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Experiments in Fluids

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01.01.2014 | Research Article

High Reynolds number flow over a backward-facing step: structure of the mean separation bubble

verfasst von: Pankaj M. Nadge, R. N. Govardhan

Erschienen in: Experiments in Fluids | Ausgabe 1/2014

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Abstract

In the present paper, the structure of the mean separation bubble downstream of the backward-facing step is studied at large Reynolds numbers. The flow over the step at these Reynolds numbers is turbulent with the presence of unsteady large-scale structures. There is however a well-defined time-averaged mean separation bubble. We study the effect of Reynolds number and expansion ratio on the structure of this mean separation bubble, the expansion ratio being the primary geometrical parameter in this case. Using PIV measurements within the separation bubble, parameters such as the reattachment length, mean velocity field, and the turbulent stresses are systematically mapped out. These measurements show that there exists a high Reynolds number separation bubble structure that is nearly independent of both Reynolds number and expansion ratio, as long as the Reynolds numbers are large (Re > 36,000 based on step height). Within this large Reynolds number separation bubble, the normalized mean velocity field and the normalized turbulent stresses are found to be similar for all expansion ratio cases studied. Using these measurements, the streamwise force balance of the mean separation bubble is studied. The analysis of the data shows that in this case, the contribution to the streamwise force from both the Reynolds normal and shear stress is significant, although the Reynolds shear stress contribution is larger. Differences in the force contributions from other geometries are highlighted.

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Adams EW, Johnston JP (1988) Effects of the separating shear layer on the reattachment flow structure part 2: reattachment length and wall shear stress. Exp Fluid 6:493–499

Arie M, Rouse H (1956) Experiments on two-dimensional flow over a normal wall. J Fluid Mech 1:129–141. doi:10.1017/S0022112056000093 CrossRef

Armaly BF, Durst F, Pereira JCF, Schonung B (1983) Experimental and theoretical investigation of backward-facing step flow. J Fluid Mech 127:473–496CrossRef

Baker S (1975) Regions of recirculating flow associated with two-dimensional steps. PhD Thesis, Dept of Civil Eng, University of Surrey

Balchandar S, Mittal R, Najjar FM (1997) Properties of the mean recirculation region in the wakes of two-dimensional bluff bodies. J Fluid Mech 351:167–199CrossRef

Barkley D, Gomes MGM, Henderson RD (2002) Three-dimensional instability in flow over a backward-facing step. J Fluid Mech 473:167–190CrossRefMATHMathSciNet

Barri M, El Khoury GK, Andersson HI, Pettersen B (2010) Dns of backward-facing step flow with fully turbulent inflow. Int J Numer Methods Fluids 64(7):777–792. doi:10.1002/fld.2176 MATHMathSciNet

Beaudoin JF, Cadot O, Aider JL, Wesfreid JE (2004) Three-dimensional stationary flow over a backward-facing step. Eur J Mech B Fluids 23(1):147–155CrossRefMATH

Biswas G, Breuer M, Durst F (2004) Backward-facing step flows for various expansion ratios at low and moderate reynolds numbers. Trans ASME J Fluids Eng 126:362–374CrossRef

Cantwell B, Coles D (1983) An experimental study of entrainment and transport in the turbulent near wake of a circular cylinder. J Fluid Mech 136:321–374. doi:10.1017/S0022112083002189 CrossRef

Chandrsuda C (1975) A reattaching turbulent shear layer in incompressible flow. PhD Thesis, Departmentt of Aeronautics, Imperial College of Science and Technology

Chun KB, Sung HJ (1996) Control of turbulent separated flow over a backward-facing step by local forcing. Exp Fluid 21(6):417–426CrossRef

De Brederode V, Bradshaw P (1972) Three-dimensional flow in nominally two-dimensional separation bubbles. I. Flow behind a rearward-facing step. IC Aero Rep 72-19 Imperial College, London

Driver DM, Seegmiller HL (1985) Features of a reattaching turbulent shear-layer in divergent channel flow. AIAA J 23(2):163–171. doi:10.2514/3.8890 CrossRef

Durst F, Tropea C (1981) Turbulent backward-facing step flows in two-dimensional ducts and channels. In: Proceedings of turbulent shear flow 3 symposium Davis September 1981

Durst F, Tropea C (1982) Flows over two-dimensional backward-facing steps. Structure of complex turbulent shear flow: IUTAM-symposium, Marseille, France, August 31–September 3, 1982

Eaton JK, Johnston JP (1980) Turbulent flow reattachment: an experimental study of the flow and structure behind a backward-facing setp. Rept MD-39, Dept of Mech Eng, Stanford University, Stanford, CA

Eaton JK, Johnston JP (1981) Review of research on subsonic turbulent flow reattachment. AIAA J 19(9):1093–1100CrossRef

Etheridge DW, Kemp PH (1978) Measurements of turbulent flow downstream of a rearward-facing step. J Fluid Mech 86:545–566. doi:10.1017/S0022112078001275 CrossRef

Feng K, Ying-zheng L, Wei-zhe W, Han-ping C (2006) Wall pressure fluctuations of turbulent flow over backward-facing step with and without entrainment: microphone array measurement. J Hydrodyn 18(4):393–396. doi:10.1016/S1001-6058(06)60110-8 CrossRef

