Influence of temperature on combustion features of lithium-ion electric bicycles in confined spaces

doi:10.16265/j.cnki.issn1003-3033.2025.03.0620

Abstract

Abstract:

To address the safety risks caused by rapid fire spread and thermal smoke accumulation in confined spaces such as basements and underground warehouses due to lithium-ion electric bicycle fires, this study combines experimental and numerical simulation methods to investigate the temperature field evolution, flame characteristics, and smoke diffusion behavior of lithium-ion electric bicycle combustion under different ambient temperatures, clarifying the effect of temperature on combustion characteristics. The results show that under experimental conditions, the average temperature at the combustion center in the confined space is approximately 600 ℃, with a peak temperature exceeding 920 ℃. Ambient temperature significantly affects the initial stage of lithium-ion electric bicycle combustion. In a 40 ℃ environment, the time for combustion to enter the rapid development phase is shortened by 20 seconds compared to 20 and 0 ℃ environments. The time required for nearby temperatures to reach the ignition point of the lithium-ion electric bicycle is reduced by approximately 25 seconds compared to 20 and 0 ℃ environments. After about 80 seconds, the temperature rise rates converge. At 20 seconds, the flame morphology of lithium-ion electric bicycle combustion differs noticeably across environments: the flame height at 40 ℃ is approximately 1.15 times that at 20 ℃ and 1.32 times that at 0 ℃. Flame morphology converges after about 80 seconds. Within the first 30 seconds, the smoke diffusion velocity and production rate in a 40 ℃ environment are significantly higher than those at 20 and 0 ℃, but smoke concentrations stabilize to similar levels after approximately 50 seconds.

Key words: lithium-ion electric bicycles, confined spaces, ambient temperature, combustion features, numerical simulation

CLC Number:

X932爆炸安全与防火、防爆

LI Qingwei, ZHU Yerui, YANG Zhixiang, LYU Ziqi, KANG Furu, REN Lifeng. Influence of temperature on combustion features of lithium-ion electric bicycles in confined spaces[J]. China Safety Science Journal, 2025, 35(3): 99-106.

