Effects of free-stream turbulence on surface pressure fluctuations in a separation bubble

P. J. SAATHOFF; W. H. MELBOURNE

doi:10.1017/S0022112096004594

Abstract

Wind-tunnel experiments were conducted to investigate the cause of large pressure fluctuations near leading edges of sharp-edged bluff bodies. Measurements obtained with a blunt flat plate showed that very low pressures occur in a narrow region located approximately 0.25XR from the leading edge, where XR defines the distance from the leading edge to the mean reattachment location. This phenomenon occurs in the undisturbed flow as well as turbulent flow, although the magnitude of peak pressure fluctuations increases with both turbulence intensity, σu/u, and turbulence scale, LX.

Flow visualization experiments conducted with a high-speed cine-camera reveal the process that causes large pressure fluctuations in separation bubbles. This process is initiated when a perturbation in the approaching flow causes a roll-up of the separated shear layer, producing a strong vortex near the surface. Conditional sampling of pressure data was used to determine the spanwise length of the vortex. A significant increase in the spanwise correlation of pressure fluctuations occurs when the shear layer rolls up. Coherence measurements indicate that the spanwise length of vortices in the separation bubble is not directly related to longitudinal velocity fluctuations in the free-stream.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Li, Q.S Calderone, I and Melbourne, W.H 1999. Probabilistic characteristics of pressure fluctuations in separated and reattaching flows for various free-stream turbulence. Journal of Wind Engineering and Industrial Aerodynamics, Vol. 82, Issue. 1-3, p. 125.

Mathey, Fabrice Fröhlich, Jochen and Rodi, Wolfgang 1999. Industrial and Environmental Applications of Direct and Large-Eddy Simulation. Vol. 529, Issue. , p. 153.

Lei, C. Cheng, L. and Kavanagh, K. 1999. Re-examination of the effect of a plane boundary on force and vortex shedding of a circular cylinder. Journal of Wind Engineering and Industrial Aerodynamics, Vol. 80, Issue. 3, p. 263.

Suksangpanomrung, A. Djilali, N. and Moinat, P. 2000. Large-eddy simulation of separated flow over a bluff rectangular plate. International Journal of Heat and Fluid Flow, Vol. 21, Issue. 5, p. 655.

Djilali, N. and Suksangpanomrung, A. 2002. High Performance Computing Systems and Applications. Vol. 657, Issue. , p. 481.

Vlachos, P.P. and Hajj, M.R. 2002. A time-resolved DPIV study of the unsteady character of the flow over a surface-mounted prism. Journal of Wind Engineering and Industrial Aerodynamics, Vol. 90, Issue. 4-5, p. 543.

Tieleman, Henry W. 2003. Wind tunnel simulation of wind loading on low-rise structures: a review. Journal of Wind Engineering and Industrial Aerodynamics, Vol. 91, Issue. 12-15, p. 1627.

Tieleman, Henry W. Ge, Zhongfu Hajj, Muhammad R. and Reinhold, Timothy A. 2003. Pressures on a surface-mounted rectangular prism under varying incident turbulence. Journal of Wind Engineering and Industrial Aerodynamics, Vol. 91, Issue. 9, p. 1095.

Hudy, Laura M. Naguib, Ahmed M. and Humphreys, William M. 2003. Wall-pressure-array measurements beneath a separating/reattaching flow region. Physics of Fluids, Vol. 15, Issue. 3, p. 706.

Stieger, R. D. Hollis, David and Hodson, H. P. 2004. Unsteady Surface Pressures Due to Wake-Induced Transition in a Laminar Separation Bubble on a Low-Pressure Cascade. Journal of Turbomachinery, Vol. 126, Issue. 4, p. 544.

Yang, Zhiyin and Abdalla, Ibrahim E. 2005. Effects of free-stream turbulence on large-scale coherent structures of separated boundary layer transition. International Journal for Numerical Methods in Fluids, Vol. 49, Issue. 3, p. 331.

Gross, Andreas and Fasel, Hermann 2005. Turbulence Modeling for Low Pressure Turbine Blades.

Kim, Kyung Chun Ji, Ho Seong and Seong, Seung Hak 2005. Effects of turbulent boundary layer thickness on flow around a low-rise rectangular prism. Wind and Structures, Vol. 8, Issue. 6, p. 455.

Sarkar, S. and Voke, Peter R. 2006. Large-Eddy Simulation of Unsteady Surface Pressure Over a Low-Pressure Turbine Blade due to Interactions of Passing Wakes and Inflexional Boundary Layer. Journal of Turbomachinery, Vol. 128, Issue. 2, p. 221.

LIM, HEE CHANG CASTRO, IAN P. and HOXEY, ROGER P. 2007. Bluff bodies in deep turbulent boundary layers: Reynolds-number issues. Journal of Fluid Mechanics, Vol. 571, Issue. , p. 97.

Scott, Thomas and Banks, David 2008. Pulp CFD: Hollywood, the Elephant, and the Acronym. p. 1.

Reul, Nicolas Branger, Hubert and Giovanangeli, Jean-Paul 2008. Air Flow Structure Over Short-gravity Breaking Water Waves. Boundary-Layer Meteorology, Vol. 126, Issue. 3, p. 477.

Fu, J.Y. Li, Q.S. Wu, J.R Xiao, Y.Q. and Song, L.L. 2008. Field measurements of boundary layer wind characteristics and wind-induced responses of super-tall buildings. Journal of Wind Engineering and Industrial Aerodynamics, Vol. 96, Issue. 8-9, p. 1332.

Gavalda, X. Ferrer-Gener, J. Kopp, Gregory A. Giralt, Francesc and Galsworthy, J. 2009. Simulating pressure coefficients on a circular cylinder at Re=106 by cognitive classifiers. Computers & Structures, Vol. 87, Issue. 13-14, p. 838.

Haan, F. L. and Kareem, A. 2009. Anatomy of Turbulence Effects on the Aerodynamics of an Oscillating Prism. Journal of Engineering Mechanics, Vol. 135, Issue. 9, p. 987.

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Effects of free-stream turbulence on surface pressure fluctuations in a separation bubble

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