Calculation of Phase Composition of α- and Near-α- Titanium Alloys

Fedor V. Vodolazskiy; E.A.  Gornostaeva; S.M.  Illarionova

doi:10.4028/www.scientific.net/SSP.299.403

Paper Titles

The Use of a Magnetic Suspension for the Crucibleless Metal Melting
p.381

Computer-Simulation of the Billet Shape Change during Helical Piercing
p.386

Study of Electromagnetic Effect Parameters Influence on Fluidity of Fine Nd-Fe-B Powder
p.392

The Peculiarities of Smelting of Wear-Resistant Cast Iron IChH28N2 in the Induction Crucible Furnace IChT10
p.397

Calculation of Phase Composition of α- and Near-α- Titanium Alloys
p.403

How the Material Thickness Affects 0.08% Carbon Cold-Rolled Sheet Steel
p.409

Influence of Thermomagnetic Treatment on the Damping Properties and Structure of Iron-Based Alloys
p.418

Effect of Hf Doping of Commercially Pure Copper on Evolution of its Microstructure under High Pressure Torsion
p.424

About Impact Strength and Thermal Properties of Steel Melts
p.430

HomeSolid State PhenomenaSolid State Phenomena Vol. 299Calculation of Phase Composition of α- and Near-α-...

Calculation of Phase Composition of α- and Near-α- Titanium Alloys

Abstract:

The thermodynamic calculation of the phase composition of the PT-1M, PT-7M, Ti-3Al-2.5V alloys versus temperature is performed using the Thermo-Calc software. The comparison of calculation results with the available experimental data is made.

You might also be interested in these eBooks

Materials Engineering and Technologies for Production and Processing V

View Preview

Info:

Periodical:

Solid State Phenomena (Volume 299)

Pages:

403-408

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.299.403

Citation:

Cite this paper

Online since:

January 2020

Authors:

Fedor V. Vodolazskiy*, E.A. Gornostaeva, S.M. Illarionova

Keywords:

Phase Composition, PT-1M, PT-7M, Temperature of Polymorphic Transformation, Thermodynamic Calculation, Ti-3Al-2.5V, Titanium Alloys

Export:

RIS, BibTeX

Price:

Permissions:

Request Permissions

* - Corresponding Author

References

[1] A.A. Ilyin, B.A. Kolachyov, I.S. Polkin Titanium alloys. Composition, structure, properties. Reference book. Moscow: VILS-MATI, (2009).

Google Scholar

[2] V. Smirnov, B. Krokhin, V. Kalinin The production development of high quality tubes (TREX) from titanium alloys for aerospace systems, Titan, 1 (2003) 3-10.

Google Scholar

[3] Y. Kosmatskiy, N. Fokin, E. Filyaeva, B. Barichko Deformation ability research of the titanium alloy Ti-3Al-2.5V and the assessment of the technological capability production of hot-extrusion tube from him, Titan, 2(52) (2016) 18-22.

Google Scholar

[4] S.P. Belov, et al, Metallography of titanium and its alloys, ed. S.G. Glazunov, B.A. Kolachev, Moscow: Metallurgy, (1992).

Google Scholar

[5] Kuznetsov, A.V., Sokolovskii, V.S., Salishchev, G.A., Belov, N.A., Nochovnaya, N.A. Thermodynamic modeling and experimental study of phase transformations in alloys based on γ-tial, Metal Science and Heat Treatment. 58(5-6) (2016) 259-267.

DOI: 10.1007/s11041-016-9999-2

Google Scholar

[6] K.V. Aleksandrov, N.F. Anoshkin, A.A. Bochvar and others, Semi-finished products from titanium alloys, Moscow: Metallurgy, (1979).

Google Scholar

[7] A.P. Anisimov, V.V. Antipov, V.N. Kopylov, L.P. Rtishcheva, V.G. Smirnov, A.A. Kharin, RU Patent № 2016068748 A1 (2016).

Google Scholar

[8] B.A. Kolachev, I.S. Polkin, V.D. Talalaev, Titanium alloys of different countries: Reference book, Moscow: VILS, (2000).

Google Scholar

[9] R. Boyer, G. Welsch, E.W. Collings, Materials Propeties Handbook: Titanium Alloys, ASM International. The Material Information Society, (1994).

Google Scholar

[10] U. Zwicker, Titan and its alloys. Moscow: Peace. (1979).

Google Scholar

[11] O. Kubashevsky, State diagrams of iron-based binary systems. Moscow: Metallurgy. (1985).

Google Scholar

[12] V.M. Vozdvijensky, V.S. Lasyotskaya, M.V. Vozdvizhenskaya, Patterns of interphase distribution of concentrations of elements in α and near-α- cast titanium alloys, Izvestiya vuzov Tsvetnaya metallurgiya, 5 (1996) 32-35.

Google Scholar

[13] Qiang Liao, Chao Deng, Heng-lei Qu, Ya-she Yang, Li Nan, Jian-chao Yang Effect of Deformation rate on microstructure and tensile properties of cold rolled Ti-3Al-2,5V alloy tube, Ti 2011 - Proceedings of the 12th World Conference on Titanium, 1 (2012) 278-281.

Google Scholar

[14] D. Zhau, T. Ebel, M. Yan, M. Quian Trace carbon in biomedical beta-titanium alloys: recent progress, JOM. 67(10) (2015) 2236-2243.

DOI: 10.1007/s11837-015-1590-6

Google Scholar

[15] B.A. Kolachev, A.V. Malkov, V.I. Sedov, Effect of carbon on the structure and plasticity of beta-titanium alloys, Metal Science and Heat Treatment , 3 (1975) 42-43.

DOI: 10.1007/bf00663687

Google Scholar

[16] E.V. Chukhina, A.Yu. Sholokhov, A.V. Zhelnina, A.G. Illarionov, Using the Thermocalc software for calculating the temperature of polymorphic (α + β) → β-transformation in a two-phase titanium alloy, Proceedings of the XVII International scientific and technical Ural school-seminar for young metal scientists, 2 (2016) 314-317.

Google Scholar

[17] K. Hemmond, J. Nutting, Deformation and properties of materials for aerospace application. Moscow: Metallurgy, 1982, pp.73-111.

Google Scholar

[18] P. Tarin, N. Corral, A.G. Simon, J.M. Badia, N. Martin Evolution of alpha-beta transformation in Ti-3Al-2,5V alloy. Microstructural changes and properties obtained, Ti 2011 - Proceedings of the 12th World Conference on Titanium, 1 (2012) 481-484.

Google Scholar

[19] A.G. Illarionov, Y.I. Kosmatskii, E.A. Filyaeva, F.V. Vodolazskii, N.A. Barannikova, Experimental Determination of Temperature Parameters for Evaluating the Possibility of Manufacturing Alloy Ti–3Al–2.5V Hot-Extruded Tubes, Metallurgist, 60(9-10) (2017) 983-988.

DOI: 10.1007/s11015-017-0396-x

Google Scholar

[20] B.A. Kolachev, V.I. Yelagin, V.A. Livanov. Metal science and heat treatment of non-ferrous metals and alloys, Moscow: MISIS, (1999).

Google Scholar