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References 19

[1]	温元舒. 新国标下电动自行车地方立法实施问题研究[D]. 兰州: 兰州大学, 2023.
	WEN Yuanshu. Comparative analysis of local legislation of electric bicycle[D]. Lanzhou: Lanzhou University, 2023.
[2]	王亚利. 基于可持续理念的电动自行车充电设施设计研究[D]. 济南: 山东建筑大学, 2023.
	WANG Yali. Research on the design of electric bicycle charging facilities based on the concept of sustainability[D]. Jinan: Shandong Jianzhu University, 2023.
[3]	WANG Qingsong, MAO Binbin, STOLIAROV S I, et al. A review of lithium-ion battery failure mechanisms and fire prevention strategies[J]. Progress in Energy and Combustion Science, 2019,73:95-131.
[4]	李毅, 于东兴, 张少禹, 等. 锂离子电池火灾危险性研究[J]. 中国安全科学学报, 2012, 22(11):36-41.
	LI Yi, YU Dongxing, ZHANG Shaoyu, et al. Research on fire hazard of lithium-ion battery[J]. Journal of Safety Science and Technology, 2012, 22(11):36-41.
[5]	高飞, 杨凯, 李大贺, 等. 锂离子电池组件燃烧性及危险性评价[J]. 中国安全科学学报, 2015, 25(8):62-67.
	GAO Fei, YANG Kai, LI Dahe, et al. Evaluation of combustibility of lithium-ion battery components and dangers they involve[J]. Journal of Safety Science and Technology, 2015, 25(8):62-67.
[6]	MENG Xiangdong, LI Shi, FU Weidong, et al. Experimental study of intermittent spray cooling on suppression for lithium iron phosphate battery fires[J]. eTransportation, 2022,11: DOI: 10.1016/j.etran.2021.100141.
[7]	陈胜朋, 梁栋, 莫善军. 楼梯间电动车火灾数值模拟研究[J]. 火灾科学, 2018, 27(2): 100-106.
	CHEN Shengpeng, LIANG Dong, MO Shanjun. Numerical simulation of motorcycle fires in stairwells[J]. Fire Science, 2018, 27(2): 100-106.
[8]	潘鸣宇, 及洪泉, 邱明泉, 等. 电动汽车锂离子电池组火灾数值模拟研究[J]. 中国安全生产科学技术, 2020, 16(6): 104-109.
	PAN Mingyu, JI Hongquan, QIU Mingquan, et al. Numerical simulation study on fire of lithium-ion battery pack in electric vehicles[J]. China Safety Production Science and Technology, 2020, 16(6): 104-109.
[9]	刘得星. 车载电池包集成灭火系统关键参数仿真研究[D]. 广州: 华南理工大学, 2019.
	LIU Dexing. Simulation research on key parameters of integrated battery fire extinguishing system[D]. Guangzhou: South China University of Technology, 2019.
[10]	张青松, 曹文杰, 罗星娜, 等. 基于多米诺效应的锂离子电池热释放速率分析方法[J]. 北京航空航天大学学报, 2017, 43(5): 902-907.
	ZHANG Qingsong, CAO Wenjie, LUO Xingna, et al. Analysis method of heat release rate of lithium-ion battery based on domino effect[J]. Journal of Beihang University, 2017, 43 (5): 902-907.
[11]	张阳琳, 别传玉, 高标, 等. 三元锂电池储能性能与工作环境温度关系研究[J]. 电源技术, 2022, 46(12):1402-1406. doi: 10.3969/j.issn.1002-087X.2022.12.13
	ZHANG Yanglin, BIE Chuanyu, GAO Biao, et al. Research on relationship between energy storage performance and working temperature of ternary lithium battery[J]. Chinese Journal of Power Sources, 2022, 46(12):1402-1406. doi: 10.3969/j.issn.1002-087X.2022.12.13
[12]	王妤甜, 李剑峰, 龚宝钐, 等. 基于概率风险分析的地铁车站疏散性能评估[J]. 安全与环境学报, 2022, 22(5): 2711-2719.
	WANG Yutian, LI Jianfeng, GONG Baoshan, et al. Evacuation performance evaluation of subway stations based on probabilistic risk analysis[J]. Journal of Safety and Environment, 2022, 22(5): 2711-2719.
[13]	李大燕. 地下车库火灾蔓延规律及烟气发展过程研究[D]. 北京: 中国矿业大学, 2018.
	LI Dayan. Study on fire spread mechanisms and smoke development in underground[D]. Beijing: China University of Mining and Technology, 2018.
[14]	李晋, 王青松, 孔德明, 等. 锂离子电池储能安全评价研究进展[J]. 储能科学与技术, 2023, 12(7): 2282-2301. doi: 10.19799/j.cnki.2095-4239.2023.0252
	LI Jin, WANG Qingsong, KONG Deming, et al. Research progress on the safety assessment of lithium-ion battery energy storage[J]. Energy Storage Science and Technology, 2023, 12(7): 2282-2301. doi: 10.19799/j.cnki.2095-4239.2023.0252
[15]	肖国清, 姚泽胜, 邓洪波, 等. 基于FDS的加油站便利店火灾模拟[J]. 中国安全生产科学技术, 2018, 14(1): 143-149.
	XIAO Guoqing, YAO Zesheng, DENG Hongbo, et al. Simulation on fire in convenience store of gas station based on FDS[J]. China Safety Production Science and Technology, 2018, 14 (1): 143-149.
[16]	刘健, 王志. 轻型飞机电池舱火灾模拟研究[J]. 科技资讯, 2018, 16(3): 83-85.
	LIU Jian, WANG Zhi. Simulation study on fire in light aircraft battery cabin[J]. Science and Technology Information, 2018, 16 (3): 83-85.
[17]	李君. 电动车火灾调查与物证检测技术研究[D]. 广州: 华南理工大学, 2018.
	LI Jun. Investigation on fire evidence testing technology for electric bicycle[D]. Guangzhou: South China University of Technology, 2018.
[18]	张家荣, 赵廷元. 工程常用物质的热物理性质手册[M]. 北京: 新时代出版社, 1987:203-204.
[19]	李青蔚, 杨智翔, 邓军, 等. 电动自行车燃烧特性及简易分隔防火效果试验研究[J]. 安全与环境学报, 2023, 23(12): 4271-4278.
	LI Qingwei, YANG Zhixiang, DENG Jun, et al. Experimental study on the combustion characteristics of electric bicycles and the effect of simple separation fire[J]. Journal of Safety and Environment, 2023, 23(12): 4271-4278.

可燃物	主要材料	燃点/ ℃	氧指数/%	最大烟密度/ (mg·m^-3)
座椅	PU	205	17	99
轮胎	BR	420	38	420~630
车体塑料	PVC	180~220	17.3	<300

火源功率/ (kW·m^-2)	1.5 m平面最高温度/℃	存在问题
400	65	测点温度过低
800	200	测点温度过低
1 200	907	较符合实际情况
1 600	1 487	测点温度过高

拟合线段	拟合区域/s	拟合方程式
L₁40 ℃	[0,30)	y=0.292x+250.946
L₂40 ℃	[30,60)	y=6.828x+42.636
L₃40 ℃	[60,80]	y=24.794x-1105.230
L₁20 ℃	[0,50)	y=1.345x+196.697
L₂20 ℃	[50,80]	y=19.097x-754.053
L₁0 ℃	[0,50)	y=1.340x+161.681
L₂0 ℃	[50,80]	y=17.159x-682.176