Creating a quasi-linear model of an elastic damper support of the gas turbine engine rotor


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Abstract

In the presented work, the calculation of critical rotor speeds and determination of vibration characteristics of an advanced gas turbine engine are considered. The engine under study contains a low-pressure compressor with an elastic damper support of a new design that has non-linear characteristics of stiffness and damping coefficients. The problem of creating a model of elastic damper quasi-linear supports of gas turbine engine rotors is solved by adding a quasi-linear element to the dynamic calculation model created by the DYNAMICS A4 software system. The parameters of the element change their values depending on the rotor speed. The task of verifying the results of experimental data is investigated. The presented technique makes it possible to build a quasi-linear model of the rotor support and ensure the coincidence of calculated and experimental data.

About the authors

A. G. Tereshko

Lyulka Design Bureau

Author for correspondence.
Email: tereshko.ag@yandex.ru

Chief Strength Testing Specialist, Head of Department

Russian Federation

M. K. Leontiev

Moscow Aviation Institute

Email: lemk@alfatran.com

Doctor of Science (Engineering), Professor of Department 203 of Construction and Design of Engines

Russian Federation

References

  1. Dinamika aviatsionnykh gazoturbinnykh dvigateley / pod red. I.A. Birgera, B.F. Shorra [Dynamics of aviation gas turbine engines]. Moscow: Mashinostroenie Publ., 1981. 231 p.
  2. Natanzon V.Ya. Kolebaniya diskov osevykh kompressorov i turbin. Kriticheskie skorosti rotorov [Vibrations of disks of axial compressors and turbines, critical rotation speeds]. Moscow: Oborongiz Publ., 1955. 144 p.
  3. Khronin D.V. Teoriya i raschet kolebaniy v dvigatelyakh letatel'nykh apparatov [Theory and calculation of vibrations in aircraft engines]. Moscow: Mashinostroenie Publ., 1970. 412 p.
  4. Leontiev M.K. Konstruktsiya i raschet dempfernykh opor GTD: uchebnoe posobie [Design and calculation of damper supports of gas turbine engines. Study guide]. Moscow: Moscow Aviation Institute Publ., 2020. 78 p.
  5. Balyakin V.B., Zhil'nikov E.P. Teoriya i proektirovanie opor rotorov aviatsionnykh GTD [Theory and design of rotor supports for aviation GTE]. Samara: Samara State Aerospace University Publ., 2007. 253 p.
  6. Belousov A.I., Novikov D.K., Balyakin V.B. Gidrodinamicheskie dempfery opor rotorov turbomashin: uchebnoe posobie [Hydrodynamic damper of supports for turbo-machines. Study guide]. Samara: Kuybyshev Aviation Institute Publ., 1991. 95 p.
  7. Leontyev M.K., Tereshko A.G. Research of rotor dynamic of GTE with nonlinear stiffness of elastic elements in support parts. Vestnik of the Samara State Aerospace University. 2012. No. 3 (34), part 1. P. 173-180. (In Russ.). doi: 10.18287/2541-7533-2012-0-3-1(34)-173-180
  8. Nazarenko Y.B., Potapov A.Y. Elimination of critical rotation speeds of rotors of gas turbine engines by adjusting the stiffness of the supports. Dvigatel'. 2014. No. 1 (91). P. 14-16. (In Russ.)
  9. Diligenskiy D.S. Razrabotka obobshchennoy metodiki rascheta gidrodinamicheskogo dempfera s uprugim kol'tsom s uchetom posadok i treniya v oporakh rotorov GTD. Dis. … kand. tekhn. nauk [Development of a generalized method for calculating a hydrodynamic damper with an elastic ring, taking into account fits and friction in the supports of gas turbine engines. Thesis for a Candidate Degree in Science (Engineering)]. Samara, 2022. 232 p.
  10. Leontiev M.K., Tereshko A.G. Investigation of elastic rings mounted in rotor bearings of gas-turbine engines. Aerospace MAI Journal. 2011. V. 18, no. 3. P. 135-146. (In Russ.)
  11. Zaydullin D.A., Makarychev A.S. Vibratsionnaya dovodka VSU po rezul'tatam rascheta kriticheskikh chastot vrashcheniya i eksperimental'nykh dannykh. Sbornik Dokladov Nauchno-tekhnicheskoy Konferentsii «Klimovskie Chteniya - 2020. Perspektivnye Napravleniya Razvitiya Dvigatelestroeniya» (October, 16, 2020, Saint Petersburg). SPb: Skifiya-Print Publ., 2020. P. 287-292. (In Russ.)
  12. Zenkova L.F., Gusenko S.M., Tereshko A.G. Uprugodempfernaya opora rotora turbomashiny [Resilient damping support of turbomachine rotor]. Patent RF, no. 2623675, 2017. (Publ. 28.06.2017, bull. no. 19)
  13. Vibratsii v tekhnike. Spravochnik. T. 3 / pod red. F.M. Dimentberga, K.S. Kolesnikova [Vibration in engineering. Reference guide. V. 3]. Moscow: Mashinostroenie Publ., 1980. 544 p.
  14. Diligensky D.S., Novikov D.K. Calculation of the damping coefficient of flexible rings with working fluid. Vestnik of the Samara State Aerospace University. 2015. V. 14, no. 3, part 2. P. 327-335. (In Russ.). doi: 10.18287/2412-7329-2015-14-3-327-335
  15. Falaleev S.V. Trends in research of hydrodynamic damping in rotor supports of gas turbine engines. Russian Aeronautics. 2017. V. 60, Iss. 2. P. 229-235. doi: 10.3103/S1068799817020118

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