Electric vehicles have become a trend in recent years, and the lithium-ion battery pack provides them with high power and energy. The battery thermal system with air cooling was always used to prevent the high temperature of the battery pack to avoid cycle life reduction and safety issues of lithium-ion batteries. This work employed an easily applied optimization method to design a more efficient battery pack with lower temperature and more uniform temperature distribution. The proposed method consisted of four steps: the air-cooling system design, computational fluid dynamics code setups, selection of surrogate models, and optimization of the battery pack. The investigated battery pack contained eight prismatic cells, and the cells were discharged under normal driving conditions. It was shown that the optimized design performs a lower maximum temperature of 2.7 K reduction and a smaller temperature standard deviation of 0.3 K reduction than the original design. This methodology can also be implemented in industries where the battery pack contains more battery cells.
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November 2019
Research-Article
Temperature Distribution Optimization of an Air-Cooling Lithium-Ion Battery Pack in Electric Vehicles Based on the Response Surface Method
Xiangping Liao,
Xiangping Liao
College of Mechanical Engineering,
Hunan University of Humanities,
Science and Technology,
Loudi City 417000, China;
College of Electrical and Mechanical Engineering,
Changsha City 410083,
e-mail: 520joff@163.com
Hunan University of Humanities,
Science and Technology,
Loudi City 417000, China;
College of Electrical and Mechanical Engineering,
Central South University
,Changsha City 410083,
China
e-mail: 520joff@163.com
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Chong Ma,
Chong Ma
Intelligent Manufacturing Key Laboratory of Ministry of Education,
Shantou City 515063,
e-mail: 17cma@stu.edu.cn
Shantou University
,Shantou City 515063,
China
e-mail: 17cma@stu.edu.cn
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Xiongbin Peng,
Xiongbin Peng
2
Intelligent Manufacturing Key Laboratory of Ministry of Education,
Shantou City 515063,
e-mail: xbpeng@stu.edu.cn
Shantou University
,Shantou City 515063,
China
e-mail: xbpeng@stu.edu.cn
2Corresponding author.
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Akhil Garg,
Akhil Garg
Intelligent Manufacturing Key Laboratory of Ministry of Education,
Shantou City 515063,
e-mail: akhil@stu.edu.cn
Shantou University
,Shantou City 515063,
China
e-mail: akhil@stu.edu.cn
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Nengsheng Bao
Nengsheng Bao
Intelligent Manufacturing Key Laboratory of Ministry of Education,
Shantou City 515063,
e-mail: nsbao@stu.edu.cn
Shantou University
,Shantou City 515063,
China
e-mail: nsbao@stu.edu.cn
Search for other works by this author on:
Xiangping Liao
College of Mechanical Engineering,
Hunan University of Humanities,
Science and Technology,
Loudi City 417000, China;
College of Electrical and Mechanical Engineering,
Changsha City 410083,
e-mail: 520joff@163.com
Hunan University of Humanities,
Science and Technology,
Loudi City 417000, China;
College of Electrical and Mechanical Engineering,
Central South University
,Changsha City 410083,
China
e-mail: 520joff@163.com
Chong Ma
Intelligent Manufacturing Key Laboratory of Ministry of Education,
Shantou City 515063,
e-mail: 17cma@stu.edu.cn
Shantou University
,Shantou City 515063,
China
e-mail: 17cma@stu.edu.cn
Xiongbin Peng
Intelligent Manufacturing Key Laboratory of Ministry of Education,
Shantou City 515063,
e-mail: xbpeng@stu.edu.cn
Shantou University
,Shantou City 515063,
China
e-mail: xbpeng@stu.edu.cn
Akhil Garg
Intelligent Manufacturing Key Laboratory of Ministry of Education,
Shantou City 515063,
e-mail: akhil@stu.edu.cn
Shantou University
,Shantou City 515063,
China
e-mail: akhil@stu.edu.cn
Nengsheng Bao
Intelligent Manufacturing Key Laboratory of Ministry of Education,
Shantou City 515063,
e-mail: nsbao@stu.edu.cn
Shantou University
,Shantou City 515063,
China
e-mail: nsbao@stu.edu.cn
2Corresponding author.
1
These authors contributed equally to the paper.
Manuscript received October 28, 2018; final manuscript received February 4, 2019; published online March 12, 2019. Assoc. Editor: Ankur Jain.
J. Electrochem. En. Conv. Stor. Nov 2019, 16(4): 041002 (8 pages)
Published Online: March 12, 2019
Article history
Received:
October 28, 2018
Revision Received:
February 4, 2019
Accepted:
February 5, 2019
Citation
Liao, X., Ma, C., Peng, X., Garg, A., and Bao, N. (March 12, 2019). "Temperature Distribution Optimization of an Air-Cooling Lithium-Ion Battery Pack in Electric Vehicles Based on the Response Surface Method." ASME. J. Electrochem. En. Conv. Stor. November 2019; 16(4): 041002. https://doi.org/10.1115/1.4042922
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