基于径向基神经网络退役锂电池分选研究

doi:10.16180/j.cnki.issn1007-7820.2021.02.007

摘要/Abstract

摘要：

随着电动汽车关键零部件锂电池的寿命逐步到期,对退役锂电池梯次利用的研究愈发重要,其中对退役锂电池的分选技术是该领域的一大难点。传统的分选方法需要对单个电池进行逐个测试从而完成分选,但此方法不适于大批量电池快速分选。为了提高对退役动力电池的分选速度,文中采用了均衡-充电分选法。该方法对待分选的电池进行并联均衡,待电压一致后进行串联恒流充电;然后根据老化程度不同电池具有不同电压曲线的特点,结合径向基神经网络的非线性函数逼近能力;通过模型训练,实现电池容量估计,从而完成电池分选。仿真验证显示新方法容量误差不超过±5%,容量误差不超过±3%,表明文中所提方法可以实现对退役锂电池的分选。

关键词: 退役锂离子电池, 快速分选, 并联均衡, 恒流充电, 径向基神经网络, 容量估计

Abstract:

With the aging of lithium-ion batteries of electric vehicles in the near future, research on the second use of retired LIBs has become more and more critical. However, the classification method of the retired LIBs is challenging before the second use due to large cell variations. The traditional sorting method requires a single battery to be tested one by one to complete the sorting, but this method is not suitable for rapid sorting of large-scale batteries. In order to improve the sorting speed of the retired battery, the equalization-charging sorting method is proposed in this study. The batteries to be sorted are parallel-balanced, and the constant current charging is performed after the voltage is consistent. According to the characteristics of different aging batteries with different voltage curves, combined with the non-linear function approximation capability of radial basis function neural network, battery capacity estimation are realized through model training, thereby completing battery sorting. The results of the simulation verification reveale that the capacity error doesnot exceed ±5%, and the results of the experimental verification show the capacity error is within ±3%, which indicates the proposed method can achieve the sorting of retired lithium batteries.

Key words: retired lithium-ion battery, rapid classification, parallel equalization, constant current charging, radial basis function neural network, capacity estimation

中图分类号:

TP391.9

何忠霖,周萍. 基于径向基神经网络退役锂电池分选研究[J]. 电子科技, 2021, 34(2): 38-44.

HE Zhonglin,ZHOU Ping. Research on Sorting of Retired Lithium Battery Based on Radial Basis Function Neural Network[J]. Electronic Science and Technology, 2021, 34(2): 38-44.

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项目	性能指标	项目	性能指标
额定容量	32.5 Ah	推荐充电电流	11 A (1/3C)
额定工作电压	3.75 V	推荐放电电流	11 A (1/3C)
最大充电电流	65 A (2C)	充电截止电压	4.15 V
大放电电流	65 A (2C)	放电截止电压	2.5 V
保存温度范围	-40~70 ℃	使用温度范围	-25~60 ℃

Cell	1	2	3	4	5
U_o/V	3.497 6	3.497 6	3.505 1	3.514 5	3.505 7
容量/Ah	28.869 6	28.908 8	29.406 9	27.202 1	28.167 2
Cell	6	7	8	9	10
U_o/V	3.515 9	3.541 6	3.504 5	3.501 9	3.510 3
容量/Ah	28.047 8	23.283 4	27.991 9	29.219 3	27.217 2
Cell	11	12	13	14	15
U_o/V	3.474 5	3.503 3	3.502 0	3.501 4	3.502 7
容量/Ah	31.528 9	28.949 3	29.020 5	28.746 9	28.255 1