ISO/TR 9968:2023

TECHNICAL ISO/TR
REPORT 9968
First edition
2023-06
Road vehicles — Functional safety —
Application to generic rechargeable
energy storage systems for new
energy vehicle
Véhicules routiers — Sécurité fonctionnelle — Application des
systèmes génériques rechargeables de stockage d'énergie aux
véhicules utilisant les énergies nouvelles
Reference number
ISO/TR 9968:2023(E)
© ISO 2023

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ISO/TR 9968:2023(E)
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© ISO 2023
All rights reserved. Unless otherwise specified, or required in the context of its implementation, no part of this publication may
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Published in Switzerland
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ISO/TR 9968:2023(E)
Contents Page
Foreword .iv
Introduction .v
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
4 Abbreviated terms . 3
5 Item definition . 4
5.1 Objectives . 4
5.2 General . 4
5.3 OT is part of the item . 5
5.3.1 General . 5
5.3.2 Assumptions . 6
5.3.3 Functionality . . 6
5.3.4 Internal elements and their functionality . 6
5.3.5 Internal interfaces . 7
5.3.6 Other objects . 8
5.3.7 External interfaces . 8
5.4 OT is not part of the item . 9
5.5 Safe intended functionality of the item . 10
6 HARA and safety concepts .10
6.1 Objectives . 10
6.2 General . 11
6.3 Case 1: Malfunctioning behaviour of the E/E systems can cause hazards related to
the OT.12
6.4 Case 2: Failure of OT causes E/E failures .12
6.5 Case 3: Non-E/E-functional hazards and related hazardous conditions are
addressed by E/E protection functions . 13
6.6 Case 4: Safety measures of elements of other technologies addressing functional
safety requirements and safety goals . 14
6.7 Case 5: Combined OT and E/E safety measures implementing a safety requirement .15
7 Verification and validation for RESS . .18
7.1 OT related hazard and hazardous conditions. 18
7.2 Case 1: Malfunctioning behaviour of the E/E systems can cause hazards related to
the OT. 19
7.3 Case 2: Failure of OT causes E/E failures . 19
7.4 Case 3: Non-E/E-functional hazards and related hazardous conditions are
addressed by E/E protection functions . 19
7.5 Case 4: Safety measures of OT addressing functional safety requirements and
safety goals. . 19
7.6 Case 5: Combined OT and E/E safety measures implementing a safety requirement . 19
8 Production, operation, service and decommissioning (POSD) .20
8.1 Objectives . 20
8.2 General . 20
8.3 Planning for production, operation, service and decommissioning . 20
8.4 Production . 20
8.5 Operation . 20
8.6 Service . 21
8.7 Decommissioning . 21
Annex A (informative) HARA and FSC example .22
Bibliography .25
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ISO/TR 9968:2023(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation of the voluntary nature of standards, the meaning of ISO specific terms and
expressions related to conformity assessment, as well as information about ISO's adherence to
the World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT), see
www.iso.org/iso/foreword.html.
This document was prepared by Technical Committee ISO/TC 22, Road vehicles, Subcommittee SC 32,
Electrical and electronic components and general system aspects.
Any feedback or questions on this document should be directed to the user’s national standards body. A
complete listing of these bodies can be found at www.iso.org/members.html.
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ISO/TR 9968:2023(E)
Introduction
The rechargeable energy storage systems (RESS) (e.g. lithium-ion battery systems) used for new energy
vehicles can introduce specific hazards like thermal runaway, toxic chemical release, high voltage
electric shock, etc.
To prevent and mitigate the risk of RESS related hazards, E/E related technology, such as battery
management systems (BMS), are integrated into the RESS. However, based on accident investigations
and statistics, a large proportion of RESS safety-related incidents are caused by faults within the E/E
[15]
systems (e.g. BMS), elements of other technologies (e.g. battery cells) or both . Due to the possibility
of the mechanical and electrochemical characteristics of the battery changing constantly over the
lifecycle [e.g. state of health (SOH), state of health energy (SOHE), direct current resistance (DCR) for
electrochemistry, and mechanical stress, air-dust tightness, resistance to chemicals for mechanical
parts] the correlated safety threshold parameters of the battery can also change accordingly which can
lead to reduced or even incorrect monitoring and control of the BMS.
