A battery equalizer with zero-current switching and zero-voltage gap among cells based on three-resonant-state LC converters

2017 IEEE Applied Power Electronics Conference and Exposition (APEC) Pub Date : 2017-03-26 DOI:10.1109/APEC.2017.7930920

Yunlong Shang, N. Cui, Qi Zhang, Chenghui Zhang

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引用次数: 10

Abstract

For the conventional switched capacitor converter (SCC) based equalizers, it is difficult to achieve the full equalization among cells due to the inevitable voltage fall across MOSFET switches. Particularly, when the voltage gap among cells is larger, the balancing efficiency is lower, but the balancing speed gets slower as the voltage gap gets smaller. In order to soften these downsides, this paper proposes a battery equalization topology with zero-current switching (ZCS) and zero-voltage gap (ZVG) among cells based on three-resonant-state SCCs. An additional resonant path is built to release the charge of the capacitor into the inductor in each cycle, which lays the foundations to obtain ZVG among cells, improves the balancing efficiency at a large voltage gap, and increases the balancing speed at a small voltage gap. A four-lithium-ion-cell prototype is applied to validate the theoretical analysis. Experiment results show the proposed topology demonstrates good balancing performance with ZCS and ZVG among cells.

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基于三谐振态LC变换器的零电流开关和电池间零电压间隙电池均衡器

对于传统的基于开关电容变换器(SCC)的均衡器，由于MOSFET开关之间不可避免的电压下降，很难实现单元之间的完全均衡。特别是当电池间电压间隙较大时，平衡效率较低，但平衡速度随着电压间隙的减小而变慢。为了消除这些缺点，本文提出了一种基于三谐振态SCCs的电池均衡拓扑，该拓扑具有零电流开关(ZCS)和零电压间隙(ZVG)。在每个周期内，通过额外的谐振路径将电容器的电荷释放到电感中，为实现电池间的ZVG奠定了基础，提高了大电压间隙下的平衡效率，提高了小电压间隙下的平衡速度。应用一个四锂离子电池原型来验证理论分析。实验结果表明，所提出的拓扑结构在单元间具有良好的ZCS和ZVG平衡性能。

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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2017 IEEE Applied Power Electronics Conference and Exposition (APEC)

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