摘 要:为了解决碳排放和全球变暖的问题,电池技术在电动汽车领域的应用研究如火如荼,电池均衡技术在提高电池使用寿命、确保电动汽车稳定高效运行方面发挥着至关重要的作用。文章介绍了主流的均衡电路分类,阐述了主动均衡中变换器式主动均衡以及国内外研究者在 LTC3300 电池组均衡技术方面的改进策略及研究成果,分析了电池均衡技术在市场上的应用及国内外主流汽车厂商的最新研究成果,最后展望了电池管理系统均衡技术的发展。
关键词:电动汽车;均衡技术;主动均衡;被动均衡
DOI:10.19850/j.cnki.2096-4706.2022.08.016
基金项目: 重庆市高校创新研究群体(CXQT20024); 重庆市自然科学基金(cstc2021jcyj-msxm2025);万州区科学技术项目
中图分类号:TM921.5 文献标识码:A 文章编号:2096-4706(2022)08-0056-04
Overview of the Development of Battery Management System Equalization Technology
WANG Xiaolu, TAN Zefu, DAI Nina, XUE Jing, XIANG Lihong
(Key Laboratory of Signal and Information Processing, Chongqing Three Gorges University, Chongqing 404000, China)
Abstract: In order to solve the problems of carbon emissions and global warming, the application research of battery technology in the field of electric vehicles is in full swing. Battery equalization technology plays a vital role in improving the service life of batteries and ensuring the stable and efficient operation of electric vehicles. This paper introduces the classification of mainstream equalization circuits, expounds the converter type active equalization in active equalization and the improvement strategies and research results of domestic and foreign researchers in LTC3300 battery pack equalization technology, analyzes the application of battery equalization technology in the market and the latest research results of domestic and foreign mainstream automobile manufacturers, and finally looks forward to the development of battery management system equalization technology.
Keywords: electric vehicle; equalization technology; active equalization; passive equalization
参考文献:
[1] 訾洪静 . 浅谈分布式电动汽车锂电池智能均衡系统设计[J]. 时代汽车,2020(16):103-104.
[2] 巫春玲,刘智轩,程琰清,等 . 动力锂电池组均衡拓扑研究综述 [J]. 电子测量技术,2021,44(15):7-14.
[3] 刘征宇,武银行,李鹏飞,等 . 基于 Cuk 斩波电路的电池组均衡方法 [J]. 仪器仪表学报同,2019,40(2):233-241.
[4] 李斌,许磊,郑征,等 . 基于 Cuk 电路的多交错对称式均衡方案 [J]. 储能科学与技术,2021,10(4):1400-1406.
[5] LI Y K,ZHANG A,LI H,et al. A Voltage Equalization Device ForMulti-TypeLithium-Ion Batteries [C]//2019 IEEE 3rd International Electrical and Energy Conference (CIEEC). Beijing:IEEE,2019:326-329.
[6] DEHRI K,NOURI A S. A discrete repetitive adaptive sliding mode control for DC-DC buck converter [J].Proceedings of the Institution of Mechanical Engineers Part I Journal of Systems and Control Engineering,2021,235(9):1698-1708.
[7] 龚坤珊,李赓,戴钱坤 . 一种无源无损吸收的交错并联Buck 电路 [J]. 电力电子技术,2021,55(6):81-83.
[8] 马晓爽,梁晖,丁庆,等 . 多端口双向 Buck-Boost 变换器研究 [J]. 电力电子技术,2021,55(5):129-135.
[9] 王鹤,褚渊,黄堃,等 . 基于移相全桥的两级式交错并联DC/DC 拓扑研究 [J]. 电源技术,2021,45(3):386-390.
[10] 刘政,张向文,黄斌 . 基于 LTC3300-1 的电动汽车锂电池组主动均衡系统研究 [J]. 电源技术,2018,42(7):993-996.
[11] 行业分析 .2021 年新能源汽车行业深度报告 [EB/OL].[2022-02-30].https://xw.qq.com/partner/vivoscreen/20210811A0DPBO/20210811A0DPBO00?isNews=1.
作者简介:王晓露(1998.06—),女,汉族,天津人,硕士研究生在读,研究方向:电动汽车关键技术研究。