Effective safety design and management of RESS relies on system capability to adaptively adjust the
logic and control according to the alteration of mechanical and electrochemical related characteristics
of the battery. The ISO 26262 series is focused on the malfunctioning behaviour of E/E systems. An item
(as well as external measures) can include systems or elements of other technologies. Malfunctioning
behaviour can be caused by failures of systems or elements of other technologies. However, the
ISO 26262 series includes limited guidance concerning such failures, for example, sudden failures or
wear out of other technologies.
The purpose of this document is to present a case study of functional safety for RESS considering
E/E systems (e.g. BMS) and mechanical, electrical and electrochemical factors for elements of other
technologies (e.g. battery cells) according to the methodology of the ISO 26262 series, and to show
examples of functional safety development for E/E systems (e.g. BMS) and systems of other technologies
as a reference.
Based on the ISO 26262:2018 series, the case study in this document provides an additional methodology
to cover the strong interaction between E/E systems (e.g. BMS) and systems of other technologies
(e.g. battery cells) by considering E/E, mechanical and electrochemical related factors. This document
follows the V model framework defined in the ISO 26262 series and provides corresponding functional
safety strategies, and verification and validation methods for the development of a functionally safe
RESS.
All the technical information and the associated data in this document are combined with the state-
of-the-art technologies of current automotive battery industry, which will be updated with the
development of battery cell technology and other related technology.
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TECHNICAL REPORT ISO/TR 9968:2023(E)
Road vehicles — Functional safety — Application to
generic rechargeable energy storage systems for new
energy vehicle
1 Scope
This document is intended to be applied to the usage of ISO 26262 methodology for rechargeable
energy storage systems (RESS), for example, lithium-ion battery systems, that are installed in series-
production road vehicles, excluding mopeds.
This document does not address unique E/E systems in special vehicles such as E/E systems designed
for drivers with disabilities.
This document provides:
a) a generic informative framework regarding the interaction of E/E systems with elements of other
technologies with respect to the ISO 26262 series aspects of item definition, hazard analysis and
risk assessment (HARA), functional safety concept (FSC), verification and validation (V&V), and
production, operation, service and decommissioning (POSD);
b) various examples elaborating the generic framework;
c) topics which could be considered in future editions of the ISO 26262 series.
RESS includes BMS, cells, harnesses, connectivity, etc. In order to achieve product safety non-E/E
functional safety requirements need to be fulfilled by the other technology itself without the support of
E/E technology. These requirements are not in scope of this document.
2 Normative references
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.
ISO 26262-1, Road vehicles — Functional safety — Part 1: Vocabulary
3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO 26262-1 and the following
apply.
ISO and IEC maintain terminology databases for use in standardization at the following addresses:
— ISO Online browsing platform: available at https:// www .iso .org/ obp
— IEC Electropedia: available at https:// www .electropedia .org/
3.1
RESS
rechargeable energy storage system
system that stores energy for delivery of electrical energy and which is rechargeable
EXAMPLE RESS including batteries, capacitors, battery management system (BMS) (3.2), etc.
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ISO/TR 9968:2023(E)
3.2
BMS
battery management system
E/E system with the intended functionality being to measure battery status, exchanges information
(e.g. voltage, current, temperature, fault information, etc.) with external E/E components, and support/
control managing battery electrical energy storage and delivery
Note 1 to entry: Managing the battery includes monitoring of safety-related properties and conditions and to
appropriately react to these if necessary.
Note 2 to entry: It monitors and/or manages its state, calculates secondary data, reports that data and/or
controls its environment to influence the battery’s safety, performance and/or service life.
Note 3 to entry: The BMS is sometimes also referred to as a BМU (battery management unit).
3.3
hazardous condition
condition causing the occurrence of a hazard
EXAMPLE 1 Over temperature can lead to a thermal event of a lithium-ion battery cell. In this case the over
temperature is considered to be a hazardous condition.
EXAMPLE 2 For some lithium-ion battery technologies, repeated charging at sub-zero temperatures can
cause lithium plating, dendrite growth and ultimately a cell short circuit leading to a thermal event. In this case
charging at sub-zero temperatures is considered to be a hazardous condition.
3.4
protection function
intended E/E functionality to control a malfunctioning behaviour of another item, a failure of an
element external to the item, to prevent the occurrence of a non-E/E-functional hazard (3.6), to control
non-E/E-functional hazard or to prevent the occurrence of harm due to non-E/E-functional hazards
3.5
hazard
potential source of harm
[SOURCE: ISO 26262-1:2018, 3.75, modified — The phrase “caused by malfunctioning behaviour of the
item” as well as the Note 1 to entry were deleted.]
