180 Ah钠离子电池热失控与产气特性分析

doi:10.19799/j.cnki.2095-4239.2025.0242

储能科学与技术 ›› 2025, Vol. 14 ›› Issue (9): 3611-3618.doi: 10.19799/j.cnki.2095-4239.2025.0242

• 储能测试与评价 • 上一篇

180 Ah钠离子电池热失控与产气特性分析

储玉喜¹^,²^,³(), 马畅¹^,²^,³, 陈红光¹^,²^,³, 张少禹¹^,²^,³, 卓萍¹^,²^,³()

^1.应急管理部天津消防研究所，天津 300381
^2.电化学能源消防安全联合创新应急管理部重点实验室，北京 102000
^3.天津市消防安全技术重点实验室，天津 300381

收稿日期:2025-03-14 修回日期:2025-03-29 出版日期:2025-09-28 发布日期:2025-09-05
通讯作者: 卓萍 E-mail:chuyuxi@tfri.com.cn;zhuoping@tfri.com.cn
作者简介:储玉喜（1986—），男，博士，副研究员，主要从事锂离子电池安全领域相关研究，E-mail： chuyuxi@tfri.com.cn；
基金资助:
应急管理部天津消防研究所中央级公益性科研院所基本科研业务费项目(2024SJ21);应急管理部重点科技计划(2024EMST111107)

Thermal runaway and gas production characteristics of a 180 Ah sodium-ion battery

Yuxi CHU¹^,²^,³(), Chang MA¹^,²^,³, Hongguang CHEN¹^,²^,³, Shaoyu ZHANG¹^,²^,³, Ping ZHUO¹^,²^,³()

^1.Tianjin Fire Research Institute of Emergency Management Department, Tianjin 300381, China
^2.Key Laboratory of Electrochemical Energy and Fire Safety Joint Innovation, Ministry of Emergency Management, Beijing 102000, China
^3.Tianjin Key Laboratory of Fire Safety Technology, Tianjin 300381, China

Received:2025-03-14 Revised:2025-03-29 Online:2025-09-28 Published:2025-09-05
Contact: Ping ZHUO E-mail:chuyuxi@tfri.com.cn;zhuoping@tfri.com.cn

摘要/Abstract

摘要：

近年来，由于材料成本低廉、无资源限制和宽温性能等优势，钠离子电池被看作锂离子电池的替代路线而发展迅速。然而，关于钠离子电池的火灾特性研究远落后于其商业化进程。本工作以方形铝壳180 Ah钠离子电池为研究对象，结合绝热加速量热仪与密闭压力容器，系统探究了绝热、外部加热及0.5C过充三种滥用条件下的热失控行为。结果表明：①电池在绝热条件下自产热温度T_onset为115.92 ℃，热失控触发温度T_tr为201.30 ℃，最高温度T_max为444.82 ℃。电池在热失控过程中的最高温升速率为2353.08 ℃/min，质量损失率为22.80%。②在加热条件下，电池热失控起始温度约为171.83 ℃，热失控最高温度为484.51 ℃，热失控后释放混合气体总量为123.25 L，主要由氢气(35.39%)、二氧化碳(30.95%)、一氧化碳(19.16%)和乙烯(4.34%)等组成，电池质量损失率为24.98%。③在0.5C过充条件下，当过充SOC达到190.84%左右时，电池发生热失控，热失控最高温度为573.60 ℃，热失控后释放混合气体总量为200.26 L，主要由二氧化碳(29.08%)、氢气(28.10%)、一氧化碳(20.79%)和乙烯(14.43%)等组成，电池质量损失率为47.96%。

关键词: 钠离子电池, 热失控, 绝热环境, 电热滥用, 产气特性

Abstract:

