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锂离子电池组热管理系统研究现状
Statues quo of research on Li-ion battery thermal management system

查看参考文献24篇

文摘 归纳锂离子电池组结构设计的要点,包括冷却介质的流通方式、进出口设置和电池的排列。总结现有电池冷却和预热技术的优缺点。空气冷却系统结构简单、应用广泛,但效果较差;液体冷却系统效果显著,能耗较大、密封要求高;相变材料的应用需要提高导热率和比热容;热管冷却系统结构紧凑,配合风机冷却效果更佳。相对于内部加热系统,电池组外部加热系统结构简单,但加热速度较慢。冷却/加热一体化电池组热管理系统的开发,将是研究的方向。
其他语种文摘 The points of Li-ion battery pack structure design were overviewed,including the flow modes of cooling medium,inlet and outlet settings and the arrangement of cells. The advantages and disadvantages of the existing battery cooling and preheating technology were summarized. Air cooling system with a simple structure was widely used,but the performance was relatively poor. Liquid cooling system performed well,while the energy consumption and the sealing requirements were high. The improvement of thermal conductivity and specific heat would promote the application of phase change materials. Heat-pipe cooling system was more compact and performed well with a fan. In contrast of the internal heating system,the battery external heating system was simple structure but heating up slowly. The development of battery thermal management system with heating and cooling function would be the research direction.
来源 电池 ,2016,46(3):168-171 【扩展库】
关键词 锂离子电池 ; 电池热管理系统 ; 结构设计 ; 冷却技术 ; 预热技术
地址

中国科学院广州能源研究所, 广东, 广州, 510640

语种 中文
文献类型 综述型
ISSN 1001-1579
学科 电工技术
基金 广东省广州市科技计划项目 ;  广东省科技计划项目
文献收藏号 CSCD:5753502

参考文献 共 24 共2页

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引证文献 3

1 宋文吉 锂离子电池组不一致性控制的研究进展 电池,2017,47(5):303-306
被引 3

2 黄彩霞 电动汽车用锂离子电池组的爆炸原因与避免措施 电池,2018,48(1):60-62
被引 2

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