Features of the effect of alloying elements on linear thermal expansion coefficient of wrought heat-resistant alloys based on the Ni–Fe system are studied. Short-term and long-term strength at 600°C is simulated and parameters are used successfully as equivalent alloy chemical composition, calculated by a system of unpolarized ionic radii equations. A new deformable weldable alloy based on Ni–Fe–Co is developed with working temperature up to 650°C, with \( \upsigma_u^{20 } \) = 1400 MPa, \( \upsigma_u^{600 } \) = 1200 MPa, and \( \upsigma_{100}^{600 } \) = 950 MPa, with low linear thermal expansion coefficient (α = 11.8 · 10–6 K–1 in the temperature range 20–600°C). The alloy is structurally stable, efficient in forming and welding, and with respect to set of properties it is better than standard alloys of similar designation. New alloy structure, phase composition, and properties are described.
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Notes
The work was performed by E. B. Chabina and E. V. Filonova.
References
E. N. Kablov, “Strategic areas for development of materials and processing technology in the period up to 2030,” in: Aviation Materials and Technology: Jubilee Sci.-Tech. Coll. (Appendix to Journal Aviatsionnye Materialy i Tekhnologii) [in Russian], VIAM, Moscow (2012), pp. 7–17.
B. S. Lomberg, S. V. Ovsepyan, M. M. Bakradze, and I. S. Mazalov, “High-temperature heat-resistant nickel alloys for gas turbine engine components,” ibid., pp. 52–57.
C. T. Sims, N. S. Stoloffa, and U. K. Hagel (eds.), Superalloys II. Heat-Resistant Materials for Aerospace and Industrial Power Installations [Russian translation], in 2 books, Metallurgiya, Moscow (1993).
R. B. Frank, “The long-term stability of thermospan alloy,” JOM, 52, No. 1, 37–39 (2000).
E. A. Wanner and D. A. Deantonio, USA Patent 5283032, publ. 02.01.1992.
M. Fahrmann, S. K. Srivastava, and L. M. Pike, “Development of new 760°C (1400 °F) capable low thermal expansion alloy,” Proc. 12th Symp. Superalloys 2012, pp. 769–776.
K. A. Heck, M. A. Moore, D. F. Smith, et al., USA Patent 5478417, publ. 12.26.1995.
S. B. Maslenkov, Heat-Resistant Steels and Alloys: Handbook [in Russian], Metallurgiya, Moscow (1983).
V. B. Latyshev, “Heat-resistant wrought weldable alloys for combustion chamber,” Sci.-Tech. Coll. Aviation Materials Abroad in the XX–XXI Centuries, VIAM, Moscow (1994).
B. S. Lomberg, S. V. Ovsepyan, and V. B. Latyshev, “Contemporary wrought heat-resistant alloys,” Coll. Int. Sci.-Tech. Conf. Scientific Ideas of S. T. Kishkin and Contemporary Materials Science, VIAM, Moscow (2006), pp. 75–84.
M. F. Rothman and H. M. Twancy, USA Patent 4818486, Haynes International, Inc., publ. 04.04.1989.
F. C. Hull, S. K. Hwang, J. M. Wells, and R. J. Jaffee, “Effect of composition on thermal expansion of alloys used in power generation,” J. Mat. Eng., 9, No. 1, 81–82 (1987).
E. V. Prikhod’ko, Metal Chemistry of Complex Alloying [in Russian], Metallurgiya, Moscow (1983).
B. S. Lomberg, S. V. Ovsepyan, and E. V. Baburina, “Calculation of heat resistance of complexly-alloyed nickel alloys by means of a system of unpolarized ionic radii (SUIR) equations,” MiTOM, No. 6, 9–11 (1995).
B. S. Lomberg, S. V. Ovsepyan, and M. M. Bakradze, “Features of alloying and heat treatment of heat-resistant nickel alloys for a new generation of gas turbine engine disks,” Aviats. Mater. Tekhnol., No. 2, 3–8 (2012).
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Translated from Metallurg, No. 7, pp. 61–65, July, 2013.
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Ovsepyan, S.V., Lomberg, B.S., Grigor’eva, T.I. et al. Heat-Resistant Wrought Weldable Alloy for GTE Components with Low Linear Thermal Expansion Coefficient. Metallurgist 57, 623–628 (2013). https://doi.org/10.1007/s11015-013-9779-9
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DOI: https://doi.org/10.1007/s11015-013-9779-9