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Optimization of Lithium Battery Lifetime Based on Dual-Stage Active Topology
Received date: 2022-07-21
Revised date: 2022-08-13
Accepted date: 2022-08-26
Online published: 2023-03-03
With the increasing demand for energy storage charging stations, many energy storage systems utilize lithium batteries as the major carriers. However, due to frequent charging and discharging at high power levels, the cycle life of lithium batteries is greatly reduced, which increases the energy storage costs. Given the longevity of supercapacitors, a supercapacitor-lithium hybrid energy storage system has been developed to effectively extend the lifespan of lithium batteries and reduce both investment and operational costs of energy storage charging stations. Based on the dual-stage active topology, a hybrid energy storage system combining supercapacitor-lithium is proposed. Under mild load conditions, two supercapacitor modules are alternatively charged by the lithium battery. Then, the supercapacitor modules are discharges when high power demands are encountered. Accordingly, based on working conditions of the charging pile, a multi-stage strategy, integrating state-of-power estimation and programming, is proposed to optimize the power distribution, smooth the power fluctuation of the lithium battery, and protect the lithium battery. The simulation results show that compared with the lithium batteries only energy storage and the traditional full active topology energy storage, the dual-stage active topology energy storage significantly improves the cycle life of lithium batteries.
ZHANG Cheng, JU Changjiang, XIONG Can, YANG Genke . Optimization of Lithium Battery Lifetime Based on Dual-Stage Active Topology[J]. Journal of Shanghai Jiaotong University, 2024 , 58(5) : 719 -729 . DOI: 10.16183/j.cnki.jsjtu.2022.285
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