车用功率模块液冷板多目标拓扑优化设计研究

doi:10.19562/j.chinasae.qcgc.2025.02.013

Abstract

Abstract:

With the increasing power levels and integration of electric vehicles， the thermal load of power modules is rising rapidly， which puts higher demand on the thermal management technology of power modules. The topology optimization design of power module liquid cooled plates is becoming a key technology for achieving high heat flux density heat dissipation due to its high heat transfer and low-pressure drop loss characteristics. In this paper， based on the density topology method， a topology optimization design model is constructed for the flow channel structure of the power module liquid cooling plate. Through the coupling of multiple physical fields of flow and heat transfer； multi-objective topology optimization design for the flow channel of the liquid cooling plate is carried out. The results show that the topology-optimized liquid cooling plate design presents a multi-level biomimetic flow channel structure， which significantly reduces pressure drop loss and improves heat dissipation capacity. Compared to the traditional finned liquid cooling plate structure of the benchmark， the pressure drop loss of the flow channel structure after topology optimization is reduced by 72.8% ， with a maximum temperature reduction of 33.28 K， which provides a new design idea for high-performance liquid cooling plates of automotive electronic control power modules.

Key words: power module, cold-plate, multi-objective, topology optimization

Heping Ling,Jiapei Yang,Hanzhi Wang,Haijun Liu,Bin He. Research on Multi-objective Topology Optimization Design of the Power Module Cold-Plate for the Electric Vehicles[J].Automotive Engineering, 2025, 47(2): 326-331.

Figures/Tables 9

材料

密度

$ρ$ /（kg·m^-3）

定压热容

c_p /（J·kg^-1·K^-1）

导热系数

$k$ /（W·m^-1·K^-1）

动力黏度

$η$ /mPa

铝

2 700

900

237

水

1 000

4 180

0.61

References 15

1	蔡蔚，杨茂通，刘洋，等. SiC功率模块封装技术及展望［J］. 汽车工程， 2022， 44（4）： 638-648.
	CAI W， YANG M T， LIU Y， et al. SiC power module packaging technologies and prospects［J］. Automotive Engineering， 2022， 44（4）： 638-648.
2	ZHANG Z， WANG X， YAN Y. A review of the state-of-the-art in electronic cooling［J］. e-Prime-Advances in Electrical Engineering， Electronics and Energy， 2021， 1： 100009.
3	SIGMUND O， MAUTE K. Topology optimization approaches： a comparative review［J］. Structural and Multidisciplinary Optimization， 2013， 48（6）： 1031-1055.
4	FAWAZ A， HUA Y， CORRE S L， et al. Topology optimization of heat exchangers： a review［J］. Energy， 2022， 252： 124053.
5	ALEXANDERSEN J. A detailed introduction to density-based topology optimisation of fluid flow problems with implementation in MATLAB［J］. Structural and Multidisciplinary Optimization， 2023，66：12.
6	ALEXANDERSEN J， ANDREASEN C S. A review of topology optimisation for fluid-based problems［J］. Fluids， 2020， 5（1）：29.
7	PICELLI R， RANJBARZADEH S， SIVAPURAM R， et al. Topology optimization of binary structures under design-dependent fluid-structure interaction loads［J］. Structural and Multidisciplinary Optimization， 2020，62（4）：2101-2116.
8	MO X， ZHI H， XIAO Y， et al. Topology optimization of cooling plates for battery thermal management［J］. International Journal of Heat and Mass Transfer， 2021， 178： 121612.
9	QIAN S， WANG W， GE C， et al. Topology optimization of fluid flow channel in cold plate for active phased array antenna［J］. Structural and Multidisciplinary Optimization， 2018， 57： 2223-2232.
10	XIA Y， CHEN L， LUO J， et al. Numerical investigation of microchannel heat sinks with different inlets and outlets based on topology optimization［J］. Applied Energy， 2023， 330： 120335.
11	左孔天，赵雨东，陈立平.传热结构的多目标拓扑优化设计研究［J］.计算力学学报， 2007 （5）：620-627.
	ZUO K T， ZHAO Y D， CHEN L P. Study on multiple objective topology optimization of thermal conductive structure［J］. Chinese Journal of Computational Mechanics， 2007 （5）：620-627.
12	王运宇，阎琨，蔡贤辉，等.基于COMSOL的简化对流传热结构拓扑优化方法［J］.计算力学学报，2023，40（4）：532-537.
	WANG Y Y， YAN K， CAI X H， et al. Topology optimization of simplified convection heat transfer problem by COMSOL［J］. Chinese Journal of Computational Mechanics， 2023， 40（4）：532-537.
13	WANG F， LAZAROV B S， SIGMUND O. On projection methods， convergence and robust formulations in topology optimization［J］. Structural and Multidisciplinary Optimization， 2011， 43： 767-784.
14	GUEST J K， PREVOST J H. Topology optimization of creeping fluid flows using a Darcy-Stokes finite element［J］. International Journal for Numerical Methods in Engineering， 2006， 66（3）： 461-484.
15	SVANBERG K. The method of moving asymptotes-a new method for structural optimization［J］. International Journal for Numerical Methods in Engineering， 1987， 24（2）： 359-373.

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Research on Multi-objective Topology Optimization Design of the Power Module Cold-Plate for the Electric Vehicles

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