Flexible path planning-based reconfiguration strategy for maximum capacity utilization of battery pack

Maximizing the utilization of lithium-ion battery capacity is an important means to alleviate the range anxiety of electric vehicles. Battery pack inconsistency is the main limiting factor for improving battery pack capacity utilization, and poses major safety hazards to energy storage systems. To solve this problem, a maximum capacity utilization scheme based on a path planning algorithm is proposed. Specifically, the reconfigurable topology proposed is highly flexible and fault-tolerant, enabling battery pack consistency through alternating cell discharge and reducing the increased risk of short circuits due to relay error. The Dijkstra algorithm is used to find the optimal energy path, which can effectively remove faulty cells and find the current path with the best consistency of the battery pack and the lowest relay loss. Finally, the effectiveness of the scheme is verified by hardware-in-the-loop experiments, and the experimental results show that the state-of-charge SOC consistency of the battery pack at the end of discharge is increased by 34.18%, the relay energy loss is reduced by 0.16%, and the fault unit is effectively isolated.CO 2023 Science Press and Dalian Institute of Chemical Physics, Chinese Academy of Sciences. Published by ELSEVIER B.V. and Science Press. All rights reserved.

Automated summary

Maximizing the utilization of lithium-ion battery capacity is crucial for alleviating range anxiety in electric vehicles. A capacity utilization scheme based on a path planning algorithm is proposed to address the issue of battery pack inconsistency and reduce safety hazards. By using alternating cell discharge and finding the optimal energy path, the proposed scheme improves battery pack consistency and decreases relay loss.