous output current . 90
h
6.4.7 Object 604C : Device set maximum peak input current . 91
h
6.4.8 Object 604D : Device set maximum peak input current time . 92
h
6.4.9 Object 604E : Device set maximum peak output current. 93
h
6.4.10 Object 604F : Device set maximum peak output current time . 94
h
– 4 – IEC TS 61851-3-5:2023  IEC 2023
6.5 Application objects consumed by CANopen devices with NMT slave
functionality (optional) . 95
6.5.1 General . 95
6.5.2 Object 600D : Error behaviour at process interface (optional) . 95
h
6.5.3 Object 6058 : Device security key (optional) . 96
h
6.5.4 Object 6059 : Devices' user name and address (optional) . 97
h
6.5.5 Object 605A : Device password (optional) . 99
h
6.5.6 Object 6053 : Prefixes and SI units for analogue values (optional) . 100
h
7 Application objects relevant for fleet management (optional) . 103
7.1 General . 103
7.2 Object 63D5h: Travelled distance . 103
7.3 Object 63D6h: Travelled distance current trip. 104
7.4 Object 63D7 : Travelled time . 105
h
7.5 Object 63D8 : Travelled time current trip . 106
h
7.6 Object 63D9 : Transferred watt hours . 107
h
7.7 Object 63DA : Current trip transferred watt hours . 108
h
8 Stationary applications (optional) . 110
8.1 General application objects relevant for stationary applications . 110
8.2 Object 6010 : Ambient temperature . 110
h
8.3 Object 6011 : Phase 1 AC Current . 111
h
8.4 Object 6012 : Phase 2 AC Current . 113
h
8.5 Object 6013 : Phase 3 AC Current . 114
h
8.6 Object 6014 : Phase 1 AC voltage . 115
h
8.7 Object 6015 : Phase 2 AC voltage . 117
h
8.8 Object 6016 : Phase 3 AC voltage . 118
h
8.9 Object 6017 : Line 12 AC voltage . 120
h
8.10 Object 6018 : Line 23 AC voltage . 121
h
8.11 Object 6019 : Line 13 AC voltage . 123
h
8.12 Object 601A : Phase 1 AC reactive power . 124
h
8.13 Object 601B : Phase 2 AC reactive power . 126
h
8.14 Object 601C : Phase 3 AC reactive power . 127
h
8.15 Object 601D : Phase 1 AC apparent power . 129
h
8.16 Object 601E : Phase 2 AC apparent power . 130
h
8.17 Object 601F : Phase 3 AC apparent power . 132
h
8.18 Object 6030 : Phase 1 AC real power . 134
h
8.19 Object 6031 : Phase 2 AC real power . 135
h
8.20 Object 6032 : Phase 3 AC real power . 137
h
8.21 Object 6033 : Total AC reactive power . 138
h
8.22 Object 6034 : Total AC apparent power . 140
h
8.23 Object 6035 : Total AC real power. 141
h
8.24 Object 6036 : Phase1 power factor (cos phi) . 143
h
8.25 Object 6037 : Phase 2 power factor (cos phi) . 144
h
IEC TS 61851-3-5:2023  IEC 2023 – 5 –
8.26 Object 6038 : Phase 3 power factor (cos phi) . 146
h
8.27 Object 6050 : AC Frequency . 147
h
8.28 Object 6051 : Isolation resistance . 149
h
8.29 Object 6052 : Rated power . 150
h
Annex A (informative) Measured values . 152
A.1 General . 152
A.2 Actual voltage . 152
Annex B (normative) Process data object (PDO) communication for EMS . 153
B.1 General . 153
B.2 Specification of messages . 153
B.3 Allocation of PDOs to virtual devices . 153
B.4 Detailed PDO parameters . 159
B.4.1 General . 159
B.4.2 TPDO parameters for message number 1 . 159
B.4.3 TPDO parameters for message number 2 . 162
B.4.4 TPDO parameters for message number 3 . 164
B.4.5 TPDO parameters for message number 4 to 9 . 167
B.4.6 TPDO parameters for message number 10 . 168
B.4.7 TPDO parameters for message number 12 . 170
Bibliography . 173

