Study of the efficiency of the application of gas dynamic stabilization of the flame in a current engine
- Autores: Belonozhkin V.V.1, Teslya D.N.1
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Afiliações:
- Military Educational and Scientific Center of the Air Force Academy named after Professor N.E. Zhukovsky and Yu.A. Gagarin
- Edição: Volume 22, Nº 3 (2023)
- Páginas: 7-12
- Seção: AIRCRAFT AND SPACE ROCKET ENGINEERING
- URL: https://journal-vniispk.ru/2542-0453/article/view/145850
- DOI: https://doi.org/10.18287/2541-7533-2023-22-3-7-12
- ID: 145850
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Resumo
An analysis of the problems that arise when dealing with issues of increasing the efficiency of using an afterburner as part of a current aircraft engine is presented, where the complex problem of reducing its influence in non-afterburning operation and improving the work process when using it is solved. In a number of cases, solving the problem comes down to a compromise which does not allow full realization of all the advantages of the design element in question. The results of a study of the influence of the method of gas-dynamic flame stabilization on the main target indicator – specific fuel consumption in a real engine are presented, which makes it possible to justify conducting this kind of research on a real object. Graphs of changes in specific fuel consumption and thrust of a gas turbine engine when changing the engine rotor speed for non-afterburning operating modes are presented, as well as graphs of changes in specific fuel consumption and thrust of a gas turbine engine when changing the speed of the aircraft for afterburning operating modes. A conclusion is drawn about the expedience of using gas-dynamic flame stabilization in the afterburner from the point of view of its effect on specific fuel consumption.
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Sobre autores
V. Belonozhkin
Military Educational and Scientific Center of the Air Force Academy named after Professor N.E. Zhukovsky and Yu.A. Gagarin
Autor responsável pela correspondência
Email: belonozhkinvv@mail.ru
Associate Professor
RússiaD. Teslya
Military Educational and Scientific Center of the Air Force Academy named after Professor N.E. Zhukovsky and Yu.A. Gagarin
Email: patmi@rambler.ru
Senior Lecturer
RússiaBibliografia
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- Pakhol'chenko A.A., Cherkasov A.N., Alekseev A.A., Koren' G.P., Moskaev V.A. Teoriya aviatsionnykh dvigateley: funktsional'nye elementy seriynykh silovykh ustanovok: uchebnoe posobie [Theory of aircraft engines: functional units of production power plants: Tutorial]. Voronezh: Voenno-vozdushnaya Akademiya Publ., 2015. 231 p.
- Nechaev Yu.N., Fedorov R.M., Kotovskiy V.N., Polev A.S. Teoriya aviatsionnykh dvigateley. Ch. 1 [Theory of aircraft engines. Part 1]. Moscow: Voenno-vozdushnaya Inzhenernaya Akademiya imeni N.E. Zhu-kovskogo Publ., 2006. 365 p.
- Evdokimov A.I., Kotsyubinskiy S.V., Frolov V.B., Gorskiy A.N., Titov D.V. Konstruktsiya i prochnost' aviadvigateley [Aircraft engine design and strength]. Moscow: Voenno-vozdushnaya Inzhenernaya Akademiya imeni N.E. Zhukovskogo Publ., 2007. 339 p.
- Mingazov B.G. Kamery sgoraniya gazoturbinnykh dvigateley: konstruktsiya, mod-elirovanie protsessov i raschet: uchebnoe posobie [Combustion chambers of gas turbine engines. Design, simulation and calculation: Tutorial]. Kazan: Kazan National Research Technical University Publ., 2006. 219 p.
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