Advances in thermal management systems for next-generation power batteries

lThe critical thermal issues of lithium-ion batteries are introduced.lThe design principles for batteries thermal management are presented.lThe latest advances on battery thermal management systems are summarized.lEmerging technologies for next-generation power batteries are discussed. Replacing con...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2021-12, Vol.181, p.121853, Article 121853
Main Authors: Yue, Q.L., He, C.X., Wu, M.C., Zhao, T.S.
Format: Article
Language:English
Subjects:
Automobiles
Battery thermal management
Electric vehicle
Electric vehicles
Emerging technology
Fossil fuels
Heat transfer
Heating
High temperature
Lithium
Lithium-ion batteries
Low temperature
Management systems
New technology
Nonuniformity
Operating temperature
Phase change material
Power management
Power sources
Rechargeable batteries
Temperature
Thermal management
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Summary:lThe critical thermal issues of lithium-ion batteries are introduced.lThe design principles for batteries thermal management are presented.lThe latest advances on battery thermal management systems are summarized.lEmerging technologies for next-generation power batteries are discussed. Replacing conventional gasoline-powered cars with electric vehicles (EVs) can reduce not only pollution emissions but also the dependence on fossil fuels. As the most widely used power source to propel EVs, lithium-ion batteries are highly sensitive to the operating temperatures, rendering battery thermal management indispensable to ensure their high performance, long cycle life and safe operation. In this review, we summarize the recent advances in thermal management for lithium-ion batteries. The critical thermal issues caused by high temperature, low temperature and temperature non-uniformity are firstly discussed. The design principles and the existing thermal management systems are then presented and elaborated extensively. Emerging technologies such as thermoelectric devices and internal heating methods for future battery thermal management are analyzed. We highlight that the combination of passive and active cooling/heating methods is promising to meet the stringent thermal requirements, particularly under dynamic conditions with drastic power fluctuations. Finally, the remaining challenges and perspectives of thermal management systems with high efficiency and durability are provided. This review offers comprehensive guidance on the design of advanced thermal management system for next-generation power batteries.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2021.121853