三元锂离子电池过放电循环后性能及热稳定性试验

doi:10.16265/j.cnki.issn1003-3033.2026.04.1484

摘要/Abstract

摘要：

为提升锂离子电池长期使用的稳定性和安全性,开展过放电导致的潜在安全隐患研究。针对锂离子电池在新能源电动汽车、电化学储能等实际应用中可能面临的过放电-再次充电现象,以三元锂离子电池为对象,通过循环及混合功率脉冲特性测试(HPPC),利用绝热加速量热仪测试电池热失控,分析过放电-再次充电循环对电池放电容量(DC)、直流内阻、容量增量等电特性参数,以及对绝热条件下热失控特征参数的影响。结果表明:过放电循环会加速电池容量衰减和内阻增加,低荷电状态区域的放电直流内阻增加尤为显著,但在短期循环内长时间搁置电池,电池容量具有一定的恢复能力;过放电循环电池的热稳定性降低,自产热温度降低,热失控时间相较于新鲜电池和正常循环电池提前,但热失控最大温度相对较低。

关键词: 锂离子电池, 过放电循环, 热稳定性, 放电容量(DC), 热失控

Abstract:

To enhance the long-term stability and safety of lithium-ion batteries, a study on potential safety hazards caused by over-discharge was conducted. Aiming at the over-discharge/recharge phenomenon that the lithium-ion batteries may encounter in practical applications such as new energy electric vehicles and electrochemical energy storage, ternary lithium-ion batteries were examined. Through cycle tests and Hybrid Pulse Power Characteristic(HPPC) tests, adiabatic accelerating rate calorimetry was employed to investigate thermal runaway. The effects of over-discharge/recharge cycles on electrical characteristics—such as discharge capacity, DC internal resistance, and incremental capacity—as well as on the thermal runaway characteristic parameters under adiabatic conditions, were analyzed. The results show that over-discharge cycling accelerates battery capacity decay and increases internal resistance, with a particularly notable rise in DC internal resistance in the low state-of-charge region. However, after short-term cycling, prolonged resting allows partial capacity recovery. Over-discharge cycles also reduce the thermal stability of batteries, lower the self-heating onset temperature, and shorten the thermal runaway time compared to fresh batteries and normally cycled batteries, although the maximum thermal runaway temperature is relatively lower.

Key words: lithium-ion batteries, over-discharge cycles, thermal stability, discharge capacity(DC), thermal runaway

中图分类号:

X946

马迷娜, 张宸宇, 张艳辉, 陈明明, 刘梦饶, 王青松. 三元锂离子电池过放电循环后性能及热稳定性试验[J]. 中国安全科学学报, 2026, 36(4): 160-167.

Ma Mi'na, Zhang Chenyu, Zhang Yanhui, Chen Mingming, Liu Mengrao, Wang Qingsong. Experiment on performance and thermal stability of ternary lithium-ion batteries after over-discharge cycles[J]. China Safety Science Journal, 2026, 36(4): 160-167.

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参数	数值或特性
化学体系	LiNi_0.5Co_0.2Mn_0.3O₂正极, 石墨负极,陶瓷隔膜
额定容量/Ah	25
标称电压/V	3.6
充电截止电压/V	4.2
放电截止电压/V	2.75
最大充电电流/C	1
最大放电电流/C	3
工作环境	充电: 0~ +45 ℃,湿度≤85% 放电: -20 ~ +60 ℃,湿度≤85%
电池尺寸/ (mm×mm×mm)	长×宽×高:134×9.2×201