On the effect of gas generation on heat transfer during thermal runaway of pouch cells

IF 3.2 Q2 CHEMISTRY, PHYSICAL

Energy advances Pub Date : 2024-06-07 DOI:10.1039/D4YA00205A

Niklas Weber, Sebastian Schuhmann, Robert Löwe, Jens Tübke and Hermann Nirschl

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Abstract

Lithium-ion batteries produce a vast amount of gases during decomposition reactions and thermal runaway. While the amount and composition of these gases has been investigated in the past, little is known about their impact on thermal transport inside the battery cell. Especially for pouch cells, which do not have a rigid housing, this becomes even more important in multi-cell scenarios since thermal propagation is governed by heat transfer. In this work, a simulation framework is presented that enhances the chemical single cell model by accounting for these thermal transport changes in gas producing pouch cells. It is validated by performing two battery cell propagation experiments in an autoclave. Besides the temperature measurement, the propagation time between the cells and the gas composition are analyzed and compared between simulation and experiment. Further, it is investigated how the application of an external pressing force impacts the heat transfer and thus the propagation behavior. In the given setup, the propagation time decreased from 37.2 s to 16.8 s with increasing pressing force.

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袋式电池热失控过程中气体生成对传热的影响

锂离子电池在分解反应和热失控过程中会产生大量气体。虽然过去曾对这些气体的数量和成分进行过研究，但对它们对电池内部热传输的影响却知之甚少。特别是对于没有刚性外壳的袋式电池，由于热传播受热传导的影响，因此在多电池情况下，这种影响变得更加重要。本研究提出了一个仿真框架，通过考虑产气袋电池中的这些热传输变化，增强了化学单电池模型。通过在高压釜中进行两次电池单元传播实验，验证了这一模拟框架。除了温度测量外，还分析了电池和气体成分之间的传播时间，并对模拟和实验进行了比较。此外，还研究了施加外部压力如何影响热传导，进而影响传播行为。在给定的设置中，随着加压力的增加，传播时间从 37.2 秒缩短到 16.8 秒。

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来源期刊

Energy advances

CiteScore

1.80

自引率

0.00%

发文量