A Fitting Method to Characterize the Gaseous Venting Behavior of Lithium–Ion Batteries in a Sealed Chamber during Thermal Runaway

Abstract: The venting event of thermal runaway has attracted public attention due to safety issues aroused by frequent fire accidents of new energy vehicles. However, the quantitative description of venting behavior is incomplete for tests in a sealed chamber due to the initial violent injection. In this study, nine types of batteries covering 28 cases in total were employed to investigate the influence of energy density, ambient temperature, pressure, and SOC on the venting behavior, characterized by normalized gas amo… Show more

“…The quantity of gas expelled, determined through the interaction of the aforementioned thermodynamic parameters, emerges as an optimal variable for characterizing the entire gas venting process. Leveraging the principles articulated in Equation ( 2) [18] regarding the ideal gas law, the quantity of gas discharged (denoted as n) can be deduced from the tested battery using the following expression:…”

Quantitative Analysis of Lithium-Ion Battery Eruption Behavior in Thermal Runaway

“…The quantity of gas expelled, determined through the interaction of the aforementioned thermodynamic parameters, emerges as an optimal variable for characterizing the entire gas venting process. Leveraging the principles articulated in Equation ( 2) [18] regarding the ideal gas law, the quantity of gas discharged (denoted as n) can be deduced from the tested battery using the following expression:…”

Quantitative Analysis of Lithium-Ion Battery Eruption Behavior in Thermal Runaway