T形管液压成形自适应径向基函数优化设计

doi:10.16183/j.cnki.jsjtu.2017.11.009

摘要/Abstract

摘要： 讨论T形管液压成形加载路径代理模型优化的设计.采用径向基函数(RBF)模型，引入自适应优化算法，通过逐步向静态RBF模型样本库中增加样本点的方法，提升最优点附近局部近似计算精度，进而提升全局精度并获得最优解.该方法兼顾了优化效率与计算精度.首先通过数值算例证明此方法应用于全局优化的有效性；然后，以管件与中间冲头接触面积最大为优化目标，以最大减薄率小于对标实验值、成形高度大于对标实验值为约束条件，通过拉丁方试验设计抽取一定数量的样本点并调用实际分析模型构建T形管液压成形加载路径优化自适应RBF模型，开展载荷路径优化设计.结果表明，在最小厚度与成形高度不变的情况下，T形管与中间冲头的接触面积较对标实验值提高了71.912%.

关键词: 车辆工程, T形管液压成形, 代理模型, 加载路径优化, 自适应径向基函数

Abstract: The study of surrogate model optimization of the loading path of a T-shape tube hydroforming is carried out in this paper. The adaptive optimization algorithm is introduced to radial basis function(RBF). In order to improve approximate accuracy in the concerned local regions, the paper proposes to add sample points gradually into the sample database, and to obtain the globally optimal efficiency and accuracy. The effectiveness of the method in global optimization is demonstrated by a numerical example firstly, then, adaptive radial basis function model for the T-shape tube hydroforming loading path optimization is constructed，and optimization design is carried out. The contact areas of the tube and the counter punch are selected to be the optimization target, the constraints are that the maximum thinning ratio is less than the experimental value, and the protrusion height is higher than the experimental value. The Latin hypercube design is used to obtain sample points, and the actual values of finite element analysis model of T-shape hydroforming are calculated. The loading path optimization design results are compared with the experimental values, and the result shows that the contact areas of T-shape tube and counter punch have improved by 71.912% under the condition that the minimum thickness and the protrusion height are maintained.

Key words: vehicle engineering, T-shape tube hydroforming, surrogate model, loading path optimization, adaptive radial basis function (RBF)

中图分类号:

TG 376.2

宋学伟，马玲玲，黄天仑，刘敏. T形管液压成形自适应径向基函数优化设计[J]. 上海交通大学学报（自然版）, 2017, 51(11): 1340-1347.

SONG Xuewei，MA Lingling，HUANG Tianlun，LIU Min. The Loading Path Optimization for T-Shape Tube Hydroforming Using Adaptive Radial Basis Function [J]. Journal of Shanghai Jiaotong University, 2017, 51(11): 1340-1347.

参考文献

［1］DOHMANN F, HARTL C. Tube hydroforming—Research and practical application［J］. Journal of Materials Processing Technology, 1997, 71(1): 174-186. ［2］黄天仑. T型管液压成形加载路径的稳健性优化设计［D］. 长春: 吉林大学汽车工程学院, 2016. ［3］AHMADI B S Y, KHALILI K, SHAHRI S E E, et al. Loading path optimization of a hydroformed part using multilevel response surface method［J］. International Journal of Advanced Manufacturing Technology, 2014, 70(5/6/7/8): 1523-1531. ［4］ABDESSALEM A B, PAGNACCO E, EL-HAMI A. Increasing the stability of T-shape tube hydroforming process understochastic framework［J］. International Journal of Advanced Manufacturing Technology, 2013, 69(5/6/7/8): 1343-1357. ［5］ABDESSALEM A B, EL-HAMI A. Global sensitivity analysis and multi-objective optimisation of loading path in tube hydroforming process based on metamodelling techniques［J］. International Journal of Advanced Manufacturing Technology, 2014, 71(5/6/7/8): 753-773. ［6］ZHAO D, XUE D. A comparative study of metamodeling methods considering sample quality merits［J］. Structural and Multidisciplinary Optimization, 2010, 42(6): 923-938. ［7］HUANG T, SONG X, LIU M. A Kriging-based non-probability interval optimization of loading path in T-shape tube hydroforming［J］. International Journal of Advanced Manufacturing Technology, 2016, 85(5/6/7/8): 1615-1631. ［8］INGARAO G, MARRETTA L, LORENZO R D. A comparison between three meta-modeling optimization approaches to design a tube hydroforming process［J］. Key Engineering Materials. 2012, 504/505/506: 607-612. ［9］BONTE M H A, VAN DEN BOOGAARD A H, HUTINK J. A metamodel based optimisation algorithm for metal forming processes［M］. Advanced Methods in Material Forming. Springer Berlin Heidelberg, 2007: 55-72. ［10］BELHADJ T, ABBASSI F, MISTOU S, et al. Numerical analyses of tube hydroforming problem using artificial neural networks［J］. International Journal of Material Forming, 2010, 3(1): 295-298. ［11］WANG G G, DONG Z, AITCHISON P. Adaptive response surface method—A global optimization scheme for approximation-based design problems［J］. Engineering Optimization, 2001, 33(6): 707-734. ［12］WANG G G. Adaptive response surface method using inherited Latin hypercube design points［J］. Journal of Mechanical Design, 2003, 125(2): 210-220. ［13］ZHAO Z, HAN X, JIANG C, et al. A nonlinear interval-based optimization method with local-densi-fying approximation technique［J］. Structural and Multidisciplinary Optimization, 2010, 42(4): 559-573. ［14］JIANG C, HAN X, LIU G P. A sequential nonlinear interval number programming method for uncertain structures［J］. Computer Methods in Applied Mechanics and Engineering, 2008, 197(49): 4250-4265. ［15］DUPRAT F, SELLIER A. Probabilistic approach to corrosion risk due to carbonation via an adaptive response surface method［J］. Probabilistic Engineering Mechanics, 2006, 21(3): 207-216. ［16］TORII A J, LOPEZ R H. Reliability analysis of water distribution networks using the adaptive response surface approach［J］. Journal of Hydraulic Engineering, 2012, 138(3): 227-236. ［17］李凯. T 型三通管液压成形加载路径优化［D］. 哈尔滨: 哈尔滨工业大学材料科学与工程学院, 2010. ［18］李忠范, 高文森. 数理统计与随机过程［M］.北京: 高等教育出版社, 2000.

[1]	陶威, 刘钊, 许灿, 朱平. 三维正交机织复合材料翼子板多尺度可靠性优化设计[J]. 上海交通大学学报, 2021, 55(5): 615-623.
[2]	陈永信. 滑翔飞行器气动外形与轨迹一体化设计优化[J]. 空天防御, 2021, 4(3): 76-84.
[3]	丘文桢, 宋兴宇, 张新曙. 基于代理模型的三立柱半潜平台多目标优化[J]. 上海交通大学学报, 2021, 55(1): 11-20.
[4]	张科, 吴亚东. 拓宽大涵道比风扇稳定运行范围的叶片优化设计[J]. 上海交通大学学报, 2020, 54(10): 1024-1034.
[5]	王刚成，马宁，顾解忡. 基于Kriging代理模型的船舶水动力性能多目标快速协同优化[J]. 上海交通大学学报（自然版）, 2018, 52(6): 666-673.
[6]	陈巍，周雄辉，张汝珍，韩先洪，王会凤. 基于Kriging代理模型的注塑产品翘曲优化[J]. 上海交通大学学报（自然版）, 2010, 44(04): 588-0592.