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Three-dimensional structure and momentum transfer in a turbulent cylinder wake

Published online by Cambridge University Press:  10 September 1999

A. VERNET
Affiliation:
Escola Tecnica Superior d'Enginyeria Quimica, Universitat Rovira i Virgili, , Carretera de Salou, s/n, 43006 Tarragona, Catalunya, Spain
G. A. KOPP
Affiliation:
Boundary Layer Wind Tunnel Laboratory, Faculty of Engineering Science, The University of Western Ontario, London, Ontario, N6A 5B9, Canada
J. A. FERRÉ
Affiliation:
Escola Tecnica Superior d'Enginyeria Quimica, Universitat Rovira i Virgili, , Carretera de Salou, s/n, 43006 Tarragona, Catalunya, Spain
FRANCESC GIRALT
Affiliation:
Escola Tecnica Superior d'Enginyeria Quimica, Universitat Rovira i Virgili, , Carretera de Salou, s/n, 43006 Tarragona, Catalunya, Spain

Abstract

Simultaneous velocity and temperature measurements were made with rakes of sensors that sliced a slightly heated turbulent wake in the spanwise direction, at different lateral positions 150 diameters downstream of the cylinder. A pattern recognition analysis of hotter-to-colder transitions was performed on temperature data measured at the mean velocity half-width. The velocity data from the different ‘slices’ was then conditionally averaged based on the identified temperature events. This procedure yielded the topology of the average three-dimensional large-scale structure which was visualized with iso-surfaces of negative values of the second eigenvector of [S2+Ω2]. The results indicate that the average structure of the velocity fluctuations (using a triple decomposition of the velocity field) is found to be a shear-aligned ring-shaped vortex. This vortex ring has strong outward lateral velocities in its symmetry plane which are like Grant's mixing jets. The mixing jet region extends outside the ring-like vortex and is bounded by two foci separated in the spanwise direction and an upstream saddle point. The two foci correspond to what has been previously identified in the literature as the double rollers.

The ring vortex extracts energy from the mean flow by stretching in the mixing jet region just upstream of the ring boundary. The production of the small-scale (incoherent) turbulence by the coherent field and one-component energy dissipation rate occur just downstream of the saddle point within the mixing jet region. Incoherent turbulence energy is extracted from the mean flow just outside the mixing jet region, but within the core of the structure. These processes are highly three-dimensional with a spanwise extent equal to the mean velocity half-width.

When a double decomposition is used, the coherent structure is found to be a tube-shaped vortex with a spanwise extent of about 2.5l0. The double roller motions are integral to this vortex in spite of its shape. Spatial averages of the coherent velocity field indicate that the mixing jet region causes a deficit of mean streamwise momentum, while the region outside the foci of the double rollers has a relatively small excess of streamwise momentum.

Type
Research Article
Copyright
© 1999 Cambridge University Press

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