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Experiments in Fluids

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01.12.2012 | Research Article

The role of shape and relative submergence on the structure of wakes of low-aspect-ratio wall-mounted bodies

verfasst von: Seyed M. Hajimirzaie, Craig J. Wojcik, James H. J. Buchholz

Erschienen in: Experiments in Fluids | Ausgabe 6/2012

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Abstract

The effects of shape and relative submergence (the ratio of flow depth to obstacle height, d/H) are investigated on the wakes around four different low-aspect-ratio wall-mounted obstacles at Re_H = 17,800: semi-ellipsoids with the major axes of the base ellipses aligned in the streamwise and transverse directions, and two cylinders with aspect ratios matching the ellipsoids (H/D = 0.89 and 0.67, where D is the maximum transverse dimension). Particle Image Velocimetry was used to interrogate the flow. Streamwise features observed in the mean wake include counter-rotating distributions of vorticity inducing downwash (tip structures), upwash (base structures), and horseshoe vortices. In particular, the relatively subtle change in geometry produced by the rotation of the ellipsoid from the streamwise to the transverse orientation results in a striking modification of the mean streamwise vorticity distribution in the wake. Tip structures are dominant in the former case, while base structures are dominant in the latter. A vortex skeleton model of the wake is proposed in which arch vortex structures, shed from the obstacle, are deformed by the competing mechanisms of Biot-Savart self-induction and the external shear flow. The selection of tip or base structures in the ellipsoid wakes is caused by tilting of the arch structures either upstream or downstream, respectively, which is governed by ellipsoid curvature. An inverse relationship was observed between the relative submergence and the strength of the base structures for the ellipsoids, with a dominant base structure observed for d/H = 1 in both cases. These results demonstrate a means by which to achieve significant modifications to flow structure and thereby also to transport mechanisms in the flow. Therefore, this work provides insight into the modeling and control of flow over wall-mounted bodies.

Vorheriger Artikel Turbulence measurements in a rectangular mesoscale confined impinging jets reactor

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AbuOmar MM, Martinuzzi RJ (2008) Vortical structures around a surface-mounted pyramid in a thin boundary layer. J Wind Eng Ind Aerodyn 96:769–778CrossRef

Baker CJ (1979) The laminar horseshoe vortex. J Fluid Mech 95(2):347–367CrossRef

Baker CJ (1980) The turbulent horseshoe vortex. J Wind Eng Ind Aerodyn 6:9–23CrossRef

Ballio F, Bettoni C, Franzetti S (1998) A survey of time-averaged characteristics of laminar and turbulent horseshoe vortices. ASME J Fluids Eng 120:233–242CrossRef

Bearman PW, Morel T (1983) Effect of free stream turbulence on the flow around bluff bodies. Prog Aerospace Sci 20:97–123CrossRef

Becker S, Lienhart H, Durst F (2002) Flow around three-dimensional obstacles in boundary layers. J Wind Eng Ind Aerodyn 90:265–279CrossRef

Bourgeois J, Hosseini Z, Martinuzzi R (2011a) Half-loop and full-loop shedding in the wake of wall-mounted square cylinders due to boundary layer-wake interaction. Abstract Submitted for the DFD11 Meeting of The American Physical Society Abstract ID: BAPS.2011.DFD.R11.10

Bourgeois JA, Sattari P, Martinuzzi RJ (2011b) Alternating half-loop shedding in the turbulent wake of a finite surface-mounted square cylinder with a thin boundary layer. Phys Fluids 23(095101):1–14

Castro IP, Vosper S, Paisley M, Hayden P (2001) Vortex shedding behind tapered obstacles in neutral and stratified flow. Dyn Atmos Oceans 34:145–163CrossRef

Chyu M, Natarajan V (1996) Heat transfer on the base of threedimensional protruding elements. Int J Heat Mass Transfer 39:2925–2935MATHCrossRef

Etzold F, Fiedler H (1976) The near-wake structure of a cantilevered cylinder in a cross flow. J Z Flugwiss 24:77–82

Farell C, Carrasquel S, Guven O, Patel V (1977) Effect of windtunnel walls on the flow past circular cylinders and cooling tower models. ASME J Fluid Eng 99:470–479CrossRef

Hain R, Kahler CJ, Michaelis D (2008) Tomographic and time resolved piv measurements on a finite cylinder mounted on a flat plate. Exp Fluids 45:715–724CrossRef

Hunt JCR, Abell CJ, Peterka JA, Woo H (1978) Kinematical studies of the flows around free or surface-mounted obstacles. J Fluid Mech 86:179–200CrossRef

Hussein HJ, Martinuzzi RJ (1996) Energy balance of turbulent flow around a surface mounted cube placed in a channel. Phys Fluids 8:764–780CrossRef

Kawamura T, Hiwada M, Hibino T, Mabuchi I, Kumuda M (1984) Flow around a finite circular cylinder on a flat plate. Bull JSME 27(232):2142–2151CrossRef

Krajnović S (2008) Large eddy simulation of the flow over a three-dimensional hill. Flow Turbulence Combust 81:189–204MATHCrossRef

Krajnović S (2011) Flow around a tall finite cylinder explored by large eddy simulation. J Fluid Mech 676:294–317MathSciNetMATHCrossRef

Leder A (2003) 3d-flow structures behind truncated circular cylinders. In: Proceedings of the 4th ASME/JSME joint fluids engineering conference, FEDSM2003-45083, Honolulu, Hawaii

Lee BE (1975) The effect of turbulence on the surface pressure field of a square prism. J Fluid Mech 69:263–282CrossRef

Martinuzzi R (2008) Dual vortex structure shedding from low aspect ratio, surface-mounted pyramids. J Turbulence 9:1–16CrossRef

