Thermal-responsive, super-strong, ultrathin firewalls for quenching thermal runaway in high-energy battery modules

Lei Li; Chengshan Xu; Runze Chang; Chong Yang; Chao Jia; Li Wang; Jianan Song; Ziwei Li; Fangshu Zhang; Ben Fang; Xiaoding Wei; Huaibin Wang; Qiong Wu; Zhaofeng Chen; Xiangming He; Xuning Feng; Hui Wu; Minggao Ouyang

doi:10.1016/j.ensm.2021.05.018

Thermal-responsive, super-strong, ultrathin firewalls for quenching thermal runaway in high-energy battery modules

Lei Li, Chengshan Xu, Runze Chang, Chong Yang, Chao Jia, Li Wang, Jianan Song, Ziwei Li, Fangshu Zhang, Ben Fang, Xiaoding Wei, Huaibin Wang, Qiong Wu, Zhaofeng Chen, Xiangming He, Xuning Feng^*, Hui Wu, Minggao Ouyang

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

113 Citations (Scopus)

Abstract

Cascaded thermal runaway (TR) propagation is the utmost safety issue for large-format lithium-ion battery (LIB) modules because of the high risk of system fires or explosions. However, quenching TR without side effects still remains a challenge. Herein, we delivered an ultrathin smart firewall concept for avoiding the TR propagation in a LIB module. We demonstrate that the firewalls have thermally-triggered switchable thermal physical properties because of the synergistic effect of non-flammable phase change materials (NFPCM) and flexible silica nanofiber mats. Under TR condition, the firewalls give rise to multiple functions simultaneously, including cooling, fire extinguishing and thermal insulation. Consequently, the TR propagation between fully charged 50 Ah LIBs, with a transient thermal shock of up to 53 kW, is successfully suppressed by 1-mm-thick smart firewalls, yielding a maximum cell-to-cell temperature gap of 512 °C. The smart firewall design provides a reliable approach to quench TR propagation in large-format LIBs, which can also be suitable for other dynamically adaptive thermal-protection applications for oil tanks, space exploration, and firefighting equipment.

Original language	English
Pages (from-to)	329-336
Number of pages	8
Journal	Energy Storage Materials
Volume	40
DOIs	https://doi.org/10.1016/j.ensm.2021.05.018
Publication status	Published - Sept 2021
Externally published	Yes

Keywords

Battery safety
Energy storage
Smart firewalls
Thermal runaway

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.ensm.2021.05.018

Cite this

Li, L., Xu, C., Chang, R., Yang, C., Jia, C., Wang, L., Song, J., Li, Z., Zhang, F., Fang, B., Wei, X., Wang, H., Wu, Q., Chen, Z., He, X., Feng, X., Wu, H., & Ouyang, M. (2021). Thermal-responsive, super-strong, ultrathin firewalls for quenching thermal runaway in high-energy battery modules. Energy Storage Materials, 40, 329-336. https://doi.org/10.1016/j.ensm.2021.05.018

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abstract = "Cascaded thermal runaway (TR) propagation is the utmost safety issue for large-format lithium-ion battery (LIB) modules because of the high risk of system fires or explosions. However, quenching TR without side effects still remains a challenge. Herein, we delivered an ultrathin smart firewall concept for avoiding the TR propagation in a LIB module. We demonstrate that the firewalls have thermally-triggered switchable thermal physical properties because of the synergistic effect of non-flammable phase change materials (NFPCM) and flexible silica nanofiber mats. Under TR condition, the firewalls give rise to multiple functions simultaneously, including cooling, fire extinguishing and thermal insulation. Consequently, the TR propagation between fully charged 50 Ah LIBs, with a transient thermal shock of up to 53 kW, is successfully suppressed by 1-mm-thick smart firewalls, yielding a maximum cell-to-cell temperature gap of 512 °C. The smart firewall design provides a reliable approach to quench TR propagation in large-format LIBs, which can also be suitable for other dynamically adaptive thermal-protection applications for oil tanks, space exploration, and firefighting equipment.",

keywords = "Battery safety, Energy storage, Smart firewalls, Thermal runaway",

author = "Lei Li and Chengshan Xu and Runze Chang and Chong Yang and Chao Jia and Li Wang and Jianan Song and Ziwei Li and Fangshu Zhang and Ben Fang and Xiaoding Wei and Huaibin Wang and Qiong Wu and Zhaofeng Chen and Xiangming He and Xuning Feng and Hui Wu and Minggao Ouyang",