3.6
non-E/E-functional hazard
hazard not in scope of the ISO 26262 series
EXAMPLE Hazards related to electric shock, fire, smoke, heat, radiation, toxicity, flammability, reactivity,
corrosion, release of energy and similar hazards, unless directly caused by malfunctioning behaviour of safety-
related E/E systems.
3.7
E/E-functional hazard
hazard caused by the malfunctioning behaviour of the item
Note 1 to entry: This hazard is within scope of the ISO 26262 series.
3.8
risk mitigation effectiveness
risk reduction due to the safety measure for the safety concern under consideration
Note 1 to entry: The safety measure effectiveness can be assessed in a quantitative way as well as in a qualitative
way.
Note 2 to entry: Safety concerns include, but are not limited to, hazards and failure modes.
EXAMPLE 1 Due to mechanical overdesign the expected failure rate is reduced by a factor of 1 000.
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ISO/TR 9968:2023(E)
EXAMPLE 2 The failure mode coverage of a safety mechanism.
EXAMPLE 3 The diagnostic coverage (3.9) of a safety mechanism.
EXAMPLE 4 Expert judgement rating the risk mitigation effectiveness as low, medium or high.
3.9
diagnostic coverage
percentage of the failure rate of a hardware or other technology (3.10) element, or percentage of the
failure rate of a failure mode of a hardware or other technology element that is detected or controlled
by the implemented safety mechanism or protection function (3.4)
[SOURCE: ISO 26262-1:2018, 3.33, modified — The phrases “or other technology” and “or protection
function” were added and Notes 1 to 3 to entry were deleted.]
3.10
OT
other technology
technology different from E/E technologies that are within the scope of the ISO 26262 series
EXAMPLE Mechanical technology; hydraulic technology; chemical technology.
[SOURCE: ISO 26262-1:2018, 3.105 modified —Note 1 to entry was deleted and "chemical technology"
was added to the example.]
3.11
OT safety
other technology safety
absence of unreasonable risk due to non-E/E-functional hazards (3.6) caused by fault, failures or
properties of the other technology (3.10)
4 Abbreviated terms
BMS Battery management system
BOL Beginning of life
CB Circuit breaker
DCR Direct current resistance
EOL End of life
FSC Functional safety concept
HARA Hazard analysis and risk assessment
HVIL High voltage interlock loop
MOL Middle of life
OT Other technology
OVP Overvoltage protection
RESS Rechargeable energy storage system
SOC State of charge
SOH State of health
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ISO/TR 9968:2023(E)
SOHE State of health energy
UVP Undervoltage protection
V&V Verification and validation
5 Item definition
5.1 Objectives
The objectives of this clause are:
a) to provide a generic framework for the item definition regarding the interaction of E/E systems
with elements of OT;
b) to provide examples of "item definitions" illustrating the proposed "generic framework", especially
the interactions of E/E systems with elements of OT.
5.2 General
The ISO 26262 series allows significant degrees of freedom regarding the definition of item and its
boundary. Hence for a given system there are multiple ways to define the item compliant with the
ISO 26262 series. In the context of RESS two kinds of item definition approaches can be distinguished:
a) the OT is part of the item;
b) the OT is external to the item.
The different two approaches are elaborated with the help of a simplified RESS example as shown in 5.3
and 5.4. Regardless of which approach is used, the common point is:
1) to define the item itself and interior of the item:
— defining the functionality of the item, and the assumptions of the item;
— defining the functionality of internal elements;
— defining interfaces and interactions between the internal elements.
2) to define relationship between the item and other objects:
— defining expected behaviour of other objects (environment, other items, external elements,
etc.);
— defining the functionality of the item under consideration required by other objects and
constraints resulting from other objects;
— defining the functionality and constraints of other objects required by the item under
consideration;
— defining external interface.
These points are shown in Figure 1.
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ISO/TR 9968:2023(E)
Figure 1 — Visualization of the task of the item definition
5.3 OT is part of the item
5.3.1 General
In this case the item corresponds with RESS in Figure 2.
Figure 2 — OT is part of the item – Example
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ISO/TR 9968:2023(E)
5.3.2 Assumptions
The assumptions for the item are:
a) electrical energy storage [RESS-06] consists of several lithium-ion cells;
b) each cell has specifications for use (e.g. cell voltage, temperature, must be within operating limits);
NOTE Usually, these specifications are provided from the lithium-ion cell manufacturer.
c) the total voltage of the RESS-06 is greater or equal to 240 V.
