锂离子电池变频变幅交流低温自加热策略

doi:10.19595/j.cnki.1000-6753.tces.180604

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摘要低温下锂离子电池的可用容量和功率大幅下降,而且充电困难。对锂离子电池进行低温加热是改善其性能的有效途径。该文建立了电池的热-电耦合模型,设计了一种变频变幅交流自加热策略,在保证极化电压幅值不变的条件下,以加热功率最大为目标,根据电池在各个温度下得到的最佳加热频率实时调整交流激励的频率和幅值。对比不同策略发现,采用变频变幅交流自加热策略,电池在700 s内上升了47.67℃,相比恒频变幅加热策略,其温升速率最大可提高21.85%。所设计的变频变幅交流自加热策略具有良好的加热效果,有利于促进电动汽车在寒冷环境下的推广应用。

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	何锡添
	孙丙香
	阮海军
	王占国
	苏晓佳

关键词 ：锂离子电池, 低温自加热, 热-电耦合模型, 变频变幅

Abstract：At low temperatures, the available capacity and power of lithium-ion battery will significantly reduce, and charging is difficult. Low-temperature heating is an effective way to improve the performance of battery. In this paper, an electro-thermal coupled model was established, and a self-heating strategy of variable-frequency and variable-amplitude (VFVA) AC was proposed. Under the condition that the amplitude of polarization voltage was constant, the frequency and amplitude of the AC excitation were adjusted in real time according to the optimal heating frequency obtained at each temperature, which aimed at maximizing heating power. It is found that the VFVA AC self-heating strategy has a good effect and the battery temperature has risen 47.67℃in 700 s. Compared with the constant-frequency and variable- amplitude (CFVA) AC self-heating strategy, VFVA AC self-heating strategy has a maximum increase of 21.85% in the temperature rising rate. Therefore, the VFVA AC self-heating strategy is conducive to the promotion and application of electric vehicles in cold environment.

Key words： Lithium-ion battery low-temperature self-heating electro-thermal coupled model variable-frequency and variable-amplitude

收稿日期: 2018-04-16 出版日期: 2019-05-14

PACS:

TM911

基金资助:国家重点研发计划资助项目（2017YFB1201003）

引用本文:

何锡添, 孙丙香, 阮海军, 王占国, 苏晓佳. 锂离子电池变频变幅交流低温自加热策略[J]. 电工技术学报, 2019, 34(9): 1798-1805. He Xitian, Sun Bingxiang, Ruan Haijun, Wang Zhanguo, Su Xiaojia. A Variable-Frequency and Variable-Amplitude AC Low-Temperature Self-Heating Strategy for Lithium-Ion Battery. Transactions of China Electrotechnical Society, 2019, 34(9): 1798-1805.

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https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.180604 https://dgjsxb.ces-transaction.com/CN/Y2019/V34/I9/1798

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