Figure 1 – Object structure . 16
Figure 2 – Object structure supported virtual devices . 20
Figure 3 – Object structure device status . 23
Figure 4 – Value structure . 25
Figure 5 – Value structure . 32
Figure 6 – Value structure . 33
Figure 7 – Value structure . 35
Figure 8 – Value structure . 37
Figure 9 – Value structure . 39
Figure 10 – Object structure security status . 83
Figure 11 – Value structure . 85
Figure 12 – Object structure for prefixes . 101
Figure A.1 – Voltage measurement at generic active device . 152

Table 1 – Value definition for the bit field additional information . 16
Table 2 – Object description . 17
Table 3 – Entry description . 17
Table 4 – Default value definition object 1005 . 17
h
Table 5 – Value definition . 18
Table 6 – Object description (optional) . 18
Table 7 – Entry description . 19
Table 8 – Value definition for bit fields . 21
Table 9 – Object description . 22

– 6 – IEC TS 61851-3-5:2023  IEC 2023
Table 10 – Entry description . 22
Table 11 – Value definition device status . 23
Table 12 – Object description . 24
Table 13 – Entry description . 24
Table 14 – Value definition . 25
Table 15 – Object description . 26
Table 16 – Entry description . 26
Table 17 – Object description . 27
Table 18 – Entry description . 27
Table 19 – Object description . 28
Table 20 – Entry description . 28
Table 21 – Object description . 28
Table 22 – Entry description . 29
Table 23 – Object description . 29
Table 24 – Entry description . 30
Table 25 – Object description . 30
Table 26 – Entry description . 31
Table 27 – Value definition . 32
Table 28 – Object description . 33
Table 29 – Entry description . 33
Table 30 – Value definition . 34
Table 31 – Object description . 35
Table 32 – Entry description . 35
Table 33 – Value definition . 36
Table 34 – Object description . 37
Table 35 – Entry description . 37
Table 36 – Value definition . 37
Table 37 – Object description . 38
Table 38 – Entry description . 39
Table 39 – Value definition . 39
Table 40 – Object description . 40
Table 41 – Entry description . 40
Table 42 – Value definition . 41
Table 43 – Object description . 41
Table 44 – Entry description . 41
Table 45 – Value definition . 43
Table 46 – Object description . 43
Table 47 – Entry description . 43
Table 48 – Value definition . 45
Table 49 – Object description . 45
Table 50 – Entry description . 45
Table 51 – Object description . 46
Table 52 – Entry description . 47

IEC TS 61851-3-5:2023  IEC 2023 – 7 –
Table 53 – Object description . 48
Table 54 – Entry description . 48
Table 55 – Object description . 49
Table 56 – Entry description . 50
Table 57 – Object description . 51
Table 58 – Entry description . 51
Table 59 – Object description . 53
Table 60 – Entry description . 53
Table 61 – Object description . 54
Table 62 – Entry description . 54
Table 63 – Object description . 56
Table 64 – Entry description . 56
Table 65 – Object description . 57
Table 66 – Entry description . 57
Table 67 – Object description . 58
Table 68 – Entry description . 59
Table 69 – Object description . 60
Table 70 – Entry description . 60
Table 71 – Object description . 61
Table 72 – Entry description . 61
Table 73 – Object description . 63
Table 74 – Entry description . 63
Table 75 – Object description . 64
Table 76 – Entry description . 64
Table 77 – Object description . 64
Table 78 – Entry description . 64
Table 79 – Object description . 65
Table 80 – Entry description . 65
Table 81 – Object description . 66
Table 82 – Entry description . 66
Table 83 – Object description . 69
Table 84 – Entry description . 69
Table 85 – Object description . 70
Table 86 – Entry description . 71
Table 87 – Object description . 72
Table 88 – Entry description . 72
Table 89 – Object description . 74
Table 90 – Entry description . 74
Table 91 – Object description . 75
Table 92 – Entry description . 75
Table 93 – Object description . 77
Table 94 – Entry description . 77
Table 95 – Object description . 78

