Coupled Electrochemical-Thermal Simulations and Validation of Minichannel Cold-Plate Water-Cooled Prismatic 20 Ah LiFePO4 Battery

Chaithanya Akkaldevi, Sandeep Dattu Chitta, J. Jaidi, S. Panchal, M. Fowler, R. Fraser
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引用次数: 71

Abstract

This paper discusses the quantitative validation carried out on a prismatic 20 Ah LiFePO4 battery sandwiched between two minichannel cold-plates with distributed flow having a single U-turn. A two-way coupled electrochemical-thermal simulations are performed at different discharge rates (1–4 C) and coolant inlet temperatures (15–35 °C). The predicted battery voltage response at room temperature (22 °C) and the performance of the Battery Thermal Management System (BTMS) in terms of the battery surface temperatures (maximum temperature, Tmax and temperature difference, ΔT) have been analyzed. Additionally, temperature variation at ten different locations on the battery surface is studied during the discharge process. The predicted temperatures are compared with the measured data and found to be in close agreement. Differences between the predicted and measured temperatures are attributed to the assumption of uniform heat generation by the Li-ion model (P2D), the accuracy of electrochemical property input data, and the accuracy of the measuring tools used. Overall, it is suggested that the Li-ion model can be used to design the efficient BTMS at the cell level.
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小通道冷板水冷棱镜型20ah LiFePO4电池的电化学-热耦合模拟与验证
本文讨论了将20 Ah磷酸铁锂柱状电池夹在两个小通道冷板之间的定量验证,该冷板具有单个u型转弯的分布流。在不同的放电速率(1-4℃)和冷却剂入口温度(15-35℃)下进行了双向耦合电化学-热模拟。分析了室温(22°C)下的电池电压响应预测,以及电池热管理系统(BTMS)在电池表面温度(最高温度,Tmax和温差,ΔT)方面的性能。此外,研究了放电过程中电池表面10个不同位置的温度变化。将预测温度与实测数据进行了比较,发现两者非常吻合。预测温度与测量温度之间的差异归因于锂离子模型(P2D)假设均匀产热,电化学特性输入数据的准确性以及所使用测量工具的准确性。综上所述,锂离子模型可用于在电池水平上设计高效的BTMS。
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