The 3D Modeling of Dies Based on UG and Numerical Simulation of the Heat Rheological Forming of Titanium Alloy Vane Disk

Ying She Luo; Min Yu; Xiang Hua Peng

doi:10.4028/www.scientific.net/KEM.340-341.725

Paper Titles

On-Line Optimization of Coiling Temperature Control on Run-Out Table for Hot Strip Mills
p.701

Mechanics of a Special Asymmetric Rolling of Thin Strip
p.707

Analysis of the Process of AA-6201 Feedstock Using Continuous Casting and Extrusion
p.713

Web Based Shape Inspection System for the Forging Products Having Complicated Shapes
p.719

The 3D Modeling of Dies Based on UG and Numerical Simulation of the Heat Rheological Forming of Titanium Alloy Vane Disk
p.725

Upper Bound Solution to Compression Forming of Three-Layer Bounded Clad Sheet
p.731

Hot Forging Comparative Analyses by Using a Combined Finite Element Method
p.737

Effect of Tool Modeling Accuracy on Sheet Metal Forming Simulation
p.743

Resistance Heating Characteristics of High-Strength Steel Sheet Blank for Hot Press Forming
p.749

HomeKey Engineering MaterialsKey Engineering Materials Vols. 340-341The 3D Modeling of Dies Based on UG and Numerical...

The 3D Modeling of Dies Based on UG and Numerical Simulation of the Heat Rheological Forming of Titanium Alloy Vane Disk

Abstract:

The heat rheological forming of the TC11 titanium alloy vane disk has been studied. The dies of rheological forming were 3D-modeled based on UG and the heat rheological forming of the TC11 titanium alloy under a certain temperature and a low strain rate was analyzed by DEFORM 3D based on variation principle of rigid viscoplastic non-compressed material. A series of results including rheological forming procedure, equivalent strain field, temperature field and load-stroke curves of punch and cavity die, were obtained by finite element method. The deformation characteristic of the TC11 titanium alloy was well known and its heat rheological forming process and parameters were determined. Moreover, the local underfilled phenomenon in practical manufacture was predicted and analyzed, and we found that the defects could be restricted by reducing the forming velocity.

You might also be interested in these eBooks

Engineering Plasticity and Its Applications

View Preview

Info:

Periodical:

Key Engineering Materials (Volumes 340-341)

Pages:

725-729

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.340-341.725

Citation:

Cite this paper

Online since:

June 2007

Authors:

Ying She Luo, Min Yu, Xiang Hua Peng

Keywords:

3D Modeling, Deform 3D, Finite Element, Heat Rheological Forming, TC 11 Titanium Alloy

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Y. G. Hu, Y. S. Luo, et al., Numercal simulation of rheological warm extrusion molding of missile shell. Forging technology, Vol. 25(1) (2000), pp.10-12.

Google Scholar

[2] S. Y. Li, Y. S. Luo, S.W. Li, X. H. Xu, J. L. Zhou: The numerical simulation and its application on the rheological forming of the TC11 titanium alloy disk, Hot working technology, No. 1 (2001), pp.22-25.

Google Scholar

[3] Y. S. Luo, K.W. Luo, Y. G. Hu, Theory and practice on metal's rheological forming. Forging technology, Vol. 22(4) (1997), pp.11-13.

Google Scholar

[4] Y.S. Luo, X. G. Guo, Y. F. Mei, Y. G. Hu. Dislocation evolution with rheological forming of metal. Trans Nonferrous Met. Soc. China, Vol. 9(3) (1999), pp.623-628.

Google Scholar

[5] Y. S. Luo, The survey in researching and prospect on metal processing rheology, Proc. of XШth international congress of rheology, Cambridge, UK, Vol. 3 (2000), pp.406-408.

Google Scholar

[6] Y. S. Luo, K. Dohda and Z. Wang, Experimental Solution for Viscosity Coefficient of Solid Alloy Material, Int. J. of Applied Mechanics and Engineering, Vol. 8 (2003), pp.271-276.

Google Scholar

[7] Y. S. Luo, F. Liu and Y. Liu, et al., The Numerical Simulation and Mechanics Analysis for Deep-Draw Thermal-rheological Forming of One Ti Alloy Rectification Internal Hood, Key Engineering Material, Vols. 274-276(2004) pp.721-726.

DOI: 10.4028/www.scientific.net/kem.274-276.721

Google Scholar

[8] J. S. Liu, H. Q. Chen, X. X. Guo, The Finite Element Simulation technology of Metal' Plastic Process and Its Application, Metallurgy Industry Press, Beijing, (2003).

Google Scholar

[9] G. C. Wang, G. Q. Zhao, S. S. Xie, Y. G. Luan, Numerical and experimental study on new cole precision forging technique of spur gears, Trans. Nonferrous Met. Soc., vol. 13(2003), pp.798-802.

Google Scholar