Influence of Temperature and Pressure on the Wetting Progress in 21700 Lithium-Ion Battery Cells: Experiment, Model, and Lattice Boltzmann Simulation

IF 5.1 4区材料科学 Q2 ELECTROCHEMISTRY

Batteries & Supercaps Pub Date : 2024-10-08 DOI:10.1002/batt.202400531

Johannes Wanner, Matthias Burgard, Nabih Othman, Soumya Singh, Prof. Dr. Kai Peter Birke

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Abstract

The electrolyte filling and subsequent wetting of the active material is a time-critical process in the manufacturing of lithium-ion batteries. Due to the metallic cell housing, the process phenomena are insufficiently accessible, preventing the replication of the wetting processes by mathematical or simulative methods and hindering efforts to accelerate the wetting process. Therefore, this publication employs a glass cell housing for electrolyte filling of a 21700 cylindrical cell to investigate the wetting at different temperatures and process pressures. In parallel, a mathematical replication of the wetting, as well as a lattice Boltzmann pore-scale simulation, is used to evaluate the influence of these varying process boundary conditions. The results show a strong temperature dependence on electrolyte wetting and the positive effect of pressure changes in the wetting process. These findings are particularly relevant to the process design of large-scale cylindrical cell manufacturing.

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温度和压力对21700锂离子电池润湿过程的影响：实验、模型和晶格玻尔兹曼模拟

在锂离子电池的制造过程中，电解液的填充和随后活性材料的润湿是一个时间紧迫的过程。由于金属电池外壳，过程现象无法充分接近，阻碍了通过数学或模拟方法复制润湿过程，并阻碍了加速润湿过程的努力。因此，本出版物采用玻璃电池外壳，用于21700圆柱形电池的电解质填充，以研究不同温度和工艺压力下的润湿。同时，湿润的数学复制，以及晶格玻尔兹曼孔尺度模拟，被用来评估这些变化的过程边界条件的影响。结果表明，温度对电解质润湿有很强的依赖性，而压力变化对润湿过程有积极的影响。这些发现与大规模圆柱形电池制造的工艺设计特别相关。

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来源期刊

Batteries & Supercaps Multiple-

CiteScore

8.60

自引率

5.30%

发文量

223

期刊介绍： Electrochemical energy storage devices play a transformative role in our societies. They have allowed the emergence of portable electronics devices, have triggered the resurgence of electric transportation and constitute key components in smart power grids. Batteries & Supercaps publishes international high-impact experimental and theoretical research on the fundamentals and applications of electrochemical energy storage. We support the scientific community to advance energy efficiency and sustainability.