Finite Element Simulation of the Hot-Rolling Process of Titanium Alloy Bar

Mwi Rong Shuai; Qing Xue Huang; Yan Chun Zhu

doi:10.4028/www.scientific.net/AMR.145.181

Paper Titles

Analysis of the Mill Roller Bearing Using Mixed Fast Multipole Boundary Element Method
p.159

Optimization of Rolling Schedule in Tandem Cold Mill Based on QPSO Algorithm
p.165

The Development of Short Stress Path Experimental Asymmetric Multifunctional Rolling Mill
p.171

Analysis on Diffusion Parameters of Rolling Mill Bearing Alloy-Interface
p.177

Finite Element Simulation of the Hot-Rolling Process of Titanium Alloy Bar
p.181

3-D Finite Element Simulation of the Vertical-Horizontal Rolling Process
p.187

Simulation of Automatic Position Control in an 8-High Cold Rolling Mill Hydraulic System
p.193

Research on Online Model of Vertical Rolling Force in Hot Strip Roughing Trains
p.198

Asymmetric Shape Control Theory and Practice in Cold Strip Mills
p.204

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 145Finite Element Simulation of the Hot-Rolling...

Finite Element Simulation of the Hot-Rolling Process of Titanium Alloy Bar

Abstract:

In order to overcome the drawbacks in the process of the titanium alloy, the authors propose to produce this kind of bar by Y-type rolling mill. The deforming process of titanium alloy has been simulated dynamically using MSC.Marc finite element software. The stress, strain, temperature and residual stress distributions of deformation area have been analyzed. The rolling force and torque have been obtained. The model could provide the foundation for further theoretical research and engineering application of titanium alloy bar rolling process.

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Periodical:

Advanced Materials Research (Volume 145)

Pages:

181-186

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.145.181

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Online since:

October 2010

Authors:

Mwi Rong Shuai, Qing Xue Huang, Yan Chun Zhu

Keywords:

Flat Triangular, Simulation, Titanium Alloy, Y-Type Mill

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