In recent years, sodium-ion batteries (SIBs) have emerged as promising alternatives to lithium-ion batteries, owing to their low material cost, absence of resource constraints, and broad operational temperature range. However, research on the fire safety and thermal characteristics of SIBs lags behind their commercialization. In this study, a 180 Ah square aluminum-shell SIB was selected as the research subject. Using an adiabatic accelerating calorimeter and a closed pressure vessel, thermal runaway experiments under adiabatic, overheating, and 0.5C overcharge conditions were conducted to investigate temperature, voltage, and gas generation behaviors under electro-thermal abuse. The results show that (1) under adiabatic conditions, the self-heating onset temperature (T_onset) was 115.9 ℃, the thermal runaway trigger temperature (T_tr) was 201.3 ℃, and the maximum temperature (T_max) reached 444.8 ℃. The maximum temperature rise rate during thermal runaway was 2353 ℃/min, and the mass loss was 22.8%. (2) under overheating conditions, thermal runaway started at approximately 171.8 ℃, with a T_max of 484.5 ℃. The total volume of mixed gas released after thermal runaway was 123.3 L, mainly consisting of hydrogen (35.4%), carbon dioxide (31.0%), carbon monoxide (19.2%), and ethylene (4.3%), with a mass loss of 25.0%. (3) under 0.5C overcharge conditions, thermal runaway occurred when the state of charge reached approximately 190.8%. The T_max was 573.6 ℃, and the total gas released was 200.3 L, primarily containing carbon dioxide (29.1%), hydrogen (28.1%), carbon monoxide (20.8%), and ethylene (14.4%), with a mass loss of 48.0%. These findings provide a reference for the safety design and risk assessment of high-capacity SIBs.

Key words: sodium-ion battery, thermal runaway, adiabatic environment, electro-thermal abuse, gas-generating properties

中图分类号:

TM 911

储玉喜, 马畅, 陈红光, 张少禹, 卓萍. 180 Ah钠离子电池热失控与产气特性分析[J]. 储能科学与技术, 2025, 14(9): 3611-3618.

Yuxi CHU, Chang MA, Hongguang CHEN, Shaoyu ZHANG, Ping ZHUO. Thermal runaway and gas production characteristics of a 180 Ah sodium-ion battery[J]. Energy Storage Science and Technology, 2025, 14(9): 3611-3618.

