Compressible Flows with Oscillating Boundaries

O. A. Logvinov; Логвинов О. А.

doi:10.31857/S1024708422600828

Compressible Flows with Oscillating Boundaries

Autores: Logvinov O.A.¹
Afiliações:
1. Moscow State University, Mechanics and Mathematics Department
Edição: Nº 3 (2023)
Páginas: 36-46
Seção: Articles
URL: https://clinpractice.ru/1024-7084/article/view/672360
DOI: https://doi.org/10.31857/S1024708422600828
EDN: https://elibrary.ru/TMPLGN
ID: 672360

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Resumo
Sobre autores
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Resumo

The flow of a viscous compressible heat-conducting fluid in a plane channel with rigid oscillating walls is considered. It is shown that even a vanishingly small compressibility can be the reason for the onset of a resonance, i.e., sharp increase in the amplitude of oscillations of the flow parameters at a properly selected wall oscillation frequency. An exact analytical expression for the leading resonant frequency is given. Numerical calculations have demonstrated the possibility of a cumulative effect, namely, sharp increase in the mass flow rate even at constant pressure gradient.

Palavras-chave

compressibility, viscosity, thermal conductivity, cumulative resonance

Sobre autores

O. Logvinov

Moscow State University, Mechanics and Mathematics Department

Autor responsável pela correspondência
Email: oleglogvinov@mail.ru
Moscow, Russia

Bibliografia

Ганиев О.Р., Ганиев Р.Ф., Звягин А.В., Украинский Л.Е., Устенко И.Г. Повышение нефтеотдачи пластов на основе волноводных эффектов. Немонотонность затухания двумерных волн в волноводе // Спр. инж. журн. 2016. 228. № 3. С. 42–48.
Ганиев О.Р., Ганиев Р.Ф., Звягин А.В., Украинский Л.Е., Устенко И.Г. Повышение нефтеотдачи пластов на основе волноводных эффектов. Распределение в волноводе силы, действующей на частицы в гармоническом волновом поле // Спр. инж. журн. 2016. 229. № 4. С. 49–56.
Secomb T.W. Flow in a channel with pulsating walls // J. Fluid. Mech. 1978. V. 88. P. 273–288.
Hall P., Papageorgiou D.T. The onset of chaos in a class of Navier – Stokes solutions // J. Fluid. Mech. 1999. V. 393. P. 59–87.
Mingalev S.V., Filippov L.O., Lyubimova T.P. Flow rate in a channel with small-amplitude pulsating walls // Euro. J. Mech. B/Fl. 2015. V. 51. P. 1–7.
Тукмаков А.Л. Течение газа в плоском канале с вибрирующими стенками // Инж.-физ. журн. 2002. Т. 75. № 6. С. 109–115.
Smirmov N.N., Shugan I.V., Legros J.C. Streaming flows in a channel with elastic walls // Phys. Fluids. 2002. V. 14. № 10. P. 1–10.
Bagchi S., Gupta K., Kushari A., Iyengar N.G.R. Experimental study of pressure fluctuations and flow perturbations in air flow through vibrating pipes // J. Sound. Vibr. 2009. V. 328. P. 441–455.
Logvinov O.A., Malashin A.A. Resonance phenomena in a channel with oscillating walls // Euro. J. Mech. B/Fl. 2020. 83. 205–211.
Ковеня В.М., Яненко Н.Н. Метод расщепления в задачах газовой динамики. Новосибирск: Наука, 1981. 304 с.