Abstract
This paper presents results of an experimental investigation on the flow in a trapped vortex cell, embedded into a flat plate, and interacting with a zero-pressure-gradient boundary layer. The objective of the work is to describe the flow features and elucidate some of the governing physical mechanisms, in the light of recent investigations on flow separation control using vortex cells. Hot-wire velocity measurements of the shear layer bounding the cell and of the boundary layers upstream and downstream are reported, together with spectral and correlation analyses of wall-pressure fluctuation measurements. Smoke flow visualisations provide qualitative insight into some relevant features of the internal flow, namely a large-scale flow unsteadiness and possible mechanisms driving the rotation of the vortex core. Results are presented for two very different regimes: a low-Reynolds-number case where the incoming boundary layer is laminar and its momentum thickness is small compared to the cell opening, and a moderately high-Reynolds-number case, where the incoming boundary layer is turbulent and the ratio between the momentum thickness and the opening length is significantly larger than in the first case. Implications of the present findings to flow control applications of trapped vortex cells are also discussed.
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References
Adkins RC (1975) A short diffuser with low pressure loss. J Fluids Eng 97:297–302
Albensoeder S, Kuhlmann HC, Rath HJ (2001) Three-dimensional centrifugal-flow instabilities in the lid-driven-cavity problem. Phys Fluids 13(1):121–135
Baranov PA, Guvernyuk SV, Zubin MA, Isaev SA (2000) Numerical and physical modeling of the circulation flow in a vortex cell in the wall of a rectilinear channel. Fluid Dyn 35(5):663–673
Basley J, Pastur LR, Lusseyran F, Faure TM, Delprat N (2010) Experimental investigation of global structures in an incompressible cavity flow using time-resolved PIV. Exp Fluids 50(4):905–918
Bendat J, Piersol A (1986) Random data: analysis and measurement procedures. Wiley, New York
Brès G, Colonius T (2008) Three-dimensional instabilities in compressible flow over open cavities. J Fluid Mech 599:309–339
Bunyakin AV, Chernyshenko SI, Stepanov GY (1998) High-Reynolds-number Batchelor-model asymptotics of a flow past an aerofoil with a vortex trapped in a cavity. J Fluid Mech 358(1):283–297
Chatellier L, Laumonier J, Gervais Y (2004) Theoretical and experimental investigations of low Mach number turbulent cavity flows. Exp Fluids 36(5):728–740
Chernyshenko SI, Castro IP, Hetsch T, Iollo A, Minisci E, Savelsberg R (2008) Vortex cell shape optimization for separation control. In: 8th ECCOMAS, European congress on computational methods in applied sciences and engineering, 30 June–4 July 2008, Venice, Italy
Chernyshenko S, Galletti B, Iollo A, Zannetti L (2003) Trapped vortices and a favorable pressure gradient. J Fluid Mech 482:235–255
Choudhry A, Arjomandi M, Kelso R (2016) Methods to control dynamic stall for wind turbine applications. Renew Energy 86:26–37
De Gregorio F, Fraioli G (2008) Flow control on a high thickness airfoil by a trapped vortex cavity. In: 14th international symposium on applications of laser techniques to fluid mechanics, 7–10 July 2008, Lisbon, Portugal
de Vicente J, Basley J, Meseguer-Garrido F, Soria J, Theofilis V (2014) Three-dimensional instabilities over a rectangular open cavity: from linear stability analysis to experimentation. J Fluid Mech 748:189–220
Donelli RS, Iannelli P, Iuliano E, De Rosa D (2009b) Suction optimization on thick airfoil to trap vortices. In: XIX Congresso AIMETA, 14–17 September 2009, Ancona, Italy
Donelli R, Chernyshenko S, Iannelli P, Iollo A, Zannetti L (2009a) Flow models for a vortex cell. AIAA J 2(47):451–467
Faure TM, Adrianos P, Lusseyran F, Pastur L (2006) Visualizations of the flow inside an open cavity at medium range Reynolds numbers. Exp Fluids 42(2):169–184
