Experimental Investigation on Affecting Air Flow against the Maximum Temperature Difference of a Lithium-Ion Battery with Heat Pipe Cooling

IF 2.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

World Electric Vehicle Journal Pub Date : 2023-11-07 DOI:10.3390/wevj14110306

Chokchai Anamtawach, Soontorn Odngam, Chaiyut Sumpavakup

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Abstract

Research on battery thermal management systems (BTMSs) is particularly significant since the electric vehicle sector is growing in importance and because the batteries that power them have high operating temperature requirements. Among them, heat pipe (HP)-based battery thermal management systems have very high heat transfer performance but fall short in maintaining uniform temperature distribution. This study presented forced air cooling by an axial fan as a method of improving the cooling performance of flat heat pipes coupled with aluminum fins (FHPAFs) and investigated the impact of air velocity on the battery pack’s maximum temperature differential (ΔTmax). All experiments were conducted on lithium nickel manganese cobalt oxide (NMC) pouch battery cells with a 20 Ah capacity in seven series connections at room temperature, under forced and natural convection, at various air velocity values (12.7 m/s, 9.5 m/s, and 6.3 m/s), and with 1C, 2C, 3C, and 4C discharge rates. The results indicated that at the same air velocity, increasing the discharge rate increases the ΔTmax significantly. Forced convection has a higher ΔTmax than natural convection. The ΔTmax was reduced when the air velocity was increased during forced convection.

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热管冷却对锂离子电池最大温差影响的实验研究

电池热管理系统(btms)的研究尤为重要，因为电动汽车领域的重要性日益提高，而且为电动汽车提供动力的电池具有很高的工作温度要求。其中，基于热管(HP)的电池热管理系统具有很高的传热性能，但在保持温度均匀分布方面存在不足。本研究提出了轴流风扇强制空气冷却作为一种改善铝翅片平板热管(fhfas)冷却性能的方法，并研究了空气速度对电池组最大温差的影响(ΔTmax)。实验采用容量为20 Ah的锂镍锰钴氧化物(NMC)袋状电池，在室温、强迫对流和自然对流、不同风速值(12.7 m/s、9.5 m/s和6.3 m/s)、1C、2C、3C和4C放电速率下进行7组串联连接。结果表明:在风速相同的情况下，增大排气率可显著提高ΔTmax。强迫对流比自然对流具有更高的ΔTmax。在强制对流过程中，随着气流速度的增大，ΔTmax减小。

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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