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The paper deals with the analysis of power factors acting within the boundary layer for different types of flow: convergent, gradientless and diffuser. Based on the considered formation mechanism of boundary layer separation, a hypothesis about the possible influence on structure and character of a separated flow by changing the gradient of the tangential stresses in the boundary layer was proposed. This impact is proposed to realize by means of the longitudinal finning of diffuser. Verification of the concept is performed on the basis of numerical flow investigation and available experimental data.
Rocznik
Tom
Strony
127--138
Opis fizyczny
Bibliogr. 21 poz., rys., tab.
Twórcy
autor
- National Research University “Moscow Power Engineering Institute” Moscow, Russia
autor
- National Research University “Moscow Power Engineering Institute” Moscow, Russia
autor
- National Research University “Moscow Power Engineering Institute” Moscow, Russia
autor
- National Research University “Moscow Power Engineering Institute” Moscow, Russia
Bibliografia
- [1] Fiola C., Agarwal R.K., Simulation of secondary and separated flow in a serpentine diffuser (S-Duct) for air breathing propulsion, SAE Technical Papers 2013, 7, Article ID 2119.
- [2] Hu B., Zhang H., Younis M.Y., Li Y., Raza M.S., Experimental investigation on the transition of separation/attachment in steady laminar juncture flows, Experiments in Fluids 2015, 56, Article ID 74.
- [3] New T.H., Long J. Dynamics of laminar circular jet impingement upon convex cylinders, Physics of Fluids 2015, 27, Article ID 024109.
- [4] Dholey S., The boundary layers of an unsteady separated stagnation-point flow of a viscous incompressible fluid over a moving plate, Fluid Dynamics Research 2015, 47, Article ID 035504.
- [5] Nadeem M., Lee J.H., Lee J., Sung H.J., Turbulent boundary layers over sparsely-spaced rod-roughened walls, International Journal of Heat and Fluid Flow 2015, 56, 16-27.
- [6] Liu Y., Sun J., Lu L., Corner separation control by boundary layer suction applied to a highly loaded axial compressor cascade, Energies 2014, 7, 7994-8007.
- [7] Walker J.M., Sargison J.E., Henderson A.D., Turbulent boundary-layer structure of flows over freshwater biofilms, Experiments in Fluids 2013, 54, Article ID 1628.
- [8] Van Dommelen L.L., Yapalparvi R., Laminar boundary-layer separation control by Gortlerscale blowing, European Journal of Mechanics 2014, 46, 1-16.
- [9] Dovgal A.V., Zanin B.Y., Sorokin A.M., Flow instability in the zone of laminar axisymmetric boundary layer separation, Fluid Dynamics 2013, 48, 747-753.
- [10] Simens M.P., Gungor A.G., The effect of surface roughness on laminar separated boundary layers, Journal of Turbomachinery 2013, 136, Article ID 031014.
- [11] Fernandez-Feria R, Pino C., Fernandez-Gutierrez A., Separation in the mixed convection boundary - layer radial flow over a constant temperature horizontal plate, Physics of Fluids 2014, 26, Article ID 103603.
- [12] Flack K.A., Schultz M.P., Roughness effects on wall-bounded turbulent flows, Physics of Fluids 2014, 26, Article ID 101305.
- [13] Vanstone L., Estruch-Samper D., Hillier R., Ganapathisubramani B., Shock induced separation in transitional hypersonic boundary layers, Proceedings of the 43rd Fluid Dynamics Conference, San Diego 2013.
- [14] Chen J., Qu H., Li P., Li Y., Xie Y., Zhang D., Numerical Study on Flow Separation Control for High-lift Low - pressure Turbine Split Blade, Proceedings of the ASME Fluids Engineering Division Summer Meeting, Incline Village 2013.
- [15] Urankar S., Raikar S., Bharath N., Naveen R., Gupta S., Theoretical computation of boundary layer separation point over an impeller vane pressure surface in centrifugal pump, Proceedings of the 3rd International Conference on Advances in Computing and Communications, Bangalore 2013.
- [16] Tornblom O., Experimental study of the turbulent flow in a plane asymmetric diffuser, Licentiate thesis, Dept. Mechanics, Royal Institute of Technology, Stockholm 2003.
- [17] Chandavari V., Palekar M.S., Diffuser angle control to avoid flow separation, International Journal of Technical Research and Application 2014, 16-21.
- [18] Lenarcic M., Erne S., Bauer C., Improvement in performance parameters by shape optimization of a conocal flow around diffuser, VI International Conference on Adaptive Modeling and Simulation (ADMOS), Lisbon 2013.
- [19] Singh S.N., Seshadri V., Chandel S., Gailwad M., Analysis of the improvement in performance characteristics of S-shaped rectangular diffuser by momentum injection using computational fluid dynamics, Engineering Applications of Computational Fluid Mechanics 2009, 3, 109-122.
- [20] Zaryankin A.E., Gribin V.G., Paramonov A.N., Noskov V.V., Mitrohova O.M., The influence of the opening angle of flat diffusers on their vibration state and ways of reducing these vibrations, Thermal Engineering 2012, 9, 22-27.
- [21] Prandtl L., Essentials of Fluid Dynamics, Hafner Publications, New York 1952.
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
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