Frontiers of Mechanical Engineering >
Robust optimization of the billet for isothermal local loading transitional region of a Ti-alloy rib-web component based on dual-response surface method
Received date: 27 Jul 2017
Accepted date: 11 Oct 2017
Published date: 11 Jun 2018
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Billet optimization can greatly improve the forming quality of the transitional region in the isothermal local loading forming (ILLF) of large-scale Ti-alloy rib-web components. However, the final quality of the transitional region may be deteriorated by uncontrollable factors, such as the manufacturing tolerance of the preforming billet, fluctuation of the stroke length, and friction factor. Thus, a dual-response surface method (RSM)-based robust optimization of the billet was proposed to address the uncontrollable factors in transitional region of the ILLF. Given that the die underfilling and folding defect are two key factors that influence the forming quality of the transitional region, minimizing the mean and standard deviation of the die underfilling rate and avoiding folding defect were defined as the objective function and constraint condition in robust optimization. Then, the cross array design was constructed, a dual-RSM model was established for the mean and standard deviation of the die underfilling rate by considering the size parameters of the billet and uncontrollable factors. Subsequently, an optimum solution was derived to achieve the robust optimization of the billet. A case study on robust optimization was conducted. Good results were attained for improving the die filling and avoiding folding defect, suggesting that the robust optimization of the billet in the transitional region of the ILLF was efficient and reliable.
Ke WEI , Xiaoguang FAN , Mei ZHAN , Miao MENG . Robust optimization of the billet for isothermal local loading transitional region of a Ti-alloy rib-web component based on dual-response surface method[J]. Frontiers of Mechanical Engineering, 2018 , 13(3) : 376 -384 . DOI: 10.1007/s11465-018-0500-3
| 1 |
Yang H, Fan X G, Sun Z C,
|
| 2 |
Kleiner M, Geiger M, Klaus A. Manufacturing of lightweight components by metal forming. CIRP Annals-Manufacturing Technology, 2003, 52(2): 521–542
|
| 3 |
Fan X G, Yang H, Gao P F. Through-process macro-micro finite element modeling of local loading forming of large-scale complex titanium alloy component for microstructure prediction. Journal of Materials Processing Technology, 2014, 214(2): 253–266
|
| 4 |
Yang H, Gao P F, Fan X G,
|
| 5 |
Yang H, Fan X G, Sun Z C,
|
| 6 |
Sun Z C, Yang H, Sun N G. Effects of parameters on inhomogeneous deformation and damage in isothermal local loading forming of Ti-alloy component. Journal of Materials Engineering and Performance, 2012, 21(3): 313–323
|
| 7 |
Gao P F, Yang H, Fan X G,
|
| 8 |
Gao P F, Yang H, Fan X G,
|
| 9 |
Wei K, Zhan M, Fan X G,
|
| 10 |
Gao P F, Li X D, Yang H,
|
| 11 |
Taguchi G. Taguchi on Robust Technology Development: Bringing Quality Engineering Upstream. New York: ASME Press, 1993
|
| 12 |
Hou B, Wang W R, Li S H,
|
| 13 |
Huang Z L, Wang G, Wei S P,
|
| 14 |
Li H, Xu J, Yang H,
|
| 15 |
Li Y Q. Research on six sigma robust optimization of sheet metal forming. Dissertation for the Doctoral Degree. Shanghai: Shanghai Jiaotong University, 2006 (in Chinese)
|
| 16 |
Wei K, Yang H, Fan X G,
|
| 17 |
Zhang D W, Yang H. Metal flow characteristics of local loading forming process for rib-web component with unequal-thickness billet. International Journal of Advanced Manufacturing Techno-logy, 2013, 68(9–12): 1945–1965
|
| 18 |
Huang T L, Song X W, Liu X Y. The multi-objective robust optimization of the loading path in the T-shape tube hydroforming based on dual response surface model. International Journal of Advanced Manufacturing Technology, 2016, 82(9–12): 1595– 1605
|
| 19 |
Shen C W. Research on material constitution models of TA15 and TC11 titanium alloys in hot deformation process. Thesis for the Master’s Degree. Xi’an: Xi’an Northwestern Polytechnical University, 2007 (in Chinese)
|
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| 〈 |
|
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