– 8 – IEC TS 61851-3-5:2023  IEC 2023
Table 96 – Entry description . 78
Table 97 – Object description . 80
Table 98 – Entry description . 80
Table 99 – Object description . 81
Table 100 – Entry description . 81
Table 101 – Value definition security status . 83
Table 102 – Object description. 83
Table 103 – Entry description . 84
Table 104 – Value definition. 85
Table 105 – Object description. 85
Table 106 – Entry description . 86
Table 107 – Object description. 87
Table 108 – Entry description . 87
Table 109 – Object description. 88
Table 110 – Entry description . 88
Table 111 – Object description. 89
Table 112 – Entry description . 89
Table 113 – Object description. 90
Table 114 – Entry description . 90
Table 115 – Object description. 91
Table 116 – Entry description . 91
Table 117 – Object description. 92
Table 118 – Entry description . 92
Table 119 – Object description. 93
Table 120 – Entry description . 93
Table 121 – Object description. 94
Table 122 – Entry description . 94
Table 123 – Value definition. 95
Table 124 – Object description. 95
Table 125 – Entry description . 96
Table 126 – Object description. 97
Table 127 – Entry description . 97
Table 128 – Object description. 98
Table 129 – Entry description . 98
Table 130 – Object description. 99
Table 131 – Entry description . 99
Table 132 – Additional units . 101
Table 133 – Allocation of powerlines to sub-indices . 101
Table 134 – Object description. 101
Table 135 – Entry description . 101
Table 136 – Object description. 103
Table 137 – Entry description . 104
Table 138 – Object description. 105

IEC TS 61851-3-5:2023  IEC 2023 – 9 –
Table 139 – Entry description . 105
Table 140 – Object description. 106
Table 141 – Entry description . 106
Table 142 – Object description. 107
Table 143 – Entry description . 107
Table 144 – Object description. 108
Table 145 – Entry description . 108
Table 146 – Object description. 109
Table 147 – Entry description . 109
Table 148 – Object description.
...

Questions, Comments and Discussion

Ask us and Technical Secretary will try to provide an answer. You can facilitate discussion about the standard in here.

Loading comments...

This May Also Interest You

CLC
EN IEC 62840-2:2025(Main)
Electric vehicle battery swap system - Part 2: Safety requirements
SIST EN IEC 62840-2:2025

IEC 62840-2:2025 provides the safety requirements for a battery swap system, for the purposes of swapping swappable battery system (SBS)/handheld-swappable battery system (HBS) of electric vehicles. The battery swap system is intended to be connected to the supply network. The power supply is up to 1 000 V AC or up to 1 500 V DC in accordance with IEC 60038. This document also applies to battery swap systems supplied from on-site storage systems (e.g. buffer batteries). Aspects covered in this document: • safety requirements of the battery swap system and its systems; • security requirements for communication; • electromagnetic compatibility (EMC); • marking and instructions; • protection against electric shock and other hazards. This document is applicable to battery swap systems for EV equipped with one or more SBS/HBS. This document is not applicable to • aspects related to maintenance and service of the battery swap station (BSS), • trolley buses, rail vehicles and vehicles designed primarily for use off-road, and • maintenance and service of EVs. Requirements for bidirectional energy transfer are under consideration This second edition cancels and replaces the first edition published in 2016. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) expands the scope to encompass both swappable battery systems (SBS) and handheld swappable battery systems (HBS); b) introduces stricter interoperability requirements through detailed system interface specifications and defined state transition protocols; c) enhances data security by defining safety message transmission protocols and integrating telecom network requirements; d) increases electrical safety protection levels for battery swap stations (BSS) with specified capacitor discharge time limits to mitigate electric shock risks; e) introduces enhanced mechanical safety requirements for automated battery handling systems, with technical alignment to ISO 10218-1 and ISO 10218-2; f) strengthens overload and short-circuit protection for BSS through standardized testing methods and overcurrent protection specifications; g) defines upgraded electromagnetic compatibility (EMC) standards to ensure system resilience against external interference, supplemented with EMC-related functional safety measures. This document is to be read in conjunction with IEC 62840-1:2025.

