Paper Titles

Type Certification of 18 Ni Maraging Steels for Landing Gears
p.511

Structure-Property Correlation of Rolled ZM21/Al Magnesium Macrocomposite
p.516

Effect of Cold Working and Heat Treatment on Recrystallization, Mechanical Properties and Microstructure of High Strength Ti15V3Al3Cr3Sn (Ti-Beta) Alloy
p.521

Age Hardening Behavior in Al-8Zn-2Mg-2Cu Wrought Aluminum Alloy
p.527

Modeling the High Temperature Deformation Behaviour of a near Alpha Titanium Alloy with Bi-Modal Microstructure
p.533

Influence of Crystallographic Texture on Mechanical Properties in Cold Rolled 7XXX Series Al Alloys Used in Space Applications
p.539

Effect of Microstructure on Wear Characteristics of Spray Cast Al-Si Alloys
p.545

Effect of Counter Surface Temperature and Load on the Transition from Mild to Severe Wear Behavior of Al-Si-SiC_p Composites in Reciprocating Conditions
p.551

Optimization of Homogenization Parameters of Al-Cu-Li Alloy Cast Ingots Using Calorimetry and Metallographic Techniques
p.557

HomeMaterials Science ForumMaterials Science Forum Vol. 710Modeling the High Temperature Deformation...

Modeling the High Temperature Deformation Behaviour of a near Alpha Titanium Alloy with Bi-Modal Microstructure

Article Preview

Abstract:

The high temperature deformation behaviour of near alpha titanium alloy IMI834 with a bimodal microstructure has been evaluated by carrying out isothermal compression tests over a range of temperature and strain rate. The optimum thermomechanical processing (TMP) parameters i.e., temperature, strain rate that can be used to produce various aeroengine components were identified using dynamic materials modeling (DMM). Using kinetic analysis, a unified constitutive equation that describes the deformation behavior of the material in the selected temperature - strain rate regime has been established and the deformation mechanisms operating in the material were identified.

You might also be interested in these eBooks

Advances in Metallic Materials and Manufacturing Processes for Strategic Sectors

Info:

Periodical:

Materials Science Forum (Volume 710)

Pages:

533-538

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.710.533

Citation:

Cite this paper

Online since:

January 2012

Authors:

I. Balasundar, T. Raghu, B.P. Kashyap

Keywords:

Bi-Modal Microstructure, IMI 834, Near Alpha Titanium Alloy, Processing Map, Thermomechanical Processing (TMP)

Export:

RIS, BibTeX

Price:

Permissions:

Request Permissions

[1] D.F. Neal, Alloy development, Titanium ' 95: Science and Technology, 1995, pp.2195-2204.

[2] D.F. Neal, Development and Evaluation of high temperature titanium alloy IMI 834. VI world conference on titanium,1998, pp.253-258.

[3] T.W. Farthing, Designing with titanium, VI world conference on titanium, 1998, p.37 – 48.

[4] T. Noda,M. Okabe, S, Isobe, S. Nishikiori and H, Hattori, Development of high performance heat resistant near alpha titanium alloy compressor disc. Titanium'95: Science and Technology, 1995, pp.2258-2264.

[5] Y. Honnorat, Ti alloys used in Turbojet Engines, VI world conference on titanium, 1998, pp.365-379.

[6] P. Wanjara, M. Jahazi, H.Monajati, S.Yue, J.P. Immarigeon, Hot working behaviour of near alpha alloy IMI 834. Mat. Sci Eng A 396 (2005) 50-60.

DOI: 10.1016/j.msea.2004.12.005

[7] P. Wanjara, M. Jahazi, H. Monajati, S. Yue, Influence of thermomechanical processing on microstructural evolution in near alpha alloy IMI 834, Mat. Sci Eng A 416 (2006) 300-311.

DOI: 10.1016/j.msea.2005.10.042

[8] P.Vo, M. Jahazi, S. Yue and P. Bocher, Flow stress prediction during hot working of near alpha titanium alloys. Mat. Sci Eng A 447(2007) 99-110.

DOI: 10.1016/j.msea.2006.10.032

[9] Miaoquan Li, Hongsi Pan, Yingying Lin, Jia Luo, High temperature deformation behaviour of near alpha Ti-5.6Al-4.8Sn-2.0Zr alloy, J. Mater. Process. Tech. 183 (2007) 71-76.

[10] Young Niu, Hongliang Hou, Miaoquan Li, Zhiqiang Li, High temperature deformation behaviour of near alpha Ti600 titanium alloy, Mat. Sci Eng A 492 (2008) 24-28.

DOI: 10.1016/j.msea.2008.02.036

[11] Y.V.R.K. Prasad, S. Sasidhara, Hot Working Guide – A Compendium of Processing maps, ASM International, Ohio, 1997.

[12] V.V. Kutumba Rao and T. Rajagopalachary, Recent developments in modeling the hot working behaviour of metallic materials, Bull. Mater. Sci. 19 (1996) 677- 698.

DOI: 10.1007/bf02745160

[13] Y.V.R.K. Prasad, Recent advances in the science of mechanical processing, Indian J. of Technol. 28 (1990) 435 - 451.

[14] Y.V.R.K. Prasad, H.L. Gegel, S.M. Doraivelu, J.C. Malas, J.T. Morgan, K.A. Lark, D. Barker, Modeling of dynamic material behaviour in hot deformation: forging of Ti-6242. Metall. Trans. A, 15 (1984) 1883 - 1892.

DOI: 10.1007/bf02664902

[15] L.E. Malvern. Introduction to the Mechanics of Continuum Medium, Eaglewood Cliffs, Prentice-Hall, NJ, 1969.

[16] A.K. Kalyan Kumar, Criteria for predicting metallurgical instabilities in processing, M.S Thesis, Department of Metallurgy, IISc Bangalore, 1987.

[17] H. Ziegler. Progress in Solid Mechanics, Vol.4, John Wiley & Sons, NY, 1965.

[18] H.L. Gegel, J.C. Malas, S.M. Doraivelu and V.A. Shende, Forging and Forming, ASM Metals Handbook, 14 (1998) 417-438.

[19] J.J. Jonas, C.M. Sellars, W.J. McG Tegart, Strength and structure under hot working conditions. Metall. Rev., Vol. 14-1 (1969) 1-24.

DOI: 10.1179/mtlr.1969.14.1.1

[20] C,M. Sellars, W.J. McG. Tegart, Hot workability, Review 158, Int. Metall. Rev.,17 (1972)1-24.