Martinuzzi R, Tropea C (1993) The flow around surface-mounted, prismatic obstacles placed in a fuly-developed channel flow. ASME J Fluids Eng 115:85–92CrossRef

Martinuzzi RJ, AbuOmar M (2003) Study of the flow around surface-mounted pyramids. Exp Fluids 34:379–389CrossRef

Mason PJ, Morton BR (1987) Trailing vortices in the wakes of surface-mounted obstacles. J Fluid Mech 175:247–293CrossRef

Nakamura N (1993) Bluff body aerodynamics and turbulence. J Wind Eng Ind Aerodyn 49:65–78CrossRef

Nakato T, Christensen J, Schonhoff B (2007) Freshwater mussel survey in pool 16, the mississippi river, near fairport, iowa: R.m. 463.5—r.m. 464.1, approximately. IIHR technical report 464, The University of Iowa, IIHR—Hydroscience & Engineering

Narasimha R, Prasad SN (1994) Leading edge shape for flat plate boundary layer studies. Exp Fluids 17:358–360CrossRef

Okamoto S, Sunabashiri Y (1992) Vortex shedding from a circular cylinder of finite length placed on a ground plane. ASME J Fluids Eng 112:512–521CrossRef

Ozturk N, Akkoca A, Sahin B (2008) Piv measurements of flow past a confined cylinder. Exp Fluids 44:1001–1014CrossRef

Palau-Salvador G, Stoesser T, Fröhlich J, Kappler M, Rodi W (2009) Large eddy simulations and experiments of flow around finite-height cylinders. Flow Turbulence Combust 84(2):239–275CrossRef

Papanicolaou AN, Kramer C (2006) Flow and sediment laboratory measurements over unsubmerged roughness elements. ASCE Conf Proc 101061/40856(200)165

Park C, Lee S (2004) Effects of free-end corner shape on flow structure around a finite cylinder. J Fluid Struct 19:141–158CrossRef

Pattenden RJ, Turnock SR, Bressloff NW (2002) An experimental and computational study of 3-d unsteady flow features found behind a cylinder. Third Fluids Engineering Summer Meeting, Japan

Pattenden RJ, Turnock SR, Zhang Z (2005) Measurements of the flow over a low-aspect-ratio cylinder mounted on a ground plane. Exp Fluids 39:10–21CrossRef

Roh SC, Park SO (2003) Vortical flow over the free end surface of a finite circular cylinder mounted on a flat plate. Exp Fluids 34:63–67

Sadeque MAF, Rajaratnam N, Loewen MR (2008) Flow around cylinders in open channels. J Eng Mech 134(1):60–71CrossRef

Sadeque MAF, Rajaratnam N, Loewen MR (2009) Effects of bed roughness on flow around bed-mounted cylinders in open channels. J Eng Mech 135(2):100–110CrossRef

Sakamoto H, Arie M (1983) Vortex shedding from a rectangular prism and a circular cylinder placed vertically in a turbulent boundary layer. J Fluid Mech 126:147–165CrossRef

Savory E, Toy N (1986) Hemispheres and hemisphere-cylinders in turbulent boundary layers. J Wind Eng Ind Aerodyn 23:345–364CrossRef

Savory E, Toy N (1988) The separated shear layers associated with hemispherical bodies in turbulent boundary layers. J Wind Eng Ind Aerodyn 28:291–300CrossRef

Shamloo H, Rajaratman N, Katopodis C (2001) Hydraulics of simple habitat structures. J Hydraulic Res 39(4):351–366CrossRef

Smith RB, Grubišić V (1993) Aerial observations of hawaii’s wake. J Atmos Sci 50(22):3728–3750CrossRef

Sousa JMM, Pereira JCF (2004) DPIV study of the effect of a gable roof on teh flow structure around a surface-mounted cubic obstacle. Exp Fluids 37:409–418CrossRef

Strom K, Papanicolaou A (2007) ADV measurements around a cluster microform in a shallow mountain stream. J Hydraulic Eng 133(12):1379–1389CrossRef

Sumner D, Heseltine JL, Dansereau OJP (2004) Wake structure of a finite circular cylinder of small aspect ratio. Exp Fluids 37:720–730CrossRef

Tanaka S, Murata S (1999) An investigation of the wake structure and aerodynamic characteristics of a finite circular cylinder. Bull JSME 42:178–187

Vosper SB, Castro I, Snyder W, Mobbs S (1999) Experimental studies of strongly stratified flow past three-dimensional orography. J Fluid Mech 390:223–249MATHCrossRef

Wang HF, Zhou Y (2009) The finite-length square cylinder near wake. J Fluid Mech 638:453–490MATHCrossRef

Wang HF, Zhou Y, Chan CK, Lam KS (2006) Effect of initial conditions on interaction between a boundary layer and a wall-mounted finite-length-cylinder wake. Phys Fluids 18:453–490

Westerweel J (2000) Theoretical analysis of the measurement precision in particle image velocimetry. Exp Fluids 29:S3-S12CrossRef

Zdravkovich MM (1997) Flow around circular cylinders, vol 2: applications. Oxford University Press,

Titel: The role of shape and relative submergence on the structure of wakes of low-aspect-ratio wall-mounted bodies
verfasst von: Seyed M. Hajimirzaie
Craig J. Wojcik
James H. J. Buchholz
Publikationsdatum: 01.12.2012
Verlag: Springer-Verlag
Erschienen in: Experiments in Fluids / Ausgabe 6/2012
Print ISSN: 0723-4864
Elektronische ISSN: 1432-1114
DOI: https://doi.org/10.1007/s00348-012-1406-1

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