  • Standard
    49 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 63380-3:2025(Main)
Standard interface for connecting charging stations to local energy management systems - Part 3 Communication protocol and cybersecurity specific aspects
SIST EN IEC 63380-3:2025

IEC 63380-3:2025 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 the application of relevant transport protocols; in this case, SPINE (smart premises interoperable neutral-message exchange), SHIP (smart home IP), and ECHONET Lite. Other communication protocols can be defined in future editions

  • Standard
    184 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 63119-1:2025(Main)
Information exchange for electric vehicle charging roaming service - Part 1: General
SIST EN IEC 63119-1:2025

IEC 63119-1:2025 establishes a basis for the other parts of IEC 63119, specifying the terms and definitions, general description of the system model, classification, information exchange and security mechanisms for roaming between EV charging service providers (CSPs), charging station operators (CSOs) and clearing house platforms through roaming endpoints. It provides an overview and describes the general requirements of the EV roaming service system. The IEC 63119 series is applicable to high-level communication involved in information exchange/interaction between different CSPs, as well as between a CSP and a CSO with or without a clearing house platform through the roaming endpoint. The IEC 63119 series does not specify the information exchange, either between the charging station (CS) and the charging station operator (CSO), or between the EV and the CS. This second edition cancels and replaces the first edition published in 2019. This edition includes the following significant technical changes with respect to the previous edition: a) the scope is expanded to include differentiation between home and visited service provider roles and adds an explicit definition of roaming entity; b) adds definitions for "home charging service provider (home-CSP)", "visited charging station operator (visited-CSO)", and "charging detail record (CDR)", and expands related terms such as "service" and "roaming entity"; c) introduces abbreviation variants for "home-CSP" and "visited-CSO" in the terminology, aligning with North American and European conventions; d) updates the communication protocol stack by adopting a newer TLS version (upgraded from 1.2 to 1.3); e) system architecture and communication interfaces include detailed interactions between home-CSP and visited-CSO; f) adds a definition for "service" to cover a broader range of applications such as parking and reservation management; g) adds a distinction between "charging detail record (CDR)" and "service detail record (SDR)" and clarifies their relationship in the terminology; h) enhances the description of user credential transfer methods in communication interfaces with greater diversity; i) enhances the description of the mixed mode in the classification of roaming service models, emphasizing improved user experience through faster response times.

  • Standard
    16 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 63380-2:2025(Main)
Standard interface for connecting charging stations to local energy management systems - Part 2: Specific data model mapping
SIST EN IEC 63380-2:2025

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.

  • Standard
    202 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 62840-1:2025(Main)
Electric vehicle battery swap system - Part 1: General and guidance
SIST EN IEC 62840-1:2025

IEC 62840-1:2025 gives the general overview for battery swap systems, for the purposes of swapping batteries of electric road vehicles when the vehicle powertrain is turned off and when the battery swap system is connected to the supply network at standard supply voltages according to IEC 60038 with a rated voltage up to 1 000 V AC and up to 1 500 V DC. This document is applicable for battery swap systems for EV equipped with one or more – swappable battery systems (SBS), or – handheld-swappable battery systems (HBS). This document provides guidance for interoperability. This document applies to • battery swap systems supplied from on-site storage systems (for example buffer batteries etc), • manual, mechanically assisted and automatic systems, • battery swap systems intended to supply SBS/HBS having communication allowing to identify the battery system characteristics, and • battery swap systems intended to be installed at an altitude of up to 2 000 m. This document is not applicable to • aspects related to maintenance and service of the battery swap station (BSS), • trolley buses, rail vehicles and vehicles designed primarily for use off-road, • maintenance and service of EVs, • safety requirements for mechanical equipment covered by the ISO 10218 series, • locking compartments systems providing AC socket-outlets for the use of manufacturer specific voltage converter units and manufacturer specific battery systems, • electrical devices and components, which are covered by their specific product standards, • any fix-installed equipment of EV, which is covered by ISO, and • EMC requirements for on-board equipment of EV while connected to the BSS. This first edition cancels and replaces the first edition of IEC TS 61280-1 published in 2016. This edition includes the following significant technical changes with respect to IEC TS 61280-1:2016: a) expanded scope to include handheld-swappable battery systems (HBS) and guidance on interoperability; b) added definitions for "handheld-swappable battery system" (HBS) and expanded related terms such as "SBS/HBS coupler," "SBS/HBS charger," etc; c) added classifications based on supply network characteristics, connection method, access and type of BSS; d) added support for HBS, detailing the different compositions and workflows for type A (SBS) and type B (HBS) battery swap stations; e) added requirements for functional interoperability, interface interoperability, data interoperability, operational interoperability, compatibility with legacy systems, and scalability; f) added requirements for communication, protection against electric shock, specific requirements for accessories), cable assembly requirements, BSS constructional requirements, overload and short circuit protection, EMC, emergency switching or disconnect, marking and instructions; g) expanded annex content, adding solutions for manual swapping stations for motorcycles with HBS and updating use cases.

