Effects of Trigger Method on Fire Propagation during the Thermal Runaway Process in Li-ion Batteries

Effects of Trigger Method on Fire Propagation during the Thermal Runaway Process in Li-ion Batteries

Lithium-ion batteries are prone to fire hazards due to the possibility of thermal runaway propagation. During battery product development and subsequent safety tests for design validation and safety certification, the thermal runaway onset is triggered by various test methods such as nail penetratio...

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Veröffentlicht in:Journal of the Electrochemical Society 2024-04, Vol.171 (4), p.40514
Hauptverfasser: Mallarapu, Anudeep, Sunderlin, Nathaniel, Boovaragavan, Vijayasekaran, Tamashiro, Matthew, Peabody, Christina, Pelloux-gervais, Thibault, Li, Xin X., Sizikov, Gregory
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Sprache:eng
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battery failure
battery safety
ENERGY STORAGE
safety testing
thermal runaway initiation
thermal runaway propagation
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container_end_page
container_issue 4
container_start_page 40514
container_title Journal of the Electrochemical Society
container_volume 171
creator Mallarapu, Anudeep
Sunderlin, Nathaniel
Boovaragavan, Vijayasekaran
Tamashiro, Matthew
Peabody, Christina
Pelloux-gervais, Thibault
Li, Xin X.
Sizikov, Gregory
description Lithium-ion batteries are prone to fire hazards due to the possibility of thermal runaway propagation. During battery product development and subsequent safety tests for design validation and safety certification, the thermal runaway onset is triggered by various test methods such as nail penetration, thermal ramp, or external short circuit. This failure initiation method affects the amount of heat contributions and the composition of gas generations. This study compares two such trigger methods, external heating and using a thermally-activated internal short circuit device (ISCD). The effects of the trigger method on total heat generation are experimentally investigated within 18650 cylindrical cells at single cell level as well as at multiple cell configuration level. The severity of failure was observed to be worse for cells with ISCDs at single cell level, whereas quite the opposite results were observed at multiple cell configuration level. A preliminary numerical analysis was performed to better understand the battery safety performance with respect to thermal runaway trigger methods and heat transfer conditions.
doi_str_mv 10.1149/1945-7111/ad3aae
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subjects battery failure
battery safety
ENERGY STORAGE
safety testing
thermal runaway initiation
thermal runaway propagation
title Effects of Trigger Method on Fire Propagation during the Thermal Runaway Process in Li-ion Batteries
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