Experimental Investigation of Thermal Runaway Propagation in a Lithium-Ion Battery Pack: Effects of State of Charge and Coolant Flow Rate

IF 4.6 4区 化学 Q2 ELECTROCHEMISTRY Batteries Pub Date : 2023-11-12 DOI:10.3390/batteries9110552
Wanyi Wu, Qiaomin Ke, Jian Guo, Yiwei Wang, Yishu Qiu, Jiwen Cen, Fangming Jiang
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Abstract

Lithium-ion batteries (LIBs) are widely used as power sources for electric vehicles due to their various advantages, including high energy density and low self-discharge rate. However, the safety challenges associated with LIB thermal runaway (TR) still need to be addressed. In the present study, the effects of the battery SOC value and coolant flow rate on the TR behavior in a LIB pack are comprehensively investigated. The battery pack consists of 10 18650-type LIBs applied with the serpentine channel liquid-cooling thermal management system (TMS). The TR tests for various SOC values (50%, 75% and 100%) and coolant flow rates (0 L/h, 32 L/h, 64 L/h and 96 L/h) are analyzed. The retarding effect of the TMS on TR propagation is found to be correlated with both the coolant flow rate and the battery SOC value, and a larger coolant flow rate and lower SOC generally result in fewer TR batteries. Furthermore, the TR propagation rate, evaluated by the time interval of TR occurrence between the adjacent batteries, increases with the battery SOC. The battery pack with 100% SOC shows more rapid TR propagation, which can be completed in just a few seconds, in contrast to several minutes for 50% and 75% SOC cases. In addition, the impact of the battery SOC and coolant flow rate on the maximum temperature of the TR battery is also examined, and no determined association is observed between them. However, it is found that the upstream batteries (closer to the external heater) show a slightly higher maximum temperature than the downstream ones, indicating a weak association between the TR battery maximum temperature and the external heating duration or the battery temperature at which the TR starts to take place.
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锂离子电池组热失控传播的实验研究:充电状态和冷却剂流量的影响
锂离子电池以其能量密度高、自放电率低等优点被广泛应用于电动汽车的动力源。然而,与LIB热失控(TR)相关的安全挑战仍然需要解决。在本研究中,全面研究了电池荷电状态值和冷却剂流量对LIB电池组TR行为的影响。电池组由10个18650型锂电池组成,采用蛇形通道液冷热管理系统(TMS)。分析了不同SOC值(50%、75%和100%)和冷却剂流量(0 L/h、32 L/h、64 L/h和96 L/h)下的TR试验。研究发现,TMS对TR传播的阻滞作用与冷却剂流量和电池荷电状态有关,冷却剂流量越大,电池荷电状态越低,TR电池数量越少。此外,通过相邻电池之间TR发生的时间间隔来评估的TR传播速率随着电池SOC的增加而增加。100% SOC的电池组显示出更快的TR传播速度,可以在几秒钟内完成,而50%和75% SOC的电池组则需要几分钟。此外,还研究了电池SOC和冷却液流量对TR电池最高温度的影响,并没有发现两者之间存在确定的关联。然而,我们发现上游电池(靠近外部加热器)的最高温度略高于下游电池,这表明TR电池的最高温度与外部加热持续时间或TR开始时的电池温度之间存在弱关联。
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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来源期刊
Batteries
Batteries Energy-Energy Engineering and Power Technology
CiteScore
4.00
自引率
15.00%
发文量
217
审稿时长
7 weeks
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