Computer Simulation on Formation of Precision Forgings of Titanium Alloy and Superalloy

R.H. Wu; K.C. Pang

doi:10.4028/www.scientific.net/MSF.539-543.3130

Paper Titles

Recent Activities on Directional Solidification at the State Key Laboratory of Solidification Processing
p.3106

Creep Strength Assessment of High Chromium Ferritic Creep Resistant Steels
p.3112

Creep Behavior of Single Crystal Superalloy DD6 at 760°C and 980°C
p.3118

Manufacturing and Analysis of Mechanical Properties of Superalloy 718 in Hydraulic Forging
p.3124

Computer Simulation on Formation of Precision Forgings of Titanium Alloy and Superalloy
p.3130

Properties of Boron Fiber Reinforced Aluminum Matrix Composites Fabricated by Pulsed Current Hot Pressing (PCHP)
p.3139

Self-Healing of Creep Cavities by Boron Segregation and Boron Nitride Precipitation Autonomously Developed during High Temperature Use
p.3145

TiNi Shape Memory Alloys for MEMS: Thin Film Deposition, Thermophysical Properties and Laser Micromachining Characteristics
p.3151

Phase Transformation and Microstructures in Ni and Cu Base Ferromagnetic Shape Memory Alloys
p.3157

HomeMaterials Science ForumMaterials Science Forum Vols. 539-543Computer Simulation on Formation of Precision...

Computer Simulation on Formation of Precision Forgings of Titanium Alloy and Superalloy

Abstract:

The deformation features are analyzed for titanium alloy and superalloy during isothermal/hot die forging process, and proper finite element models with appropriate parameter values are determined. On the platform of DEFORM software, the formation processes of vane-integrated disk and compressor disk, made of titanium alloy and superalloy respectively, are simulated and analyzed. Based on the simulation results, some important suggestions to the process design and parameter determination are brought forward, which have been taken into consideration or adoption in practice. As a result, the production yield is promoted, and a large amount of expenses of testing and die trial-manufacture are saved.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Materials Science Forum (Volumes 539-543)

Pages:

3130-3135

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.539-543.3130

Citation:

Cite this paper

Online since:

March 2007

Authors:

R.H. Wu, K.C. Pang

Keywords:

Computer Simulation, Hot Die Forging, Isothermal Forging, Superalloy, TiAl

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] B.I. Tomov, V.I. Gagov and R.H. Radev: J. of Mater. Proc. Tech. Vol. 153-154 (2004), p.352.

Google Scholar

[2] M. Zhan, Y. Liu and H. Yang: J. of Mater. Proc. Tech. Vol. 117 (2001), p.56.

Google Scholar

[3] H. Grass, C. Krempaszky, T. Reip and E. Werner: Computational Materials Science Vol. 28 (2003), p.469.

Google Scholar

[4] M. Mohamdein and J. Schwar: Proceedings of the International Symposium on Superalloys and Various Derivatives Vol. 1 (2001), p.213.

Google Scholar

[5] B. Suden, C.A. Brebbia and A. Mendes (eds. ): Computational Studies Vol. 5 (2004), p.526.

Google Scholar

[6] W.R.D. Wilson, S.R. Schmid and J.Y. Liu: J. of Mater. Proc. Tech. Vol. 155-156 (2004), p. (1912).

Google Scholar

[7] J. Fluhrer: DEFORMTM User's Manual.

Google Scholar

[8] C. Thiebaut: Journal of Materials processing Technology Vol. 77 (1998), p.240.

Google Scholar

[9] Z. Malinowski, J.G. Lenard and M.E. Davies: J. of Mater. Proc. Tech. Vol. 41(1994), p.125.

Google Scholar

[10] G. Snape, S. Clift and A. Bramley: J. of Mater. Proc. Tech. Vol. 125-126 (2002), p.353.

Google Scholar