图/表 14

表1

图1

图2

表2

图3

表3

表4

图4

图5

图6

图7

图8

图9

图10

参考文献 15

[1]	陈海生, 李泓, 徐玉杰, 等. 2023年中国储能技术研究进展[J]. 储能科学与技术, 2024, 13(5): 1359-1397. DOI: 10.19799/j.cnki.2095-4239.2024.0441.
	CHEN H S, LI H, XU Y J, et al. Research progress on energy storage technologies of China in 2023[J]. Energy Storage Science and Technology, 2024, 13(5): 1359-1397. DOI: 10.19799/j.cnki.2095-4239.2024.0441.
[2]	何佳丽. 国际锂价波动对中国锂资源供需平衡的影响及对策研究[D]. 南昌: 江西财经大学, 2024. DOI: 10.27175/d.cnki.gjxcu.2024.001134.
	HE J L. Study on the impacts of international price fluctuation of lithium on China's supply-demand balance of lithium and its countermeasures[D]. Nanchang: Jiangxi University of Finance and Economics, 2024. DOI: 10.27175/d.cnki.gjxcu.2024.001134.
[3]	张平, 康利斌, 王明菊, 等. 钠离子电池储能技术及经济性分析[J]. 储能科学与技术, 2022, 11(6): 1892-1901. DOI: 10.19799/j.cnki.2095-4239.2022.0066.
	ZHANG P, KANG L B, WANG M J, et al. Technology feasibility and economic analysis of Na-ion battery energy storage[J]. Energy Storage Science and Technology, 2022, 11(6): 1892-1901. DOI: 10.19799/j.cnki.2095-4239.2022.0066.
[4]	北极星储能网. 2024钠电储能规模化应用提速!2025或迎"钠电真元年"[EB/OL]. https://news.bjx.com.cn/html/20250113/1422304.shtml.
[5]	XIAO Y, ZHU Y F, YAO H R, et al. A stable layered oxide cathode material for high-performance sodium-ion battery[J]. Advanced Energy Materials, 2019, 9(19): 1803978. DOI: 10.1002/aenm. 201803978.
[6]	WANG J Q, ZHU Y F, SU Y, et al. Routes to high-performance layered oxide cathodes for sodium-ion batteries[J]. Chemical Society Reviews, 2024, 53(8): 4230-4301. DOI: 10.1039/D3CS00929G.
[7]	HWANG S, LEE Y, JO E, et al. Investigation of thermal stability of P2-NaxCoO₂ cathode materials for sodium ion batteries using real-time electron microscopy[J]. ACS Applied Materials & Interfaces, 2017, 9(22): 18883-18888. DOI: 10.1021/acsami.7b04478.
[8]	SIRENGO K, BABU A, BRENNAN B, et al. Ionic liquid electrolytes for sodium-ion batteries to control thermal runaway[J]. Journal of Energy Chemistry, 2023, 81: 321-338. DOI: 10.1016/j.jechem.2023.02.046.
[9]	SUN Y R, ZHOU P F, LIU S Y, et al. Manipulating Na occupation and constructing protective film of P2-Na_0.67Ni_0.33Mn_0.67O₂ as long-term cycle stability cathode for sodium-ion batteries[J]. Journal of Energy Chemistry, 2024, 88: 603-611. DOI: 10.1016/j.jechem. 2023.09.042.
[10]	YUE Y B, JIA Z Z, LI Y Q, et al. Thermal runaway hazards comparison between sodium-ion and lithium-ion batteries using accelerating rate calorimetry[J]. Process Safety and Environmental Protection, 2024, 189: 61-70. DOI: 10.1016/j.psep.2024.06.032.
[11]	MEI W X, CHENG Z X, WANG L B, et al. Thermal hazard comparison and assessment of Li-ion battery and Na-ion battery[J]. Journal of Energy Chemistry, 2025, 102: 18-26. DOI: 10.1016/j.jechem.2024.10.036.
[12]	LI Z Y, CHENG Z X, YU Y, et al. Thermal runaway comparison and assessment between sodium-ion and lithium-ion batteries[J]. Process Safety and Environmental Protection, 2025, 193: 842-855. DOI: 10.1016/j.psep.2024.11.118.
[13]	FENG X N, ZHENG S Q, HE X M, et al. Time sequence map for interpreting the thermal runaway mechanism of lithium-ion batteries with LiNixCoyMnzO₂ cathode[J]. Frontiers in Energy Research, 2018, 6: 126. DOI: 10.3389/fenrg.2018.00126.
[14]	顾正建, 陶倩艺, 杨智皋, 等. 磷酸铁锂与三元锂离子电池加热下的热失控行为[J]. 电池, 2024, 54(4): 513-518. DOI: 10.19535/j.1001-1579.2024.04.015.
	GU Z J, TAO Q Y, YANG Z G, et al. Thermal runaway behavior of LiFePO₄ and ternary Li-ion batteries under heating[J]. Battery Bimonthly, 2024, 54(4): 513-518. DOI: 10.19535/j.1001-1579.2024. 04.015.
[15]	MAO B B, LIU C Q, YANG K, et al. Thermal runaway and fire behaviors of a 300 Ah lithium ion battery with LiFePO₄ as cathode[J]. Renewable and Sustainable Energy Reviews, 2021, 139: 110717. DOI: 10.1016/j.rser.2021.110717.

参数	数值
正极材料	层状氧化物
负极材料	软碳
尺寸	—
宽/mm	174±0.5
高/mm	205±0.5
厚/mm	72±0.8
标称容量/Ah	180
标称能量/Wh	540
标称电压/V	3.0
充电截止电压/V	3.85
放电截止电压/V	2.0
重量/g	4900±100
荷电状态/%	100

