Model and experiments to investigate thermal runaway characterization of lithium-ion batteries induced by external heating method

Jin, Changyong; Sun, Yao; Wang, Huaibin; Lai, Xin; Wang, Shuyu; Chen, Siqi; Rui, Xinyu; Zheng, Yuejiu; Feng, Xuning; Wang, Hewu; Ouyang, Minggao

doi:10.1016/j.jpowsour.2021.230065

Cited by 108 publications

(36 citation statements)

References 25 publications

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“…The model is in good experimental agreement with the results of adiabatic TR tests and oven experiments for 24 Ah LIBs. The results show that the model can respond well to the thermal runaway mechanism of the battery 170 . Abada et al developed a three‐dimensional physical model of the electrothermal behavior of LIBs under thermal runaway conditions.…”

Section: Application Of Btms In Evsmentioning

confidence: 92%

“…The results show that the model can respond well to the thermal runaway mechanism of the battery. 170 Abada et al developed a three-dimensional physical model of the electrothermal behavior of LIBs under thermal runaway conditions. The combination of experimental and modeling analysis enables an excellent understanding of the mechanisms of thermal runaway in LIBs and the implications for battery aging.…”

Section: Thermal Runaway Treatmentmentioning

confidence: 99%

See 1 more Smart Citation

A review on battery thermal management and its digital improvement‐based cyber hierarchy and interactional network

Liang

Shen

Zhang

et al. 2022

Intl J of Energy Research

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Section: Application Of Btms In Evsmentioning

confidence: 92%

Section: Thermal Runaway Treatmentmentioning

confidence: 99%

A review on battery thermal management and its digital improvement‐based cyber hierarchy and interactional network

Liang

Shen

Zhang

et al. 2022

Intl J of Energy Research

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“…7 The energy storage principle of lithium-ion batteries is also well known, as a "rocking-chair battery" because lithium ions shuttle between the positive and negative electrodes to participate in electrochemical reactions through the electrolyte for realizing energy storage and release. 8 Herein, its development is limited by the instability of the electrode/electrolyte interface. Addressing this issue depends on an in-depth understanding of the basic chemistry of the high-energy battery electrode/electrolyte interface.…”

Section: Introductionmentioning

confidence: 99%

Electrolyte additive strategy enhancing the electrochemical performance of a soft-packed LiCoO₂//graphite full cell

Xie

Feng

et al. 2022

Dalton Trans.

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“…6 However, the heat generation problem becomes severer, which causes the overheating issue, such as thermal runaway. 7 Feng et al 2 analyzed the thermal modeling of lithium-ion batteries and proposed solution perspectives for the thermal issues of battery EV applications. Fei et al 8 proposed a thermo-electrochemical model for SOC-temperature co-estimation.…”

Section: Introductionmentioning

confidence: 99%

“…Besides, novel modules/packs were designed to further enhance the energy density, such as the cell‐to‐pack (CTP) design and cell to chassis (CTC) 6 . However, the heat generation problem becomes severer, which causes the overheating issue, such as thermal runaway 7 . Feng et al 2 analyzed the thermal modeling of lithium‐ion batteries and proposed solution perspectives for the thermal issues of battery EV applications.…”

Section: Introductionmentioning

confidence: 99%

Side plate‐based cell‐to‐pack LiNi ₀ _. ₅ Co ₀ _. ₂ Mn ₀ _. ₃ O ₂
Wang
¹
,
Chen
²
,
Du
³

2021
Intl J of Energy Research
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Summary Cell‐to‐pack (CTP) NCM lithium battery cell has been widely applied in electric vehicles (EVs). However, severe heat generation issue significantly affects its safety and wide application. To analyze and solve the severe heat generation issue of large capacity CTP NCM523 (LiNi0.5Co0.2Mn0.3O2) lithium battery cell, internal temperature detection is carried out through thermocouple insertion, the peak temperature value of the internal rolled cell is proved to be about 2°C and 5°C higher than the temperature value of the external surface under 1/3 C and 1 C discharging, respectively. The relationship between the temperature rising trend and the internal resistance during the charging and discharging has also been found: with a lower state of charge level, the heat generation rate increases, and the peak temperature value occurs at the end of discharging process. Furthermore, a precise battery cell model considering the thermo‐physical properties' difference of the battery casing and the internal rolled cell is proposed based on the internal temperature measurement in simulation and numerical calculation, closer to the real heat generation and conduction condition. Finally, the thermal performance of a side plate‐based battery thermal management system is investigated through numerical calculation and simulation, the maximum temperature and temperature SD of the battery module under 1 C discharging for 3454 seconds are proved to be decreased by 0.7 K without any supplementary energy cost and coolant devices. Besides, the temperature uniformity of the battery module can be reduced to 0.51°C through the design. Internal temperature of a large capacity LiNi0.5Co0.2Mn0.3O2 Li‐ion battery cell is acquired and analyzed. Precise simulation model is constructed to analyze the heat generation and transfer considering the battery casing and the internal roll. Side plate based battery module is proposed to decrease the temperature rise by 0.7°C without supplementary energy cost coolant devices. Temperature SD of the large capacity Li‐ion battery module can be decreased within 0.51°C through the design.

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Model and experiments to investigate thermal runaway characterization of lithium-ion batteries induced by external heating method

Cited by 108 publications

References 25 publications

A review on battery thermal management and its digital improvement‐based cyber hierarchy and interactional network

A review on battery thermal management and its digital improvement‐based cyber hierarchy and interactional network

Electrolyte additive strategy enhancing the electrochemical performance of a soft-packed LiCoO₂//graphite full cell

Side plate‐based cell‐to‐pack LiNi ₀ _. ₅ Co ₀ _. ₂ Mn ₀ _. ₃ O ₂
Wang
¹
,
Chen
²
,
Du
³

2021
Intl J of Energy Research
Self Cite
14
0
4
0
View full text Add to dashboard Cite

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Model and experiments to investigate thermal runaway characterization of lithium-ion batteries induced by external heating method

Cited by 108 publications

References 25 publications

A review on battery thermal management and its digital improvement‐based cyber hierarchy and interactional network

A review on battery thermal management and its digital improvement‐based cyber hierarchy and interactional network

Electrolyte additive strategy enhancing the electrochemical performance of a soft-packed LiCoO2//graphite full cell

Side plate‐based cell‐to‐pack LiNi 0 . 5 Co 0 . 2 Mn 0 . 3 O 2Wang1, Chen2, Du3 2021Intl J of Energy ResearchSelf Cite14040View full textAdd to dashboardCite

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Electrolyte additive strategy enhancing the electrochemical performance of a soft-packed LiCoO₂//graphite full cell

Side plate‐based cell‐to‐pack LiNi ₀ _. ₅ Co ₀ _. ₂ Mn ₀ _. ₃ O ₂
Wang
¹
,
Chen
²
,
Du
³

2021
Intl J of Energy Research
Self Cite
14
0
4
0
View full text Add to dashboard Cite