Dual-plane PIV technique to determine the complete velocity gradient tensor in a turbulent boundary layer

Simultaneous dual-plane PIV experiments, which utilized three cameras to measure velocity components in two differentially separated planes, were performed in streamwise-spanwise planes in the log region of a turbulent boundary layer at a moderate Reynolds number (Re= 1100). Stereoscopic data were o...

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Veröffentlicht in:	Experiments in fluids 2005-08, Vol.39 (2), p.222-231
Hauptverfasser:	GANAPATHISUBRAMANI, Bharathram, LONGMIRE, Ellen K, MARUSIC, Ivan, POTHOS, Stamatios
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Sprache:	eng
Schlagworte:	Biological and medical applications Boundary layer and shear turbulence Cameras Computational fluid dynamics Exact sciences and technology Fluid dynamics Fluid flow Fundamental areas of phenomenology (including applications) Instrumentation for fluid dynamics Marine Mathematical analysis Metrological applications Optics Physics Planes Turbulence Turbulent flow Turbulent flows, convection, and heat transfer Vorticity
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container_title	Experiments in fluids
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creator	GANAPATHISUBRAMANI, Bharathram LONGMIRE, Ellen K MARUSIC, Ivan POTHOS, Stamatios
description	Simultaneous dual-plane PIV experiments, which utilized three cameras to measure velocity components in two differentially separated planes, were performed in streamwise-spanwise planes in the log region of a turbulent boundary layer at a moderate Reynolds number (Re= 1100). Stereoscopic data were obtained in one plane with two cameras, and standard PIV data were obtained in the other with a single camera. The scattered light from the two planes was separated onto respective cameras by using orthogonal polarizations. The acquired datasets were used in tandem with continuity to compute all 9 velocity gradients, the complete vorticity vector and other invariant quantities. These derived quantities were employed to analyze and interpret the structural characteristics and features of the boundary layer. Sample results of the vorticity vector are consistent with the presence of hairpin-shaped vortices inclined downstream along the streamwise direction. These vortices envelop low speed zones and generate Reynolds shear stress that enhances turbulence production. Computation of inclination angles of individual eddy cores using the vorticity vector suggests that the most probable inclination angle is 35 degree to the streamwise-spanwise plane with a resulting projected eddy inclination of 43 degree in the streamwise-wall-normal plane.
doi_str_mv	10.1007/s00348-005-1019-z
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Stereoscopic data were obtained in one plane with two cameras, and standard PIV data were obtained in the other with a single camera. The scattered light from the two planes was separated onto respective cameras by using orthogonal polarizations. The acquired datasets were used in tandem with continuity to compute all 9 velocity gradients, the complete vorticity vector and other invariant quantities. These derived quantities were employed to analyze and interpret the structural characteristics and features of the boundary layer. Sample results of the vorticity vector are consistent with the presence of hairpin-shaped vortices inclined downstream along the streamwise direction. These vortices envelop low speed zones and generate Reynolds shear stress that enhances turbulence production. 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subjects	Biological and medical applications Boundary layer and shear turbulence Cameras Computational fluid dynamics Exact sciences and technology Fluid dynamics Fluid flow Fundamental areas of phenomenology (including applications) Instrumentation for fluid dynamics Marine Mathematical analysis Metrological applications Optics Physics Planes Turbulence Turbulent flow Turbulent flows, convection, and heat transfer Vorticity
title	Dual-plane PIV technique to determine the complete velocity gradient tensor in a turbulent boundary layer
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