用于检测健康状况不一致的串联电池组内部短路的多变量逐步算法

Hejie Lin , Jin He , Hongliang Ni , Zhenyu Yu , Yelin Deng
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引用次数: 0

摘要

电池内部短路是造成电动汽车电池系统热失控的主要原因之一。因此,防止热失控的最有效方法之一是利用电池管理系统在热失控之前检测和识别内部短路的锂离子电池。本文通过提出一种多变量逐步分析(MSA)方法来研究电池内部短路的检测和识别。MSA 方法结合了横向和纵向比较方法以及老化电池的欧姆内阻变化特征,用于检测和识别故障电池。设计了一个包含老化电池的一致性较差的电池组来进行内部短路实验。通过设置适当的阈值并水平移动窗口框,比较电池组中每个电池的欧姆内阻与正常电池平均欧姆内阻的偏差程度,可以有效识别电池组中的老化电池。健康状况(SOH)是指电池实际最大容量值的剩余百分比。SOH 为 92% 和 80% 的老化电池的欧姆内阻偏差度保持在 15% 和 45% 以上。对于等效内短路电阻为 100 Ω 的早期内短路,内短路检测时间为 3896 s;对于中后期(<10Ω)的短路,MSA 算法可在 50 s 窗口内实现快速内短路检测,降低了热失控风险。结果验证了该方法能有效识别电池组中的老化电池,并检测出其他电池的内部短路,从而减少误报,有效防止热失控。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The multi-variable stepwise algorithm for internal short circuit detection in a serial battery pack with inconsistent state of health

The multi-variable stepwise algorithm for internal short circuit detection in a serial battery pack with inconsistent state of health

Internal short circuit of cells is one of the main causes of thermal runaway in electric vehicle battery systems. Therefore, one of the most effective ways to prevent thermal runaway is to detect and identify internal short-circuit lithium-ion batteries before thermal runaway using a battery management system. This paper investigates the detection and identification of internal short circuits in batteries by proposing a multi-variable stepwise analysis (MSA) method. The MSA method is proposed for detecting and identifying faulty batteries by combining horizontal and vertical comparison methods and aging cells' ohmic internal resistance variation characteristics. A less consistent pack containing aging cells was designed to perform internal short-circuit experiments. Based on setting the appropriate threshold and moving the window frame horizontally, comparing the deviation degree of the ohmic internal resistance of each cell in the battery pack and the average ohmic internal resistance of the normal battery, the aging battery in the battery pack can be effectively identified. State of health (SOH) is the percentage remaining of the battery's actual maximum capacity value. The deviation degree of ohmic internal resistance of aging batteries with SOH of 92% and 80% is maintained at more than 15% and 45%. For early internal shorts with an equivalent internal short-circuit resistance of 100 Ω, the internal short-circuit detection time is 3896 s. For the short circuit in the middle and later periods (<10Ω), the MSA algorithm can achieve rapid internal short-circuit detection within the 50 s window, reducing the risk of thermal runaway. The results verified that the method could effectively identify aging cells within the battery pack and detect internal short circuits for other cells, reducing false positives and effectively preventing thermal runaway.

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