  • Standard
    37 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN 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
SIST EN IEC 63380-1:2025

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.

  • Standard
    157 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 63584:2025(Main)
Open Charge Point Protocol (OCPP)
SIST EN IEC 63584:2025

IEC 63584:2024 The Open Charge Point Protocol (OCPP) provides the communication between a Charging Station and a Charging Station Management System (CSMS) and is designed to accommodate any type of charging technique. It is based on OCPP 2.0.1 and was submitted as a Fast-Track document.

  • Standard
    1535 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 61851-24:2024(Main)
Electric vehicle conductive charging system - Part 24: Digital communication between a DC EV supply equipment and an electric vehicle for control of DC charging
SIST EN IEC 61851-24:2025

IEC 61851-24:2023, together with IEC 61851-23, applies to digital communication between a DC EV supply equipment and an electric road vehicle (EV) for control of conductive DC power transfer, with a rated supply voltage up to 1 000 V AC or up to 1 500 V DC and a rated output voltage up to 1 500 V DC. This document also applies to digital communication between the DC EV charging/discharging station and the EV for system A, as specified in Annex A. The EV charging mode is mode 4, according to IEC 61851-23. Annex A, Annex B, and Annex C give descriptions of digital communications for control of DC charging specific to DC EV charging systems A, B and C as defined in IEC 61851-23. This second edition cancels and replaces the first edition published in 2014. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: - Annex A and Annex B have been updated in line with IEC 61851-23:2023 and relevant standards.

  • Standard
    55 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
CLC IEC/TS 61851-3-6:2023(Main)
Electric vehicles conductive charging system - Part 3-6: DC EV supply equipment where protection relies on double or reinforced insulation - Voltage converter unit communication
SIST-TS CLC IEC/TS 61851-3-6:2024

This part of IEC 61851-3 series as a technical specification together with part 3-1 and with part 1 of IEC61851, applies to communication for the conductive transfer of electric power between the supply network and a light electric road vehicle to a removable RESS or traction-battery of a light EV when connected to the supply network, with a rated supply voltage up to 480 V a.c. or up to 400 V d.c. and a rated ìoutputî voltage up to 480 V a.c. or up to 200 V d.c.. Energy management system for control of power transfer between battery systems and voltage converter units specifies the communication for all devices that may take part in energy management control. Such energy control applications may be implemented in e.g. light electric vehicles, robots, offshore parks, isolated farms, etc. This part of IEC 61851-3 series provides application objects provided by the AC-DC voltage converter unit or DC/DC voltage converter unit

  • Technical specification
    165 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
CLC IEC/TS 61851-3-2:2023(Main)
Electric vehicle conductive charging system - Part 3-2: DC EV supply equipment where protection relies on double or reinforced insulation - Particular requirements for portable and mobile equipment
SIST-TS CLC IEC/TS 61851-3-2:2024

This part of IEC 61851-3 series (in a first step as Technical Specification for three-year period) together with part 1 of IEC61851-3, applies to the d.c. power supply equipment (e.g. VCU) for the conductive transfer of electric power between the supply network and an light electric road vehicle when connected to the supply network , with a rated supply voltage up to 480 V a.c. or up to 400 V d.c. and a rated ìoutputî voltage up to 480 V a.c. or up to 200 V d.c. The supply systems described in the IEC 61851-3 series are primarily intended for the use by EVs of category L hereinafter referred to as light electric vehicles (light EVs). NOTE 1 Light EV includes all electrically propelled two and three wheeled vehicles of Category L1 up to Category L7 according to the definition of ECE-TRANS-WP29-78r2e and all electrically propelled or assisted cycles. The electrical protection of the complete light EV supply system from the connection to the supply network up to the light EV or removed RESS complies with protective separation and with galvanic separation between a.c. input and d.c. output or class III.

  • Technical specification
    38 pages
    English language
    sale 10% off
    e-Library read for
    1 day