Electrical‐thermal behaviors of a cylindrical graphite‐<scp>NCA Li</scp>‐ion battery responding to external short circuit operation

Dong, Ti; Wang, Yiwei; Peng, Peng; Jiang, Fangming

doi:10.1002/er.4412

Cited by 33 publications

(21 citation statements)

References 27 publications

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“…Hence, from the safety perspective, failures and accidents of ternary power batteries can frequently be reported, especially under abuse conditions consisting of overheating, mechanical collision, overcharge, and overdischarge . Within, overcharge, mainly induced by the failure of battery management system, inappropriate operation of batteries, and inconsistency of cells, is the most common trigger for power batteries failure, which would further lead to catastrophic consequences due to the eventual excessive energy input to the power battery system . Thus, it is significant and urgent to investigate the thermal‐electrical characteristics and its related issues of ternary batteries with overcharge abuse in order to improve the lifespan, safety performance, and even promotion in large‐scale applications.…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation on the essential cause of the degrading performances for an overcharging ternary battery

Zhang

et al. 2020

Int J Energy Res

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Summary Ternary power batteries, as the mainstream power sources of electric vehicles, are liable to inducing thermal runaway (TR) with respect to their sensitivity to abusive conditions. Among various abuse conditions, the overcharge of a battery has been considered as the most common and severe case giving rise to thermal safety accidents. In this study, an overcharged battery and a normal battery, both using ternary/graphite electrodes, were investigated and analyzed synergistically through thermal behaviors and electrochemical characteristics. Initially, a series of electrochemical parameters including charge and discharge voltage plateaus, discharged capacity and time at different discharge rates, and internal resistances were carried out. Then, the heat generation behaviors between normal and overcharged batteries were evaluated. Furtherly, the interconnectedness with the electrochemical capacity degradation and heat generation aggravation of the ternary battery after overcharge was analyzed. Besides, the essential causes of the deterioration of electrochemical properties and severe heat behaviors resulting from overcharge were intensively analyzed via microscopic perspectives. In addition, the electrochemical characteristics fading of abused ternary battery triggered by overcharge were investigated, especially under higher temperature (55°C) and ultralow temperature (−20°C) conditions. Therefore, for an overcharged battery, this research not only elaborates the essential causa of the degraded electrochemical and anabatic thermal performance from a materials and thermal science perspective but also provides a foundation for further promoting the safety properties of commercialized power batteries with ternary chemical systems.

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Section: Introductionmentioning

confidence: 99%

Experimental investigation on the essential cause of the degrading performances for an overcharging ternary battery

Zhang

et al. 2020

Int J Energy Res

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“…Echelon utilization is an effective way to deal with the retired batteries since it is simpler, more economical and more environmentally friendly than the chemical recycling process . Safety is the key to the reuse of retired batteries, because the organic solvents in batteries are combustible substances, which can easily lead to battery thermal runaway under various abusive conditions . Although the safety management of battery is improving continuously, battery safety accidents are reported constantly.…”

Section: Introductionmentioning

confidence: 99%

Thermal runaway behavior and features of LiFePO ₄ /graphite aged batteries under overcharge

Wang

Zhu

Gao³

et al. 2020

Int J Energy Res

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In this paper, the overcharge tests of 25 Ah LiFePO 4 /graphite batteries are conducted in an open environment and the overcharge-to-thermal-runaway characteristics are studied. The effects of current rates (C-rates: 2C, 1C, 0.5C, and 0.3C) and states of health (SOHs: 100%, 80%, 70%, and 60%) on thermal runaway features are discussed in detail. The overcharge process can be summarized into five stages based on the experimental phenomena (C-rate ≥ 1 and SOH ≥ 80%): expansion, fast venting after safety valve rupture, slow venting, intense jet smoke, and explosion, while the battery cannot explode at lower Crates and SOHs. The maximum pressure increases with the increase in C-rate or SOH. There are five obvious inflection points in the voltage curve during overcharge process. The V 1 (point B) of aged battery, corresponding to lithium plating on the anode, changes little with C-rates. It is slightly lower than that of the new battery. A sharp drop in voltage (point E) is probably due to the internal short circuit (ISC), caused by the local melting and rupture of the separator. It takes more than 2 minutes from the moment of ISC to thermal runaway regardless of the SOH, indicating that there are a few minutes to take safety measures if the voltage is an indication parameter. The onset temperature of thermal runaway decreases first and then increases as the SOH decreases from 100% to 60% during 1C constant overcharge tests. These results can provide guidance for the thermal management of the whole battery life cycle and the reuse of retired batteries. K E Y W O R D Sageing, lithium-ion battery safety, overcharge, SOH, thermal runaway

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“…The lithium‐ion battery is widely used in electrical vehicle (EV) and energy storage because of its good performance in cycle life, specific energy, and theoretical capacity. However, thermal safety issues have attracted more and more attention 1,2 . Internal short circuit (ISC) can cause thermal runaway and even lead to catastrophic.…”

Section: Introductionmentioning

confidence: 99%

Risk evaluation of internal short circuit for lithium‐ion battery based on an active protection method

Chen

Song

Lin

et al. 2022

Intl J of Energy Research

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Internal short circuit (ISC) can lead to thermal runaway and even cause fire. But the traditional passive methods cannot prevent the ISC before it occurs. The active protection method is proposed based on the evaluation of the ISC risk. An evaluation model is built based on the electrochemical model and solved with the Monte-Carlo method. Then, the model is verified with experimental data. The simulation result agrees with the experimental data of accelerated cycle life. Next, the effect of different factors on the probability of ISC risk is studied. It is found that (a) the variation trend of the probability of ISC risk with cycle number is nonlinear. The critical cycle number exists in the long-time use of the battery. (b) The probability increment of ISC risk becomes apparent when the charge rate reaches a critical value. (c) Battery temperature plays a great role in the critical cycle number. A lower temperature reduces the critical cycle number. (d) Effect of factors on the probability of ISC risk is listed as follows: charge rate > cycle number > battery temperature. With the help of the active protection method, ISC risk can be predicted before ISC occurs.

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Electrical‐thermal behaviors of a cylindrical graphite‐NCA Li‐ion battery responding to external short circuit operation

Cited by 33 publications

References 27 publications

Experimental investigation on the essential cause of the degrading performances for an overcharging ternary battery

Experimental investigation on the essential cause of the degrading performances for an overcharging ternary battery

Thermal runaway behavior and features of LiFePO ₄ /graphite aged batteries under overcharge

Risk evaluation of internal short circuit for lithium‐ion battery based on an active protection method

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Electrical‐thermal behaviors of a cylindrical graphite‐NCA Li‐ion battery responding to external short circuit operation

Cited by 33 publications

References 27 publications

Experimental investigation on the essential cause of the degrading performances for an overcharging ternary battery

Experimental investigation on the essential cause of the degrading performances for an overcharging ternary battery

Thermal runaway behavior and features of LiFePO 4 /graphite aged batteries under overcharge

Risk evaluation of internal short circuit for lithium‐ion battery based on an active protection method

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Thermal runaway behavior and features of LiFePO ₄ /graphite aged batteries under overcharge