Dissipation Scalings in the Turbulent Boundary Layer at Moderate Reθ

We present an experimental and numerical study of the turbulent boundary layer at 1200 < R e θ < 3400 . We propose a combined approach that involves the use of a multi-hole pitot probe, hot-wire anemometry and direct numerical simulations, that allows to characterise the isotropy and the energ...

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Bibliographic Details
Published in:Flow, turbulence and combustion turbulence and combustion, 2022-01, Vol.108 (1), p.105-122
Main Authors: Obligado, M., Brun, C., Silvestrini, J. H., Schettini, E. B. C.
Format: Article
Language:English
Subjects:
Automotive Engineering
Boundary layer thickness
Direct numerical simulation
Energy dissipation
Engineering
Engineering Fluid Dynamics
Engineering Sciences
Engineering Thermodynamics
Fluid flow
Fluid- and Aerodynamics
Fluids mechanics
Heat and Mass Transfer
Homogeneity
Isotropy
Mechanics
Reynolds number
Robustness (mathematics)
Turbulence
Turbulent boundary layer
Velocity measurement
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Summary:We present an experimental and numerical study of the turbulent boundary layer at 1200 < R e θ < 3400 . We propose a combined approach that involves the use of a multi-hole pitot probe, hot-wire anemometry and direct numerical simulations, that allows to characterise the isotropy and the energy dissipation scalings of the flow in the outer layer, in the range 0.4 < y / δ < 0.75 , with y the vertical coordinate and δ the boundary layer thickness. We confirm previous results from the literature that show that for low values of R e θ (in our case R e θ < 2500 ), on the outer layer the dissipation constant C ε is Reynolds number dependent, following a R e λ - 1 law. This dependency seems to be robust, as the value of C ε collapses for previously reported direct numerical simulations and experiments with different incoming velocities. We also show that, while large scales of the flow are strongly anisotropic on the outer layer, the turbulence energy dissipation rate and the dissipation constant can still be characterised assuming local isotropy and homogeneity.
ISSN:1386-6184
1573-1987
DOI:10.1007/s10494-021-00270-1