镍0.8钴0.1铝0.1/石墨电池的性能和热稳定性与过量水的变化

IF 1.6 Q4 ENERGY & FUELS IET Energy Systems Integration Pub Date : 2024-04-04 DOI:10.1049/esi2.12148
Xi Liu, Jingbo Mao, Hongtao Yan, Chunjing Lin, Chuang Qi, Tao Yan, Li Lao, Yazhou Sun
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引用次数: 0

摘要

在锂离子电池的生产过程中,由于工厂环境对水的控制不力,会出现电池内部水分过多的情况。此外,电池外壳可能因腐蚀、外部振动等原因而损坏,从而导致水进入电池。据作者所知,很少有文献揭示与上述问题相关的影响机制。本文讨论了过量的水对电池性能和安全性的影响。结果表明,当电池吸入过量水时,容量会下降,自放电率会迅速增加。电池的自热温度呈上升趋势。热失控温度显著降低,从自热到热失控的时间大大缩短。在整个反应过程中,电池的热稳定性不断恶化。这主要是由于电池中吸收的水与电解液和电极材料发生反应的机理,导致电解液电导率下降和电极材料腐蚀,以及固体电解液界面膜增厚和杂质积累。研究结果对于证明过量水分与电池性能和安全性之间的定量关系具有积极意义。此外,它还能加深人们对电池自发失效复杂情况的理解,这对解决电池自热失控问题至关重要。
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Changes in performance and thermal stability of Ni0.8Co0.1Al0.1/graphite batteries with excessive water
During the production process of lithium‐ion batteries, there exists a scenario of excessive water inside the battery due to poor water control in the factory environment. In addition, the battery housing may be damaged by corrosion, external vibration etc., which would cause water to enter the battery. To the best of the authors’ knowledge, there is little literature to reveal the influencing mechanism related to the above issue. The effects of excessive water on battery performance and safety were discussed. The results show that when the battery absorbs excessive water, the capacity decreases and the self‐discharging rate increases rapidly. The self‐heating temperature of the battery shows an increasing trend. The thermal runaway temperature decreases significantly with the time from self‐heating to thermal runaway dramatically shortened. The thermal stability of the battery deteriorates throughout the reaction process. This is mainly due to the mechanisms by which the water absorbed in the battery reacts with the electrolyte and the electrode material, resulting in the decrease of the electrolyte conductivity and the corrosion of the electrode material, as well as the thickening of the Solid Electrolyte Interface film and the accumulation of impurities. The findings are of positive significance in demonstrating the quantitative relationship between excessive water and the performance and safety of batteries. Also, it can add to the understanding of the complex scenarios of battery spontaneous failure, which is vital for solving battery self‐thermal runaways.
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来源期刊
IET Energy Systems Integration
IET Energy Systems Integration Engineering-Engineering (miscellaneous)
CiteScore
5.90
自引率
8.30%
发文量
29
审稿时长
11 weeks
期刊最新文献
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