Effect of thermal insulation material layout on thermal runaway propagation inhibition effect of 280 Ah lithium-iron phosphate battery

doi:10.19799/j.cnki.2095-4239.2023.0535

Abstract

Abstract:

The thermal runaway propagation (TRP) of Li-ion batteries poses a substantial fire and explosion risks, preventing their further widespread application. Herein, glass fiber aerogel and ceramic fiber mats are used to suppress the TRP in batteries, exploring the influence of the type and thickness of the insulation material on the suppression effect. Two module layout methods are designed: single barrier and spacer barrier modules. The former involves placing a piece of insulation material in every other battery, while the latter involves placing a piece of insulation material in every two batteries. Research results show that in a single barrier module, glass fiber aerogels with a thickness of 2 and 1 mm can effectively prevent TRP, and the temperature rises of the front and back surfaces of the protected battery are 193.6℃, 86.1 ℃, and 222.6 ℃, 86.8 ℃, respectively. However, a 2 mm-thick ceramic fiber felt can only delay the speed of TRP butnot completely prevent it. In the spacer barrier module, using a 2 mm glass fiber aerogel as a barrier results in a temperature rise of 168.3 ℃ and 56 ℃ on the front and back surfaces of the protected battery, demonstrating that the spacer barrier module offers an enhanced protective effect on the battery under abuse conditions. To a certain extent, the results of this study alleviate the contradiction between the use of thermal insulation materials and the energy density of modules. The findings hold important theoretical guidance for the safety design of lithium-ion battery modules.

Key words: lithium-ion battery, thermal runaway propagation, prevent, thermal insulation material, layout mode

CLC Number:

TM 911

Qikai LEI, Yin YU, Peng PENG, Man CHEN, Kaiqiang JIN, Qingsong WANG. Effect of thermal insulation material layout on thermal runaway propagation inhibition effect of 280 Ah lithium-iron phosphate battery[J]. Energy Storage Science and Technology, 2024, 13(2): 495-502.

Figures/Tables 9

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References 16

1	FENG X N, ZHENG S Q, REN D S, et al. Investigating the thermal runaway mechanisms of lithium-ion batteries based on thermal analysis database[J]. Applied Energy, 2019, 246: 53-64.
2	ZHANG Q S, LIU T T, WANG Q. Experimental study on the influence of different heating methods on thermal runaway of lithium-ion battery[J]. Journal of Energy Storage, 2021, 42: 103063.
3	MAO B B, CHEN H D, CUI Z X, et al. Failure mechanism of the lithium ion battery during nail penetration[J]. International Journal of Heat and Mass Transfer, 2018, 122: 1103-1115.
4	FENG X N, OUYANG M G, LIU X, et al. Thermal runaway mechanism of lithium ion battery for electric vehicles: A review[J]. Energy Storage Materials, 2018, 10: 246-267.
5	REN D S, FENG X N, LIU L S, et al. Investigating the relationship between internal short circuit and thermal runaway of lithium-ion batteries under thermal abuse condition[J]. Energy Storage Materials, 2021, 34: 563-573.
6	Feng X N, Zheng S Q, Ren D S, et al. Key characteristics for thermal runaway of Li-ion batteries[J]. Energy Procedia. 2019, 158: 4684-4689.
7	YU Y, HUANG Z H, MEI W X, et al. Preventing effect of different interstitial materials on thermal runaway propagation of large-format lithium iron phosphate battery module[J]. Journal of Energy Storage, 2023, 63: 107082.
8	MAO B B, HUANG P F, CHEN H D, et al. Self-heating reaction and thermal runaway criticality of the lithium ion battery[J]. International Journal of Heat and Mass Transfer, 2020, 149: 119178.
9	WU T Q, CHEN H D, WANG Q S, et al. Comparison analysis on the thermal runaway of lithium-ion battery under two heating modes[J]. Journal of Hazardous Materials, 2018, 344: 733-741.
10	WILKE S, SCHWEITZER B, KHATEEB S, et al. Preventing thermal runaway propagation in lithium ion battery packs using a phase change composite material: An experimental study[J]. Journal of Power Sources, 2017, 340: 51-59.
11	ZHAO C R, CAO W J, DONG T, et al. Thermal behavior study of discharging/charging cylindrical lithium-ion battery module cooled by channeled liquid flow[J]. International Journal of Heat and Mass Transfer, 2018, 120: 751-762.
12	KSHETRIMAYUM K S, YOON Y G, GYE H R, et al. Preventing heat propagation and thermal runaway in electric vehicle battery modules using integrated PCM and micro-channel plate cooling system[J]. Applied Thermal Engineering, 2019, 159: 113797.
13	ZHANG L, DUAN Q L, XU J J, et al. Experimental investigation on suppression of thermal runaway propagation of lithium-ion battery by intermittent spray[J]. Journal of Energy Storage, 2023, 58: 106434.
14	NIU H C, CHEN C X, LIU Y H, et al. Mitigating thermal runaway propagation of NCM 811 prismatic batteries via hollow glass microspheres plates[J]. SSRN Electronic Journal, 2021, 162: 672-683.
15	YANG X L, DUAN Y K, FENG X N, et al. An experimental study on preventing thermal runaway propagation in lithium-ion battery module using aerogel and liquid cooling plate together[J]. Fire Technology, 2020, 56(6): 2579-2602.
16	WANG Y, WANG F F, ZHAO L Y, et al. Shape-stable and fire-resistant hybrid phase change materials with enhanced thermoconductivity for battery cooling[J]. Chemical Engineering Journal, 2022, 431: 133983.

实验分组	实验编号	隔热材料	材料厚度 /mm	说明
空白	1	—	—	对照实验
单块阻隔	2	玻纤气凝胶	2	探究不同隔热材料对热失控传播抑制效果的影响
	3	陶瓷纤维棉	2	探究不同隔热材料对热失控传播抑制效果的影响
	4	玻纤气凝胶	1	与实验2对比，探究隔热材料的厚度对热失控传播抑制效果的影响
间隔阻隔	5	玻纤气凝胶	2	与实验2对比，探究隔热材料布局方式对热失控传播抑制效果的影响

时间节点	电池-1	电池-2	电池-3
安全阀门打开时间/s	2814	3382	4154
热失控时间/s	2956	3617	4413

实验编号	隔热方式	ΔT_n,f/℃	ΔT_n,b/℃
1	无	TR	TR
2	2 mm玻纤气凝胶单块阻隔	193.6	86.1
3	2 mm陶瓷纤维棉单块阻隔	TR	TR
4	1 mm玻纤气凝胶单块阻隔	222.6	86.8
5	2 mm玻纤气凝胶间隔阻隔	168.3	56.0

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