Surrogate Model for the Effect of Charge State in Lithium-ion Battery Fires

Fire Science and Engineering Pub Date : 2024-02-28 DOI:10.7731/kifse.3b730202

S. Kim, Eui-Ju Lee

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Abstract

Recently, the demand for eco-friendly energy sources, including batteries, has increased rapidly owing to growing climate and environmental problems. However, battery fire accidents are also increasing, and many researchers are focusing on the safe use of batteries and their flammability characteristics. Owing to the multiple battery types, conducting experiments is difficult in all cases, so various methods to model battery fires are being attempted. This study focuses on the effect of charge states and models surrogate fuels for battery thermal runaway. Three surrogate fuels were selected based on the battery components, and a method of increasing the oxygen concentration was adapted to model the effect that occurs when the charge states of a battery fire increases. As a result, the temperature and pressure increased in all cases, and it appears that the explosion caused by the battery thermal runaway can be simulated by the model. One of the results of this study is that ethane exposed to a high temperature not only contributes to the physical explosion of the battery but also increases the risk of chemical explosion as it decomposes in to H2 and CH4 .

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锂离子电池火灾中充电状态影响的替代模型

最近，由于气候和环境问题日益严重，对包括电池在内的环保能源的需求迅速增加。然而，电池火灾事故也在不断增加，许多研究人员都在关注电池的安全使用及其易燃特性。由于电池种类繁多，在任何情况下都很难进行实验，因此人们正在尝试各种方法来模拟电池火灾。本研究的重点是充电状态的影响和电池热失控的代用燃料模型。根据电池组件选择了三种代用燃料，并调整了增加氧气浓度的方法，以模拟电池起火时电荷状态增加所产生的影响。结果，所有情况下的温度和压力都增加了，看来模型可以模拟电池热失控引起的爆炸。这项研究的结果之一是，暴露在高温下的乙烷不仅会导致电池的物理爆炸，而且还会由于分解成 H2 和 CH4 而增加化学爆炸的风险。

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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Fire Science and Engineering

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