5.3.3 Functionality
The functionality of the item is:
a) to cooperate with other HV DC systems to provide the required RESS energy level, input / output
current and temperature within operating limits;
b) to connect/disconnect RESS and other HV DC systems;
c) to store electrical energy within itself, providing electrical energy for other HV systems, and
receiving electrical energy from other HV DC systems.
5.3.4 Internal elements and their functionality
Internal elements and their functionality are as follows, including their classification as E/E or OT:
a) enclosure [RESS-01]: OT
— to provide structural protection for the RESS and separation from the external environment
that could affect the internal RESS;
— to ensure pressure balancing and limit the pressure with the venting device;
b) BMS [RESS-02]: E/E
— to estimate state of charge (SOC);
— to estimate state of health (SOH);
— to send information to other systems, e.g.
— SOC, SOH, charging/discharging current limit, cooling/warming request;
— to receive information from other systems, e.g.
— HV junction connecting/disconnecting request;
— to monitor current, voltage and temperature;
— to perform emergency electrical disconnection during crash;
— to monitor ground isolation;
— to perform cell balancing;
— etc.
c) HV junction [RESS-03]: E/E
— to connect/disconnect RESS and other HV DC systems;
— to provide an electrical controlled fuse to protect from overcurrent;
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ISO/TR 9968:2023(E)
d) electrical energy storage sensors [RESS-04]: E/E
— to measure all cell voltages;
— to measure electrical storage temperature;
— to measure current into and out of electrical storage;
e) RESS temperature control unit [RESS-05]: E/E
— to measure RESS heat exchanger temperature;
— to open/close coolant path;
f) electrical energy storage [RESS-06]: E/E and OT
— to store electrical energy;
g) RESS heat exchanger [RESS-07]: OT
— to cool HV junction, and exchange heat (cooling or warming) between electrical storage and
itself.
5.3.5 Internal interfaces
The internal interfaces are as follows, including their classification as E/E or OT:
a) communication [in I/F-01]: E/E
— communication of measured values (all cell voltages, electrical storage temperature, current)
from electrical energy storage sensors to BMS;
— communication of cell balancing instructions from BMS to electrical energy storage sensors;
b) HV DC2 [in I/F-02]: E/E
— transferring electrical power between HV junction and electrical energy storage sensors;
c) I/O1 [in I/F-03]: E/E
— transferring drive signals from BMS to HV junction. This signal is able to connect/disconnect
RESS and other HV DC systems;
d) I/O2 [in I/F-04]: E/E
— transferring measured temperature value of heat exchanger from RESS temperature control
unit to BMS;
— transferring drive signals from BMS to RESS temperature control unit. This signal is able to
open/close coolant path;
e) HV DC3 [in I/F-05]: E/E
— transferring electrical power between electrical energy storage sensors and electrical storage;
f) I/O3 [in I/F-06]: E/E
— connecting electrical energy storage and electrical energy storage sensors for monitoring cell
voltage;
— transferring charge to balance cell voltage;
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ISO/TR 9968:2023(E)
g) heat conduct1 [in I/F-07]: OT
— conducting electrical storage heat to electrical energy storage sensors;
h) heat conduct2 [in I/F-08]: OT
— conducting HV junction heat to RESS heat exchanger;
i) heat conduct3 [in I/F-09]: OT
— conducting RESS heat exchanger heat to RESS temperature control unit;
j) Coolant2 [in I/F-10]: OT
— transferring heat between RESS temperature control unit and RESS heat exchanger;
k) heat exchange [in I/F-11]: OT
— exchanging heat between electrical storage and RESS heat exchanger.
5.3.6 Other objects
Other objects are as follows, including their classification as E/E or OT.
a) vehicle system controller [OtherItem-01]: E/E
— controlling the drive of a vehicle;
b) charger (AC, DC) system [OtherItem-02]: E/E and OT
— controlling charging power or charging constant current or charging constant voltage into
RESS;
c) inverter and motor system [OtherItem-03]: E/E and OT
— controlling power to traction motors and power from regenerative braking;
d) vehicle thermal system [OtherItem-04]: E/E and OT
— controlling RESS to the proper temperature;
e) vehicle structure [OtherItem-05]: OT
5.3.7 External interfaces
External interfaces are as follows, including their classification as E/E or OT:
a) CAN [ex I/F-01]: E/E
— exchanging information between RESS to other systems;
b) LV DC [ex I/F-02]: E/E
— supplying power to RESS E/E systems;
c) crash signal [ex I/F-03]: E/E
— sending signal to RESS that a vehicle crash has occurred;
d) ground [ex I/F-04]: E/E
— suppl
...