重庆理工大学学报(自然科学) ›› 2023, Vol. 37 ›› Issue (2): 12-18.doi: 10.3969/j.issn.1674-8425(z).2023.02.002

• “先进动力电池状态估计及预测技术研究”专栏 • 上一篇    下一篇

锂电池容量衰退模型数据驱动方法研究

臧帏宏,李中华,王发成   

  1. (1.中国北方车辆研究所,北京 100072;2.陆军北京军代局,北京 100050)
  • 出版日期:2023-03-21 发布日期:2023-03-21
  • 作者简介:臧帏宏,女,硕士研究生,主要从事动力电池建模仿真与应用研究,Email:zangwei.hong@163.com;通讯作者 王 发成,男,博士,研究员,主要从事动力电池系统设计与测试评价技术研究,Email:fchwang@noveri.com.cn。

Study on different data-driven models of the lithium battery capacity-fading model

  • Online:2023-03-21 Published:2023-03-21

摘要: 电池循环寿命是动力电池的一项重要指标,多次循环之后电池的剩余容量预测成 为研究热点。以放电结束搁置期间的电压升高作为表征电池容量衰退的健康因子,再利用后向 传播算法(BP)和支持向量机(SVM)方法,建立健康因子与电池剩余容量之间映射模型。以一 种在役 42Ah三元锂电池 500余次充放电试验数据为样本,分别采用 BP和 SVM模型进行剩余 容量预测,最大预测误差分别为 1.4%、0.6%。试验结果表明:三元锂电池多次循环放电搁置 阶段的压升序列与剩余电池容量存在线性关系,可作为健康因子,运用 BP和 SVM模型可以实 现电池剩余容量精确预测,与 BP模型相比,针对小规模数据 SVM模型可以实现更高精度的有 效预测。

关键词: 三元锂电池, 容量衰退, 后向传播, 支持向量机

Abstract:

At present, the lithium-ion power battery system is the core component of new energy vehicles, and an effective battery management system can improve electrical performance and safety performance for the vehicles. It is worth mentioning that battery cycle life is an important indicator of power battery safety. Moreover, the most direct parameter to characterize battery performance degradation is the remaining capacity of a battery. Therefore, remaining capacity prediction of the battery after multiple charge-discharge cycles has become a research hotspot.

In a normal working process, the residual capacity of power batteries cannot be measured by direct testing means, so it is necessary to use battery characteristic parameters that are easy to measure to predict the residual capacity. Many scholars at home and abroad extract characteristic values from dynamic charge-discharge curves, but this method is easily affected by battery operating conditions. In order to avoid the influence of dynamic conditions, voltage increase during the resting time of the battery after the discharge period is used as a health factor to characterize the decline of battery capacity. The mapping model between health factors and battery remaining capacity is established by using backward propagation (BP) algorithm and a support vector machine (SVM).

The test data of more than 500 cycles of charge-discharge of an in-service 42 Ah ternary lithium battery are taken as samples. Among the samples, the first 400 cycles of the data are set as training samples. Then, through the subsequent 111 cycles of the data, this paper predicts the remaining capacity of the battery by using the model of the BP algorithm and the SVM respectively. The data results and the change trend of the test data in the two predicted models are the same. The MSE for the model of BP and SVM are 1.4% and 0.6% respectively.

The experiment results show that, after multiple charge-discharge cycles, there is an obvious linear relationship between the voltage rise sequence during the shelving period and the maximum remaining capacity of the ternary lithium battery. As health factors, voltage rise parameters can be a theoretical reference for the analysis of the remaining capacity of the same type of ternary lithium batteries in practical application. The BP and SVM models can be used to accurately predict the remaining capacity of batteries. Compared with the BP algorithm, the SVM algorithm has better performance when used for small-scale data, with more accurate and effective prediction.

中图分类号: 

  • TM912