序号	位置
T₁	电池大面
T₂	正极侧面
T₃	负极侧面
T₄	负极片
T₅	安全阀旁

序号	位置
T₁	加热板1下
T₂	加热板2下
T₃	电池大面1
T₄	电池大面2
T₅	正极侧面
T₆	负极侧面
T₇	负极巴片
T₈	安全阀旁

序号	位置
T₁	电池大面1中心
T₂	电池大面2中心
T₃	正极侧面
T₄	负极侧面
T₅	负极巴片
T₆	安全阀旁

180 Ah钠离子电池热失控与产气特性分析

Thermal runaway and gas production characteristics of a 180 Ah sodium-ion battery

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 14

参考文献 15

相关文章 15

编辑推荐

Metrics

本文评价

[1]	陈晔, 李晋, 赵瑞兰, 张少禹, 储玉喜, 杨康, 廖晓雪, 蒋波, 卓萍. 不同荷电状态下电池模组热失控传播对比试验[J]. 储能科学与技术, 2025, 14(9): 3402-3413.
[2]	谈秀雯, 李凌. 局部过热下锂电池热失控特性及其热管理研究[J]. 储能科学与技术, 2025, 14(9): 3521-3529.
[3]	李秀春, 常永刚, 解炜, 李晓明, 陈成猛. 钠离子电池煤基炭负极可控制备：研究进展与展望[J]. 储能科学与技术, 2025, 14(9): 3373-3388.
[4]	徐成善, 李涵, 王炎, 卢兰光, 冯旭宁, 欧阳明高. 双层储能电池火蔓延特性及触发过程能量传递机制研究[J]. 储能科学与技术, 2025, 14(9): 3552-3563.
[5]	刘明轩, 陈文涛, 申韶鹏, 张世杰, 韦振, 马彪, 李丹华, 刘仕强, 王芳. 储能用锂离子电池加速老化及老化后安全特性研究[J]. 储能科学与技术, 2025, 14(9): 3530-3537.
[6]	杨斌, 杨军, 徐浪, 温浩伟, 刘登锋, 阮殿波. 电容型锂离子电池的球头压痕对其安全性研究[J]. 储能科学与技术, 2025, 14(8): 3090-3099.
[7]	向靖宇, 钟伟, 程时杰, 谢佳. 助力钠电池储能：预钠化技术研究新进展[J]. 储能科学与技术, 2025, 14(8): 3051-3064.
[8]	徐成善, 孙烨, 杨智凯, 赵明强, 李亚伦, 冯旭宁, 王贺武, 卢兰光, 欧阳明高. 储能锂离子电池系统热失控诱发电弧研究进展[J]. 储能科学与技术, 2025, 14(8): 3037-3050.
[9]	熊峰, 孔得朋, 平平, 张越, 任宪通, 吕耀. 电热耦合诱导三元锂离子电池热失控特性[J]. 储能科学与技术, 2025, 14(7): 2752-2760.
[10]	翁雯媛, 沈斌, 朱建功, 汪洋, 路华鹏, 何乌利雅苏, 刘浩男, 戴海峰, 魏学哲. 锂离子电池阳极危害性析锂原位检测综述[J]. 储能科学与技术, 2025, 14(7): 2575-2589.
[11]	张子敬, 原蓓蓓, 李红, 高颖. 锂离子电池热失控气体检测分析及预警[J]. 储能科学与技术, 2025, 14(7): 2820-2832.
[12]	刘德帅, 朱慧琴, 孙睿浩, 李蒙, 巩文豪, 李晓辉, 钱伟伟. 双添加剂协同提升钠离子电池循环稳定性[J]. 储能科学与技术, 2025, 14(5): 1858-1865.
[13]	李昱, 李丹丹, 谢飞, 唐彬, 容晓晖, 梁沁沁, 胡勇胜. 钠离子电池正极预钠化技术进展[J]. 储能科学与技术, 2025, 14(5): 1748-1757.
[14]	唐从庆, 蔡京升. 补钠技术在钠离子电池中的应用进展[J]. 储能科学与技术, 2025, 14(5): 1884-1899.
[15]	莫子鸣, 饶宗昕, 杨建飞, 杨孟昊, 蔡黎明. 锂离子电池过充热失控气热模型构建及关键参数影响分析[J]. 储能科学与技术, 2025, 14(5): 1784-1796.