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doi = "10.1016/j.ensm.2021.05.018",

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T1 - Thermal-responsive, super-strong, ultrathin firewalls for quenching thermal runaway in high-energy battery modules

AU - Li, Lei

AU - Xu, Chengshan

AU - Chang, Runze

AU - Yang, Chong

AU - Jia, Chao

AU - Wang, Li

AU - Song, Jianan

AU - Li, Ziwei

AU - Zhang, Fangshu

AU - Fang, Ben

AU - Wei, Xiaoding

AU - Wang, Huaibin

AU - Wu, Qiong

AU - Chen, Zhaofeng

AU - He, Xiangming

AU - Feng, Xuning

AU - Wu, Hui

AU - Ouyang, Minggao

PY - 2021/9

Y1 - 2021/9

N2 - Cascaded thermal runaway (TR) propagation is the utmost safety issue for large-format lithium-ion battery (LIB) modules because of the high risk of system fires or explosions. However, quenching TR without side effects still remains a challenge. Herein, we delivered an ultrathin smart firewall concept for avoiding the TR propagation in a LIB module. We demonstrate that the firewalls have thermally-triggered switchable thermal physical properties because of the synergistic effect of non-flammable phase change materials (NFPCM) and flexible silica nanofiber mats. Under TR condition, the firewalls give rise to multiple functions simultaneously, including cooling, fire extinguishing and thermal insulation. Consequently, the TR propagation between fully charged 50 Ah LIBs, with a transient thermal shock of up to 53 kW, is successfully suppressed by 1-mm-thick smart firewalls, yielding a maximum cell-to-cell temperature gap of 512 °C. The smart firewall design provides a reliable approach to quench TR propagation in large-format LIBs, which can also be suitable for other dynamically adaptive thermal-protection applications for oil tanks, space exploration, and firefighting equipment.

AB - Cascaded thermal runaway (TR) propagation is the utmost safety issue for large-format lithium-ion battery (LIB) modules because of the high risk of system fires or explosions. However, quenching TR without side effects still remains a challenge. Herein, we delivered an ultrathin smart firewall concept for avoiding the TR propagation in a LIB module. We demonstrate that the firewalls have thermally-triggered switchable thermal physical properties because of the synergistic effect of non-flammable phase change materials (NFPCM) and flexible silica nanofiber mats. Under TR condition, the firewalls give rise to multiple functions simultaneously, including cooling, fire extinguishing and thermal insulation. Consequently, the TR propagation between fully charged 50 Ah LIBs, with a transient thermal shock of up to 53 kW, is successfully suppressed by 1-mm-thick smart firewalls, yielding a maximum cell-to-cell temperature gap of 512 °C. The smart firewall design provides a reliable approach to quench TR propagation in large-format LIBs, which can also be suitable for other dynamically adaptive thermal-protection applications for oil tanks, space exploration, and firefighting equipment.

KW - Battery safety

KW - Energy storage

KW - Smart firewalls

KW - Thermal runaway

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DO - 10.1016/j.ensm.2021.05.018

M3 - Article

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SN - 2405-8297

VL - 40

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EP - 336

JO - Energy Storage Materials

JF - Energy Storage Materials

ER -

Thermal-responsive, super-strong, ultrathin firewalls for quenching thermal runaway in high-energy battery modules

Abstract

Keywords

UN SDGs

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