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新能源汽车多腔、壁厚差异显著挤压型材模具设计的多目标优化

Multi-Objective Optimization of a Multi-Cavity, Significant Wall Thickness Difference Extrusion Profile Mold Design for New Energy Vehicles.

作者信息

Xu Xuda, Jiang Feng, Li Jianxiang, Huang Hongfeng, Jiang Chunli

机构信息

School of Material Science and Engineering, Central South University, Changsha 410083, China.

Guangdong Hoshion Aluminium Co., Ltd., Zhongshan 528463, China.

出版信息

Materials (Basel). 2024 Apr 30;17(9):2126. doi: 10.3390/ma17092126.

DOI:10.3390/ma17092126
PMID:38730932
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11084683/
Abstract

With the rapid development of the new energy vehicle market, the demand for extruded profiles for battery trays, mainly characterized by significant wall thickness differences in multiple chambers, is increasing, posing new challenges to production and quality control. This study examines the multi-objective optimization problem in the design process of aluminum profile dies with multi-cavity profiles and significant wall thickness differences. Using QFORM-extrusion professional aluminum extrusion finite element analysis software and the response surface analysis method, the standard deviation of the velocity (SDV), standard deviation of the pressure (SDP), and thick wall hydrostatic pressure (TWHP) on the profile section at the die exit are optimized. By analyzing the functional relationship between the key die structure parameters (the height of the baffle plates, the length of the bearing, and the height of the false mandrel) and the optimization objective, the optimal combination scheme of die structure parameters was obtained using the NSGA2 (non-dominated sorting genetic algorithm-2) multi-objective genetic optimization algorithm. The results show that, compared with the initial design scheme, the standard deviation of profile section velocity was reduced by 5.33%, the standard deviation of pressure was reduced by 11.16%, and the thick wall hydrostatic pressure was increased by 26.47%. The die designed and manufactured using this scheme successfully completed the hot extrusion production task, and the profile quality met the predetermined requirements, thus verifying the effectiveness of this study in optimizing the design of a multi-cavity aluminum profile die with significant differences in wall thickness for complex structures.

摘要

随着新能源汽车市场的快速发展,对电池托盘挤压型材的需求不断增加,其主要特点是多个腔室的壁厚差异显著,这给生产和质量控制带来了新的挑战。本研究考察了具有多腔型材且壁厚差异显著的铝型材模具设计过程中的多目标优化问题。利用QFORM - 挤压专业铝挤压有限元分析软件和响应面分析方法,对模具出口处型材截面的速度标准差(SDV)、压力标准差(SDP)和厚壁静水压力(TWHP)进行了优化。通过分析关键模具结构参数(挡板高度、支承长度和假芯轴高度)与优化目标之间的函数关系,采用NSGA2(非支配排序遗传算法 - 2)多目标遗传优化算法得到了模具结构参数的最优组合方案。结果表明,与初始设计方案相比,型材截面速度标准差降低了5.33%,压力标准差降低了11.16%,厚壁静水压力提高了26.47%。采用该方案设计制造的模具成功完成了热挤压生产任务,型材质量满足预定要求,从而验证了本研究在优化复杂结构壁厚差异显著的多腔铝型材模具设计方面的有效性。

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