A Study on dFMEA-based Fire Risk Assessment of Lithium-ion Secondary Battery Testing Cells

2019 9th International Conference on Fire Science and Fire Protection Engineering (ICFSFPE) Pub Date : 2023-10-31 DOI:10.7731/kifse.f4f02cf1

Jong Gu Kim, Hyeong Gi Kim

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Abstract

In this study, Design Failure Mode and Effects Analysis (dFMEA) was performed to evaluate the fire risk of lithium-ion secondary battery testing cells used during the research and development stage. dFMEA was used for the failure risk analysis, risk assessment, and risk priority analysis of the anode, cathode, separator, electrolyte, and cell design of the testing cell. In addition, the evaluation criteria, including severity, occurrence, and detection, was reorganized into three categories and optimized for the testing cell application. Based on the failure risk analysis, a total of 11 causes of failure were identified. In particular, explosion and thermal runaway were predicted when a nickel-cobalt-manganese (NCM)-based anode material with a high nickel content was used, the separator had a high thermal contraction rate and low tensile strength characteristics, and there were errors in the electrolyte composition optimization. This cause of failure was classified as a moderate risk with a high fire risk by the risk priority analysis. Therefore, at the research and development stage, it is critical to evaluate the mutual reactivity and preliminary physical properties of battery materials and to construct safety equipment to reduce fire damage.

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基于dfmea的锂离子二次电池测试电芯火灾风险评估研究

本研究采用设计失效模式及影响分析(dFMEA)对研发阶段使用的锂离子二次电池测试电芯进行火灾风险评估。采用dFMEA对测试电池的阳极、阴极、分离器、电解液、电池设计进行失效风险分析、风险评估和风险优先级分析。此外，评估标准(包括严重性、发生和检测)被重新组织为三类，并针对测试单元应用程序进行了优化。基于失效风险分析，共确定了11个失效原因。特别是在使用镍含量高的镍钴锰(NCM)基阳极材料、高热收缩率和低抗拉强度特性以及电解质成分优化存在误差的情况下，预测了爆炸和热失控。通过风险优先级分析，该故障原因被归类为中度风险和高度火灾风险。因此，在研发阶段，评估电池材料的相互反应性和初步物理性能，构建安全设备以减少火灾损害至关重要。

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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2019 9th International Conference on Fire Science and Fire Protection Engineering (ICFSFPE)

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