The Impact of a Combined Battery Thermal Management and Safety System Utilizing Polymer Mini-Channel Cold Plates on the Thermal Runaway and Its Propagation

Graichen, Henrik-Christian; Boye, Gunar; Sauerhering, Jörg; Köhler, Florian; Beyrau, Frank

doi:10.3390/batteries10010001

Batteries

2023

DOI: 10.3390/batteries10010001

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The Impact of a Combined Battery Thermal Management and Safety System Utilizing Polymer Mini-Channel Cold Plates on the Thermal Runaway and Its Propagation

Henrik-Christian Graichen,

Gunar Boye,

Jörg Sauerhering

et al.

Abstract: Lithium-ion batteries are widely used in mobile applications because they offer a suitable package of characteristics in terms of specific energy, cost, and life span. Nevertheless, they have the potential to experience thermal runaway (TR), the prevention and containment of which require safety measures and intensive thermal management. This study introduces a novel combined thermal management and safety application designed for large aspect-ratio battery cells such as pouches and thin prismatics. It comprise… Show more

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2024

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Cited by 2 publications

References 111 publications

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Optimization and analysis of battery thermal management system structure based on flat heat pipes and biomimetic fins

Liu,

Xiong,

2024

Heliyon

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Optimization and analysis of battery thermal management system structure based on flat heat pipes and biomimetic fins

Liu,

Xiong,

2024

Heliyon

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An Experimental Study on the Thermal Runaway Propagation of Cycling Aged Lithium-Ion Battery Modules

Han,

Zhao,

Zhao

et al. 2024

Fire

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The primary concerns for individuals using lithium-ion batteries (LIBs) are aging and thermal runaway (TR). This paper focuses on the thermal runaway propagation (TRP) of cycling aged LIB modules. The impacts of state of charge (SOC), state of health, and cyclic aging temperature on TRP in LIB modules are investigated. The analysis includes parameters such as temperature, voltage, and mass of the modules during TRP. It was found that as SOC increases, the maximum increase in temperature and maximum temperature rate of the modules increased, as did the total mass loss and smoke emissions. The average heat transfer between adjacent cells was higher for the lower SOC. Cycle aging reduces the thermal stability of LIBs, leading to a lower maximum temperature and maximum temperature rate, as well as a larger mass loss compared with fresh battery modules. Regarding aging temperature, low-temperature aging reduces the total duration of TRP compared with room temperature, but it increases the maximum temperature rate and causes greater mass loss. Aging also increases the average heat transfer between adjacent cells.

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The Impact of a Combined Battery Thermal Management and Safety System Utilizing Polymer Mini-Channel Cold Plates on the Thermal Runaway and Its Propagation

Cited by 2 publications

References 111 publications

Optimization and analysis of battery thermal management system structure based on flat heat pipes and biomimetic fins

Optimization and analysis of battery thermal management system structure based on flat heat pipes and biomimetic fins

An Experimental Study on the Thermal Runaway Propagation of Cycling Aged Lithium-Ion Battery Modules

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