Effect of States of Charge on the Burning Behaviors of Lithium ion Batteries

2019 9th International Conference on Fire Science and Fire Protection Engineering (ICFSFPE) Pub Date : 2019-10-01 DOI:10.1109/ICFSFPE48751.2019.9055886

Lu-qing Rong, Xudong Cheng, Yangyang Fu

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引用次数: 1

Abstract

The burning behaviors of 18650 type lithium ion batteries under various states of charge (SOCs) were investigated using a cone calorimeter under an incident heat flux of 50 kW/m2. Several parameters were measured, including heat release rate (HRR), time to ignition and concentration of toxic gases. The experimental results show that the peak HRR, concentration of CO2 and CO increase with the increasing SOCs, whereas the time to ignition, time to explosion and the released energy during the burning decrease. The 100 % SOC is the highest fire risk due to the most serious toxicity (CO concentration: 1500 ppm), the maximum HRR (2.78 kW) and the shortest time to ignition (43 s). Besides, the burning process of the lithium ion batteries with various SOCs could be divided into four phases and the SOCs show important influence on the combustion intensity. The HRR of the fully charged LIBs is fourth power of time, which is much higher than the time-squared fire model mentioned in NFPA for most combustibles. A correlation is developed to predict the peak HRR. This study could serve as a technical guide for safe storage, application, and transportation in lithium ion batteries.

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电荷状态对锂离子电池燃烧行为的影响

采用锥形量热仪研究了18650型锂离子电池在入射热流密度为50 kW/m2时不同充电状态下的燃烧行为。测量了几个参数，包括热释放率(HRR)、点火时间和有毒气体浓度。实验结果表明，随着SOCs的增加，峰值HRR、CO2和CO浓度增加，而点火时间、爆炸时间和燃烧过程中释放的能量减少。100%荷电状态下的锂离子电池毒性最强(CO浓度为1500 ppm)， HRR最大(2.78 kW)，着火时间最短(43 s)，火灾危险性最高。不同荷电状态下的锂离子电池燃烧过程可分为4个阶段，且荷电状态对燃烧强度有重要影响。充满电的lib的HRR是时间的四次方，这远远高于NFPA中提到的大多数可燃物的时间平方火灾模型。建立了一种相关性来预测峰值HRR。本研究可为锂离子电池的安全储存、应用和运输提供技术指导。

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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