Furuichi N, Hachiga T, Kumada M (2004) An experimental investigation of a large-scale structure of a two-dimensional backward-facing step by using advanced multi-point ldv. Exp Fluids 36(2):274–281. doi:10.1007/s00348-003-0718-6 CrossRef

Hudy LM, Naguib A, William MH (2007) Stochastic estimation of a separated-flow field using wall-pressure-array measurements. Phys Fluids 19(2):024103. doi:10.1063/1.2472507 CrossRef

Jovic S, Driver D (1995) Reynolds number effect on the skin friction in separated flows behind a backward-facing step. Exp Fluids 18(6):464–467. doi:10.1007/BF00208471 CrossRef

Kaiktsis L, Karniadakis GE, Orszag SA (1991) Onset of 3-dimensionality, equilibrium and early transition in flow over a backward-facing step. J Fluid Mech 231:501–528CrossRefMATH

Kang SW, Choi H (2002) Suboptimal feedback control of turbulent flow over a backward-facing step. J Fluid Mech 463:201–227CrossRefMATH

Kasagi N, Matsunaga A (1995) Three-dimensional particle-tracking velocimetry measurement of turbulence statistics and energy budget in a backward-facing step flow. Int J Heat Fluid Flow 16(6):477–485. doi:10.1016/0142-727X(95)00041-N CrossRef

Kim J, Kline SJ, Johnston JP (1978) Investigation of separation and reattachment of a turbulent shear layer: flow over a backward-facing step. Rept MD-37, Dept of Mech Eng, Stanford University, Stanford, CA

Kostas J, Soria J, Chong MS (2002) Particle image velocimetry measurements of a backward-facing step flow. Exp Fluid 33(6):838–853CrossRef

Kuehn DM (1980) Effects of adverse pressure-gradient on the incompressible re-attaching flow over a rearward-facing step. AIAA J 18(3):343–344CrossRefMathSciNet

Le H, Moin P, Kim J (1997) Direct numerical simulation of turbulent flow over a backward-facing step. J Fluid Mech 330:349–374CrossRefMATH

Leder A (1991) Dynamics of fluid mixing in separated flows. Phys Fluids A 3(7):1741–1748. doi:10.1063/1.857953 CrossRef

Lee I, Ahn SK, Sung HJ (2004) Three-dimensional coherent structure in a separated and reattaching flow over a backward-facing step. Exp Fluid 36(3):373–383. doi:10.1007/s00348-003-0367-6 CrossRef

Narayanan MA, Khadgi YN, Viswanath PR (1974) Similarities in pressure distribution in separated flow behind backward-facing steps. Aeronaut Q 25:305–312

Nie JH, Armaly BF (2004) Reverse flow regions in three-dimensional backward-facing step flow. Intl J Heat Mass Transf 47:4713–4720CrossRef

Otugen MV (1991) Expansion-ratio effects on the separated shear-layer and reattachment downstream of a backward-facing step. Exp Fluid 10(5):273–280CrossRef

Raffel M, Willert C, Kompenhans J (1998) Particle image velocimetry: a practical guide. Spinger, BerlinCrossRef

Roshko A (1993) Free shear layers base pressure and bluff-body drag In: Proceedings of symposium on developement in fluid dynamics and aerospace engineering. Bangalore, India, December 9–10, 1993

Scarano F, Benocci C, Riethmuller ML (1999) Pattern recognition analysis of the turbulent flow past a backward facing step. Phys Fluids 11(12):3808–3818CrossRefMATH

Schram C, Rambaud P, Riethmuller M (2004) Wavelet based eddy structure eduction from a backward facing step flow investigated using particle image velocimetry. Exp Fluid 36:233–245. doi:10.1007/s00348-003-0695-9 CrossRef

Spazzini PG, Iuso G, Onorato M, Zurlo N, Di Cicca GM (2001) Unsteady behavior of back-facing step flow. Exp Fluids 30:551–561

Sychev V (1982) Asymptotic theory of separation flows. Fluid Dyn 17(2):179–188CrossRef

Tani I, Iuchi M, Komoda H (1961) Experimental investigation of flow separation associated with a step or groove. Report No 364, Aero Research Institute, University of Tokyo

Tylli N, Kaiktsis L, Ineichen B (2002) Sidewall effects in flow over a backward-facing step: experiments and numerical simulations. Phys Fluids 14:3835–3845CrossRef

Westphal RV, Johnston JP, Eaton JK (1984) Experimental study of flow reattachment in a single-sided sudden expansion. NASA CR-3765

Williams PT, Baker AJ (1997) Numerical-solutions of laminar flow over a 3D backward-facing step. Int J Numer Methods Fluids 24:1159–1183CrossRefMATH

Titel: High Reynolds number flow over a backward-facing step: structure of the mean separation bubble
verfasst von: Pankaj M. Nadge
R. N. Govardhan
Publikationsdatum: 01.01.2014
Verlag: Springer Berlin Heidelberg
Erschienen in: Experiments in Fluids / Ausgabe 1/2014
Print ISSN: 0723-4864
Elektronische ISSN: 1432-1114
DOI: https://doi.org/10.1007/s00348-013-1657-5

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