Research on Capacity Difference Identification Method of Lithium-ion Battery Pack

被引：0

作者：

Liu Y. ^{[1
]}

Zhang C. ^{[1
]}

Jiang J. ^{[2
]}

Zhang W. ^{[1
]}

Zhang L. ^{[1
]}

机构：

[1] National Active Distribution Network Technology Research Center, Beijing Jiaotong University, Haidian District, Beijing

[2] School of Electrical and Electronic Engineering, Hubei University of Technology, Wuhan

来源：

Zhongguo Dianji Gongcheng Xuebao/Proceedings of the Chinese Society of Electrical Engineering | 2021年 / 41卷 / 04期

关键词：

Capacity difference estimation; Charging voltage curve; Dynamic time warping algorithm; Lithium-ion battery pack;

D O I：

10.13334/j.0258-8013.pcsee.200483

中图分类号：

学科分类号：

摘要：

Inconsistency is one of the important factors restricting the available capacity of battery packs. The difference in the parameters of the battery pack is an important indicator for describing the performance of the battery pack, and the difference in capacity is causally related to the available capacity and optimized control of the battery pack. A reasonable assumption for simple scaling of the voltage curve when the charging current changes was proposed. Based on this assumption, a fast capacity difference identification method was established. The rationality and adaptability of the method was analyzed and verified in various situations. The incremental capacity analysis method was used to correct the estimation error caused by SOC and internal resistance. This method was applied to battery pack charging data with high voltage sampling accuracy and wide SOC operating range. The basic algorithm error is less than 2.5%, and the identification error can be less than 1.5% after correction. The method proposed in this paper can be used to describe the inconsistency of the battery capacity within the battery pack and provide a reference for the balance and maintenance of the battery pack. © 2021 Chin. Soc. for Elec. Eng.

引用

页码：1422 / 1430

页数：8

共 25 条

[1] LEE S, KIM J, LEE J, Et al., State-of-charge and capacity estimation of lithium-ion battery using a new open-circuit voltage versus state-of-charge, Journal of Power Sources, 185, 2, pp. 1367-1373, (2008)
[2] WANG Leyi, WANG Caisheng, YIN G, Et al., Balanced control strategies for interconnected heterogeneous battery systems, IEEE Transactions on Sustainable Energy, 7, 1, pp. 189-199, (2016)
[3] CAO Jian, SCHOFIELD N, EMADI A., Battery balancing methods: A comprehensive review, 2008 IEEE Vehicle Power and Propulsion Conference, pp. 1-6, (2008)
[4] REDDY T B, LINDEN D., Linden's handbook of batteries, (2011)
[5] ZHENG Yuejiu, LI Jiaqi, ZHU Zhiwei, Et al., Rapid classification based on fast charging curves for reuse of retired lithium-ion battery modules, Power System Technology, 44, 5, pp. 1664-1672, (2020)
[6] GONG Minming, WANG Zhanguo, MA Zeyu, Et al., Design of online equilibrium system for lithium-ion battery pack, Chinese Journal of Power Sources, 40, 3, pp. 539-542, (2016)
[7] SONG Yuchen, LIU Datong, PENG Yu, Series-connected lithium-ion battery pack health modeling with cell inconsistency evaluation, 2019 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), pp. 1-6, (2019)
[8] ZHANG Xu, WANG Yujie, LIU Chang, Et al., A novel approach of remaining discharge energy prediction for large format lithium-ion battery pack, Journal of Power Sources, 343, pp. 216-225, (2017)
[9] CHENG Ze, YANG Lei, SUN Xingmian, State of charge and state of health estimation of li-ion batteries based on adaptive square-root unscented Kalman filters, Proceedings of the CSEE, 38, 8, pp. 2384-2393, (2018)
[10] WEI Haiyan, CHEN Xiaojie, LU Zhiqiang, Et al., Online estimation of lithium-ion battery state of health using grey neural network, Power System Technology, 41, 12, pp. 4038-4044, (2017)

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