System safety and ISO 26262 compliance for automotive lithium-ion batteries

2012 IEEE Symposium on Product Compliance Engineering Proceedings Pub Date : 2012-12-31 DOI:10.1109/ISPCE.2012.6398297

W. Taylor, G. Krithivasan, J. J. Nelson

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引用次数: 20

Abstract

Lithium ion batteries pave the way for today's plug-in hybrid and electric vehicles. However, these batteries contain the potential of thermal runaway, posing a higher safety risk from thermal incidences than NiMH batteries. Thermal runaway can be mitigated using electronic control systems, which are intended to maintain a safe state of the battery under all operating conditions. When safety depends on these control systems, any malfunction of the system or its elements (such as sensors, microcontrollers, contactors, software, etc.) may lead to a dangerous state. The newly published ISO 26262 standard provides processes and methods for the proper design, development and manufacturing of E/E automotive systems to ensure functional safety. In this paper, the ISO 26262 standard is applied to several example scenarios involving lithium-ion batteries for plug-in vehicles. Key concepts are explored and conclusions drawn regarding several of the standard's required processes, including hazard analysis and risk assessment, functional safety concept, functional safety and technical safety requirements, and related topics.

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汽车锂离子电池的系统安全性和ISO 26262合规性

锂离子电池为今天的插电式混合动力汽车和电动汽车铺平了道路。然而，这些电池存在热失控的可能性，与镍氢电池相比，热事故带来的安全风险更高。使用电子控制系统可以减轻热失控，该系统旨在保持电池在所有操作条件下的安全状态。当安全依赖于这些控制系统时，系统或其元件(如传感器、微控制器、接触器、软件等)的任何故障都可能导致危险状态。新发布的ISO 26262标准为E/E汽车系统的正确设计、开发和制造提供了流程和方法，以确保功能安全。在本文中，ISO 26262标准应用于涉及插电式汽车锂离子电池的几个示例场景。探讨了几个标准要求过程的关键概念并得出结论，包括危害分析和风险评估、功能安全概念、功能安全和技术安全要求以及相关主题。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2012 IEEE Symposium on Product Compliance Engineering Proceedings

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