Recent Advancements and Future Prospects in Lithium-Ion Battery Thermal Management Techniques

Energy Storage Pub Date : 2024-11-03 DOI:10.1002/est2.70076
Puneet Kumar Nema,  Vijaya, P. Muthukumar, Ranjith Thangavel
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Abstract

Lithium-ion batteries (LiBs) are the leading choice for powering electric vehicles due to their advantageous characteristics, including low self-discharge rates and high energy and power density. However, the degradation in the performance and sustainability of lithium-ion battery packs over the long term in electric vehicles is affected due to the elevated temperatures induced by charge and discharge cycles. Moreover, the thermal runaway (TR) issues due to the heat generated during the electrochemical reactions are the most significant safety concern for LiBs, as inadequate heat dissipation can be potentially hazardous, leading to explosions and fires. Considering the safety of EVs and for better performance, understanding the mechanism of TR is of paramount importance. This review provides a comprehensive analysis of the TR phenomenon and underlying electrochemical principles governing heat accumulation during charge and discharge cycles. Furthermore, the article explores the cell modeling and thermal management techniques intended for both individual lithium-ion battery cells and larger battery packs, with a particular emphasis on enhancing fire prevention and safety measures. The main goal of this review paper is to offer new insights to the developing battery community, assisting in the development of efficient battery thermal management systems (BTMS) using enhanced cooling methodologies. This article could also support the advancement of next-generation electric vehicle battery packs equipped with built-in safety features to improve the cycle life of LiBs and prevent thermal runaway accidents.

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锂离子电池热管理技术的最新进展和未来展望
锂离子电池(LiBs)具有自放电率低、能量和功率密度高等优点,是电动汽车的主要动力选择。然而,由于充放电循环导致的温度升高,锂离子电池组在电动汽车中的长期性能和可持续性受到影响。此外,电化学反应过程中产生的热量导致的热失控(TR)问题是锂电池最重要的安全问题,因为散热不足可能会导致爆炸和火灾。考虑到电动汽车的安全性和更好的性能,了解 TR 的机理至关重要。本综述全面分析了 TR 现象以及充放电循环过程中热量积累的基本电化学原理。此外,文章还探讨了针对单个锂离子电池芯和大型电池组的电池建模和热管理技术,并特别强调要加强防火和安全措施。这篇综述论文的主要目的是为发展中的电池界提供新的见解,利用增强型冷却方法协助开发高效的电池热管理系统(BTMS)。这篇文章还有助于推动配备内置安全功能的下一代电动汽车电池组的发展,以提高锂电池的循环寿命并防止热失控事故的发生。
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