热失控
电池(电)
弧(几何)
热的
焦耳加热
电极
失效模式及影响分析
电弧
材料科学
模式(计算机接口)
电压
焦耳(编程语言)
电气工程
汽车蓄电池
路径(计算)
核工程
表征(材料科学)
汽车工程
发热
工程类
连接(主束)
机械工程
弧长
温度测量
电子工程
电流(流体)
电气设备
作者
Zhenxing Yu,Chuan Chen,Pengfei Zhao,Yantao Qiao,Yu Cao,Binwei He,Zhimin Liu
标识
DOI:10.1038/s44172-026-00657-w
摘要
Thermal runaway-induced short-circuit arc in battery cell blocks or modules pose severe risks to electric vehicle safety; Despite this risk, however, their failure mechanisms, path and safety thresholds remain insufficiently understood. This study addresses these gaps by investigating short-circuit arc in commercial battery systems. Three short-circuit arc modes (case-to-case, case-to-busbar, and busbar-to-busbar) and corresponding failure paths were identified, with the case-to-case mode confirmed as the most hazardous. Experimental characterization reveals three phenomena during the case-to-case mode: weak Joule heating, intrinsic breakdown, and thermal breakdown with temperatures exceeding 1400 °C under 117 V and 7.2 mm, capable of triggering adjacent cell thermal runaway. A quadratic correlation between the critical breakdown voltage and electrode spacing was established, and a risk map was proposed. This study clarifies the mechanisms of thermal runaway-induced short-circuit arc, providing a quantitative safety design tool for highly integrated/high-voltage battery systems.
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