Abstract
Turbulent flow separation induced by a protuberance on one of the walls of an otherwise planar channel is investigated using direct numerical simulations. Different bulge geometries and Reynolds numbers – with the highest friction Reynolds number simulation reaching a peak of $Re_{\unicode[STIX]{x1D70F}}=900$ – are addressed to understand the effect of the wall curvature and of the Reynolds number on the dynamics of the recirculating bubble behind the bump. Global quantities reveal that most of the drag is due to the form contribution, whilst the friction contribution does not change appreciably with respect to an equivalent planar channel flow. The size and position of the separation bubble strongly depends on the bump shape and the Reynolds number. The most bluff geometry has a larger recirculation region, whilst the Reynolds number increase results in a smaller recirculation bubble and a shear layer more attached to the bump. The position of the reattachment point only depends on the Reynolds number, in agreement with experimental data available in the literature. Both the mean and the turbulent kinetic energy equations are addressed in such non-homogeneous conditions revealing a non-trivial behaviour of the energy fluxes. The energy introduced by the pressure drop follows two routes: part of it is transferred towards the walls to be dissipated and part feeds the turbulent production hence the velocity fluctuations in the separating shear layer. Spatial energy fluxes transfer the kinetic energy into the recirculation bubble and downstream near the wall where it is ultimately dissipated. Consistently, anisotropy concentrates at small scales near the walls irrespective of the value of the Reynolds number. In the bulk flow and in the recirculation bubble, isotropy is restored at small scales and the isotropy recovery rate is controlled by the Reynolds number. Anisotropy invariant maps are presented, showing the difficulty in developing suitable turbulence models to predict separated turbulent flow dynamics. Results shed light on the processes of production, transfer and dissipation of energy in this relatively complex turbulent flow where non-homogeneous effects overwhelm the classical picture of wall-bounded turbulent flows which typically exploits streamwise homogeneity.
Highlights
Flow separation consists of fluid flow around bodies becoming detached, causing the fluid closest to the object’s surface to flow in reverse or different directions, most often giving rise to turbulent fluctuations
Case A3 can be regarded as producing a turbulent boundary layer between the external turbulent stream and the wall able to better withstand the adverse pressure gradients before separation
The latter is probably the largest Reynolds number ever achieved in the direct numerical simulation (DNS) of this specific configuration, corresponding to a maximum friction Reynolds number of approximately Reτ = 900
Summary
Flow separation consists of fluid flow around bodies becoming detached, causing the fluid closest to the object’s surface to flow in reverse or different directions, most often giving rise to turbulent fluctuations. Boundary layer separation is induced by strong curvature effects and the associated adverse pressure gradient (APG) The understanding of such complex interplay among flow curvature, the APG and separation is considered one of the most challenging issues in fluid dynamics both for modelling (Wilcox 1998) and most recently for direct numerical simulation (DNS) (Soria et al 2017). In these conditions, the classical scaling of turbulent statistics is not valid since the flow separation modifies the Reynolds shear stress distribution as discussed by Skaare & Krogstad (1994).
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