Energy Storage Science and Technology ›› 2024, Vol. 13 ›› Issue (7): 2470-2482.doi: 10.19799/j.cnki.2095-4239.2024.0091
• Energy Storage Test: Methods and Evaluation • Previous Articles Next Articles
Guohe CHEN1,2(
), Peizhao LYU1,2, Menghan LI1,2, Zhonghao RAO1,2()
Received:2024-01-28
Revised:2024-02-08
Online:2024-07-28
Published:2024-07-23
Contact:
Zhonghao RAO
E-mail:202121301006@stu.hebut.edu.cn;raozhonghao@hebut.edu.cn
CLC Number:
Guohe CHEN, Peizhao LYU, Menghan LI, Zhonghao RAO. Research progress on thermal runaway propagation characteristics of lithium-ion batteries and its inhibiting strategies[J]. Energy Storage Science and Technology, 2024, 13(7): 2470-2482.
Fig. 1
Thermal runaway propagation paths. (a) 2 mm spacing, Heat transfer paths for heater-induced battery thermal runaway[11]; (b) Heat transfer path of a series-connected square battery module[12]; (c) Heat transfer paths in a top plate in a semi-enclosed space[14]; (d) Heat transfer paths in an enclosed space[15]"
Fig. 2
Thermal runaway triggering method"
Fig. 3
Battery connection method (a) Comparison of 10S1P and 1P10S for cylindrical batteries [21]; (b) Two types of connecting tabs in cylindrical batteries [22]; (c) Comparison of three sets of experiments with open circuit, 3P4S and 4P3S [23]; (b) Effect of parallel connection on thermal runaway[25]"
Fig. 4
Battery arrangement (a) Vertical arrangement of cylindrical batteries [26]; (b) Horizontal and vertical arrangement of square batteries [27]; (c) Arrangement of battery modules in vertical direction [28]; (d) Linear and brick arrangement of batteries[29]"
Fig. 5
Environmental factors (a) Effect of ambient pressure on the surface temperature of the battery cells; (b) thermal runaway propagation rate of the battery under open circuit; (c) thermal runaway propagation rate of the battery under parallel connection; (d) thermal runaway propagation rate of LFP and NCM523"
Fig. 6
Thermal management to suppress thermal runaway propagation (a) air cooling[35]; (b) liquid-cooled plate cooling [36]; (c) immersion cooling [37]; (d) phase change material [38]; (e) high thermal conductivity material [39]; (f) aerogel insulation[40]; (g) Combination of air-cooled and submerged liquid-cooled[42]; (h) combination between the phase change material, the aerogel and the liquid-cooled plate [41]; (i) combination of the phase change material and the aerogel [42]; (j) combination of the high thermal conductivity material and the aerogel combinations 43]"
Fig. 7
Liquid-cooled plate cooling (a) liquid-cooled plate with pin ribs[49]; (b) micro-channel liquid-cooled plate [50]; (c) serpentine-channel liquid-cooled plate[51]; and (d) wavy-shaped cooling tubes[52]"
Fig. 8
Combination of cold plate and other thermal management technology (a) Combination of aerogel and liquid-cooled plate[73]; (b) Combination of PCM and liquid-cooled plate[74]; (c) Combinations between PCM, aerogels and liquid-cooled plates; (d) Combination of PCM,aluminium plate and liquid cooling[76]"
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