Battery thermal management system (BTMS) is a complex and highly integrated system, which is used to control the battery thermal conditions in electric vehicles (EVs). The BTMS consists of many subsystems that belong to different disciplines, which poses challenges to BTMS optimization using conventional methods. This paper develops a general variable fidelity-based multidisciplinary design optimization (MDO) architecture and optimizes the BTMS by considering different systems/disciplines from the systemic perspective. Four subsystems and/or subdisciplines are modeled, including the battery thermodynamics, fluid dynamics, structure, and lifetime model. To perform the variable fidelity-based MDO of the BTMS, two computational fluid dynamics (CFD) models with different levels of fidelity are developed. A low fidelity surrogate model and a tuned low fidelity model are also developed using an automatic surrogate model selection method, the concurrent surrogate model selection (COSMOS). An adaptive model switching (AMS) method is utilized to realize the adaptive switch between variable-fidelity models. The objectives are to maximize the battery lifetime and to minimize the battery volume, the fan's power, and the temperature difference among different cells. The results show that the variable-fidelity MDO can balance the characteristics of the low fidelity mathematical models and the computationally expensive simulations, and find the optimal solutions efficiently and accurately.
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September 2018
Technical Briefs
Multidisciplinary and Multifidelity Design Optimization of Electric Vehicle Battery Thermal Management System
Xiaobang Wang,
Xiaobang Wang
School of Mechanical Engineering,
Dalian University of Technology,
Dalian 116024, LN, China;
Dalian University of Technology,
Dalian 116024, LN, China;
Department of Mechanical Engineering,
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: wxbang@mail.dlut.edu.cn
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: wxbang@mail.dlut.edu.cn
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Yuanzhi Liu,
Yuanzhi Liu
Department of Mechanical Engineering,
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: yuanzhi.liu@utdallas.edu
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: yuanzhi.liu@utdallas.edu
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Wei Sun,
Wei Sun
School of Mechanical Engineering,
Dalian University of Technology,
Dalian 116024, LN, China
e-mail: sunwei@dlut.edu.cn
Dalian University of Technology,
Dalian 116024, LN, China
e-mail: sunwei@dlut.edu.cn
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Xueguan Song,
Xueguan Song
School of Mechanical Engineering,
Dalian University of Technology Dalian,
Dalian 116024, LN, China
e-mail: sxg@dlut.edu.cn
Dalian University of Technology Dalian,
Dalian 116024, LN, China
e-mail: sxg@dlut.edu.cn
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Jie Zhang
Jie Zhang
Department of Mechanical Engineering,
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: jiezhang@utdallas.edu
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: jiezhang@utdallas.edu
Search for other works by this author on:
Xiaobang Wang
School of Mechanical Engineering,
Dalian University of Technology,
Dalian 116024, LN, China;
Dalian University of Technology,
Dalian 116024, LN, China;
Department of Mechanical Engineering,
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: wxbang@mail.dlut.edu.cn
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: wxbang@mail.dlut.edu.cn
Yuanzhi Liu
Department of Mechanical Engineering,
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: yuanzhi.liu@utdallas.edu
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: yuanzhi.liu@utdallas.edu
Wei Sun
School of Mechanical Engineering,
Dalian University of Technology,
Dalian 116024, LN, China
e-mail: sunwei@dlut.edu.cn
Dalian University of Technology,
Dalian 116024, LN, China
e-mail: sunwei@dlut.edu.cn
Xueguan Song
School of Mechanical Engineering,
Dalian University of Technology Dalian,
Dalian 116024, LN, China
e-mail: sxg@dlut.edu.cn
Dalian University of Technology Dalian,
Dalian 116024, LN, China
e-mail: sxg@dlut.edu.cn
Jie Zhang
Department of Mechanical Engineering,
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: jiezhang@utdallas.edu
The University of Texas at Dallas,
Richardson, TX 75080
e-mail: jiezhang@utdallas.edu
1Corresponding author.
Contributed by the Design Automation Committee of ASME for publication in the JOURNAL OF MECHANICAL DESIGN. Manuscript received August 19, 2017; final manuscript received May 24, 2018; published online June 22, 2018. Assoc. Editor: Gary Wang.
J. Mech. Des. Sep 2018, 140(9): 094501 (8 pages)
Published Online: June 22, 2018
Article history
Received:
August 19, 2017
Revised:
May 24, 2018
Citation
Wang, X., Liu, Y., Sun, W., Song, X., and Zhang, J. (June 22, 2018). "Multidisciplinary and Multifidelity Design Optimization of Electric Vehicle Battery Thermal Management System." ASME. J. Mech. Des. September 2018; 140(9): 094501. https://doi.org/10.1115/1.4040484
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