Faure T, Pastur L, Lusseyran F, Fraigneau Y, Bisch D (2009) Three-dimensional centrifugal instabilities development inside a parallelepipedic open cavity of various shape. Exp Fluids 47(3):395–410
Faure TM (2014) Velocity field and parametric analysis of a subsonic, medium-reynolds number cavity flow. Exp Fluids 55(11):1–18
Garcia-Sagrado A, Hynes T (2011) Stochastic estimation of flow near the trailing edge of a NACA0012 airfoil. Exp Fluids 51:1057–1071
Gharib M, Roshko A (1987) The effect of flow oscillations on cavity drag. J Fluid Mech 177:501–530
Hokpunna A, Manhart M (2007) A large-eddy simulation of vortex cell flow with incoming turbulent boundary layer. Int J Mech Syst Sci Eng 1:123–128
Kasper W (1974) Aircraft wing with vortex generation. U.S Patent No. 3831885
Kuhlmann HC, Wanschura M, Rath HJ (1997) Flow in two-sided lid-driven cavities: non-uniqueness, instabilities, and cellular structures. J Fluid Mech 336:267–299
Kuo Ch, Huang Sh (2001) Influence of flow path modification on oscillation of cavity shear layer. Exp Fluids 31(2):162–178
Larchevêque L, Sagaut P, Labbé O (2007) Large-eddy simulation of a subsonic cavity flow including asymmetric three-dimensional effects. J Fluid Mech 577:105–126
Lasagna D, Donelli R, De Gregorio F, Iuso G (2011) Effects of a trapped vortex cell on a thick wing airfoil. Exp Fluids 51(5):1369–1384
Lasagna D, Orazi M, Iuso G (2013) Multi-time delay, multi-point linear stochastic estimation of a cavity shear layer velocity from wall-pressure measurements. Phys Fluids 25(1):017101
Lawson SJ, Barakos GN (2011) Review of numerical simulations for high-speed, turbulent cavity flows. Prog Aerosp Sci 47(3):186–216
Mariotti A, Grozescu A, Buresti G, Salvetti M (2013) Separation control and efficiency improvement in a 2D diffuser by means of contoured cavities. Eur J Mech B Fluid 41:138–149
Mariotti A, Buresti G, Salvetti M (2014) Control of the turbulent flow in a plane diffuser through optimized contoured cavities. Eur J Mech B Fluid 48:254–265
Maull DJ, East LF (1963) Three-dimensional flow in cavities. J Fluid Mech 16:620–632
Olsman W, Willems J, Hirschberg A, Colonius T, Trieling R (2011) Flow around a NACA0018 airfoil with a cavity and its dynamical response to acoustic forcing. Exp Fluids 51(2):493–509
Ringleb FO (1961) Separation control by trapped vortices. In: Lachmann GV (ed) Boundary layer and flow control. Pergamon Press, Oxford
Rockwell D, Knisely C (1980) Observations of the three-dimensional nature of unstable flow past a cavity. Phys Fluids 23:425–431
Rockwell D, Naudascher E (1978) Review—self-sustaining oscillations of flow past cavities. J Fluid Eng 100(2):152–165
Rowley C, Colonius T, Basu A (2001) On self-sustained oscillations in two dimensional compressible flow over rectangular cavities. J Fluid Mech 455:315–345
Savelsberg R, Castro I (2008) Vortex flows in open cylindrical-section cavities. Exp Fluids 46(3):485–497
Savitsky A, Schukin L, Kareljn V (1995) Method for control of the boundary layer on the aerodynamic surface of an aircraft, and the aircraft provided with boundary layer control system. U.S Patent No. 5417391
Tutty O, Savelsberg R, Castro IP (2012) Three-dimensional flow in circular cavities of large spanwise aspect ratio. J Fluid Mech 707:551–574
Tutty O, Buffoni M, Kerminbekov R, Donelli R, De Gregorio F, Rogers E (2013) Control of flow with trapped vortices: theory and experiments. Int J Flow Control 5(2):89–110
Vuddagiri A, Samad A (2013) Vortex trapping by different cavities on an airfoil. Wind Eng 37(5):469–482
Zannetti L (2006) Vortex equilibrium in flows past bluff bodies. J Fluid Mech 562:151–171
Zhang K, Naguib AM (2011) Effect of finite cavity width on flow oscillation in a low-Mach-number cavity flow. Exp Fluids 51(5):1209–1229
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Lasagna, D., Iuso, G. Flow regimes in a trapped vortex cell. Exp Fluids 57, 36 (2016). https://doi.org/10.1007/s00348-016-2125-9
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DOI: https://doi.org/10.1007/s00348-016-2125-9