Evaluation of turbine rotor blade life taking into account static and thermal cyclic loading


Cite item

Full Text

Abstract

The existing methods of evaluating turbine life, taking into account the effects of static and thermal cyclic loading, are based on experimental data. The need for cost- and labor-intensive experiments makes this approach difficult to apply. This brings up a crucial task of calculating the life of a turbine blade, taking into account the interaction of static and thermal cyclic loading. The classical methods based on the hypothesis of continuity do not allow calculating the strength and thermo-physical properties of a material. This problem is solved by the transition to the models of the behavior of materials from the continuity hypothesis to the account of the inter-atomic forces at the level of an elementary atomic cell. This approach makes it possible to calculate strength, elastic and thermo-physical parameters of structural elements theoretically and semi-empirically. These parameters are used as the initial data in calculating the stress-strain state of gas turbine engine elements. They are required to calculate creep strain semi-empirically. In its turn, the ultimate creep strain is a criterion for both static and thermal cyclic loading, which makes it possible to determine the blade life, taking into account their mutual influence.

About the authors

I. Kh. Badamshin

Ufa State Aviation Technical University

Author for correspondence.
Email: adbadamshin@ugatu.ac.ru

Doctor of Science (Engineering)
Associate Professor of the Department of Aviation Engines

Russian Federation

References

  1. Kuznetsov N.D., Tseytlin V.I. Ekvivalentnye ispytaniya gazoturbinnykh dvigateley [Equivalent tests of gas turbine engines]. Moscow: Mashinostroenie Publ., 1976. 214 p.
  2. Badamshin I.Kh. Ot chetyrekh k odnomu. Sily vnutri atomnogo vzaimodeystviya i prochnost' materialov [From four to one. Inter-atomic forces and strength of materials]. Mos-cow: Izdatel'skiy Dom «Akademiya Estestvoznaniya» Publ., 2016. 134 p.
  3. Svoystva elementov. V 2 ch. Ch. 1. Fizicheskie svoystva: spravochnik / pod red. G.V. Samsonova [Properties of elements. In 2 parts. Part1. Physical properties: reference book / ed. by G.V. Samsonov]. Moscow: Metallurgiya Publ., 1976. 600 p.
  4. Nozhnitskiy Yu.A., Golubovskiy E.R. Obespechenie prochnostnoy nadezhnosti monokristallicheskikh rabochikh lopatok vysokotemperaturnykh turbin perspektivnykh GTD. Sb. trudov mezhdunarodnoy nauchno-tekhnicheskoy konferentsii, posvyashchennoy 100-letiyu so dnya rozhdeniya akademika S.T. Kishkina «Nauchnye idei S.T. Kishkina i sovremennoe materialovedenie». Moscow: VIAM Publ., 2006. 362 p.
  5. Getsov L.B. Materialy i prochnost' detaley gazovykh turbin [Materials and strength of gas turbine parts]. Leningrad: Mashinostroenie Publ., 1982. 295 p.
  6. Kablov E.N., Golubovskiy E.R. Zharoprochnost' nikelevykh splavov [Heat resistance of nickel alloys]. Moscow: Mashinostroenie Publ., 1998. 464 p.
  7. Novikov I.I., Rozin K.M. Kristallografiya i defekty kristallicheskoy reshetki [Crystallography and lattice defects]. Moscow: Metallurgiya Publ., 1990. 336 p.
  8. Badamshin I.Kh. Sposob povysheniya resursa gazoturbinnogo dvigatelya po chislu zapuskov [A method for increasing the service life of a gas turbine engine in terms of the number of starts]. Patent RF, no. 2627490, 2017. (Publ.08.08.2017, bul. no. 22)

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c) 2018 VESTNIK of Samara University. Aerospace and Mechanical Engineering

This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies