nfluence of Deformation Processing Modes on the Structure and Mechanical Properties of a High-Temperature Titanium Alloy of the Ti–Al–Zr–Si–Mo–Nb–Sn System

S. V. Akhonin$^{1}$, A. Yu. Severyn$^{1}$, V. O. Berezos$^{1}$, V. A. Kostin$^{1}$, M. M. Kuzmenko$^{2}$, O. M. Shevchenko$^{2}$, I. F. Kravchenko$^{3}$

$^{1}$E. O. Paton Electric Welding Institute, NAS of Ukraine, 11 Kazymyr Malevych Str., UA-03150 Kyiv, Ukraine
$^{2}$I. M. Frantsevich Institute for Problems in Materials Science, NAS of Ukraine, 3 Omeljan Pritsak Str., UA-03142 Kyiv, Ukraine
$^{3}$Government Enterprise ‘Ivchenko-Progress’, 2 Ivanova Str., UA-69068 Zaporizhzhia, Ukraine

Received: 09.04.2024; final version - 26.06.2024. Download: PDF

To determine the kinetics of phase transformations, a calculated CCT-diagram for a titanium alloy of the Ti–Al–Zr–Si–Mo–Nb–Sn alloying system is obtained. The study of the structure and mechanical properties of the heat-resistant alloy of the Ti–Al–Zr–Si–Mo–Nb–Sn alloying system, which are obtained at different temperatures after thermodeformation treatment, is carried out. As established, the deformation treatment carried out in the upper part of the area of the existence of ($\alpha$+$\beta$)-phases made it possible to increase the strength of the material at the room and operating temperatures and, that is especially important, to increase significantly the plasticity of the material, allowing only a slight decrease on average in its yield strength during short-term tests. As also found, a greater degree of deformation destroys hard silicide layers, distributes silicides more uniformly, increases both the strength and plasticity of the alloy, and slightly reduces the heat-resistant properties at 600°C.

Key words: heat-resistant titanium alloy, phase transformation, deformation treatment, structure, phase, mechanical properties.

URL: https://mfint.imp.kiev.ua/en/abstract/v46/i07/0705.html

DOI: https://doi.org/10.15407/mfint.46.07.0705

PACS: 61.72.Ff, 62.20.-x, 81.20.Hy, 81.30.Bx, 81.40.Ef, 81.40.Jj, 81.40.Vw

Citation: S. V. Akhonin, A. Yu. Severyn, V. O. Berezos, V. A. Kostin, M. M. Kuzmenko, O. M. Shevchenko, and I. F. Kravchenko, nfluence of Deformation Processing Modes on the Structure and Mechanical Properties of a High-Temperature Titanium Alloy of the Ti–Al–Zr–Si–Mo–Nb–Sn System, Metallofiz. Noveishie Tekhnol., 46, No. 7: 705—715 (2024)


REFERENCES
  1. O. P. Solonina and S. G. Glazunov, Zharoprochnyye Titanovyye Splavy [Heat-Resistant Titanium Alloys] (Moskva: Metallurgiya: 1976) (in Russian).
  2. E. W. Collings, The Physical Metallurgy of Titanium Alloys (Metal Parks, Ohio: ASM: 1984).
  3. S. O. Firstov, Nove Pokolinnya Materialiv na Bazi Tytanu. Mekhanika Ruynuvannya Materialiv i Mitsnist' Konstruktsiy [A New Generation of Materials on the Titanium Base. Fracture Mechanics of Materials and Strength of Constructions] (Ed. V. V. Panasiuk) (Lviv: PhMI, N.A.S. of Ukraine: 2004), p. 609 (in Ukrainian).
  4. S. A. Firstov, S.V. Tkachenko, and N. N. Kuz'menko, Met. Sci. Heat Treat. 51: 12-18 (2009). Crossref
  5. Q. B. Kuang, L. M. Zou, Y. X. Cai, X. Liu, and H. W. Xie, Mater. Trans., 58, No. 12: 1735-1741 (2017). Crossref
  6. Diagrammy Sostoyaniya Dvoinykh Metallicheskikh Sistem [Diagrams of the state of dual metallic systems]. Vol. 3 (Ed. N. P. Lyakishev) (Moskva: Mashinostroenie: 2000), p. 330-332 (in Russian).
  7. M. M. Kuz'menko, Mater. Sci., 44: 49-53 (2008). Crossref
  8. P. Cavaliere, M. El. Mehtedi, E. Evangelista, N. Kuzmenko, and O. Vasylyev, Composites Part A: Applied Science and Manufacturing, 37, No. 10: 1514-1520 (2006). Crossref
  9. O. P. Ostash, A. D. Ivasyshyn, L. D. Kulak, and M. M. Kuz'menko, Mater. Sci., 44: 360-367 (2008). Crossref
  10. S. O. Firstov, L. D. Kulak, M. M. Kuzmenko, and O. M. Shevchenko, Mater. Sci., 54, No. 6: 783-788 (2019). Crossref
  11. O. M. Shevchenko, L. D. Kulak, M. M. Kuzmenko, O. Yu. Koval, A. V. Kotko, I. F. Kravchenko, and S. O. Firstov, Mater. Sci., 59, No. 1: 40-48 (2023). Crossref
  12. H. L. Lukas, S. G. Fries, and B. Sundman, Computational Thermodynamics: The Calphad Method (Cambridge, U.K.: Cambridge University Press: 2007). Crossref
  13. S. V. Akhonin, V. Y. Belous, R. V. Selin, and V. A. Kostin, IOP Conf. Ser.: Earth Environ. Sci., 688: 012012 (2021). Crossref
  14. V. Korzhyk, Y. Zhang, V. Khaskin, O. Ganushchak, V. Kostin, V. Kvasnytskyi, A. Perepichay, and A.Grynyuk, Metals, 13, No. 8: 1338 (2023). Crossref
  15. J. S. Kirkaldy and D. Venugopalan, Phase Transformation in Ferrous Alloys (Eds. A.R. Marder and J.I. Goldstein) (Philadelphia, USA: AIME: 1984).
  16. S. Akhonin, O. Pikulin, V. Berezos, A. Severyn, O. Erokhin, and V. Kryzhanovskyi, Eastern-European Journal of Enterprise Technologies, 5, No. 12 (119): 6-12 (2022). Crossref
  17. S. V. Akhonin, V. O. Berezos, A. Yu. Severyn, M. P. Gadzyra, Y. G. Tymoschenko, and N. K. Davydchuk, IOP Conf. Ser.: Mater. Sci. Eng., 582: 012051 (2019). Crossref
  18. S. V. Akhonin, V. O. Berezos, O. M. Pikulin, A. Yu. Severyn, O. O. Kotenko, M. M. Kuzmenko, L. D. Kulak, and O. M. Shevchenko, Sovremennaya Ehlektrometallurgiya [Electrometallurgy Today], No. 2: 3-9 (2022) (in Ukrainian).
  19. S. V. Akhonin, A. Yu. Severin, O. M. Pikulin, M. M. Kuzmenko, L. D. Kulak, and O. M. Shevchenko, Sovremennaya Ehlektrometallurgiya [Electrometallurgy Today], No. 4: 42-48 (2022) (in Ukrainian). Crossref
  20. O. M. Shevchenko, L. D. Kulak, M. M. Kuzmenko, and S. O. Firstov, Metallofiz. Noveishie Tekhnol., 42, No. 2: 237-249 (2020) (in Ukrainian). Crossref