Thermal runaway and its propagation within lithium-ion battery systems pose significant
challenges to widespread adoption in electric vehicles and energy storage systems …

Owing to the complexity of coupling mechanical and electrical solvers for finite element
analysis (FEA) of mechanical abuse of a battery, the simulation should be performed by …

Abstract Lithium-ion (Li-ion) cells are the optimal choice of energy storage for battery electric
vehicles. As the Li-ion cells must operate in a temperature range of 15–45° C for optimal …

This study investigates the thermal management of a battery module of an electric vehicle for
the recovery of waste heat. In the evaluation of this waste heat, a two-phase flow system is …

As large systems of Li-ion batteries are being increasingly deployed, the safety of such
systems must be assessed. Due to the high cost of testing large systems, it is important to …

This study examines the impact of applying pressure on phase change material (PCM)
cooling performance on the maximum temperature (MT) and maximum temperature …

Reliable and accurate simulations of the thermal runaway of Li-ion batteries are crucial for
designing thermal management system. However, the stiff nature of thermal abuse kinetics …

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 …

Considerable advances have been made in battery safety models, but achieving predictive
accuracy across a wide range of conditions continues to be challenging. Interactions …

Solid-solid phase change materials (SSPCMs) are potential materials for energy storage
and thermal management, and improving mechanical property and heat transfer …