Stability and dynamics of the laminar flow past rectangular prisms

Abstract

The laminar flow past rectangular prisms is studied in the space of length-to-height ratio (1 L/H 5), width-to-height ratio (1.2 W/H 5) and Reynolds number (Re 700). The primary bifurcation is investigated with linear stability analysis. For large W/L it consists of an oscillating mode breaking the top/bottom planar symmetry. For smaller W/L the flow becomes first unstable to stationary perturbations, and the wake experiences a static deflection, vertical for intermediate W/L and horizontal for small W/L. Weakly nonlinear analysis and nonlinear direct numerical simulations are used for L/H = 5 and larger Re. For W/H = 1.2 and 2.25, after the primary bifurcation the flow recovers the top/bottom planar symmetry but loses the left/right one, via supercritical and subcritical pitchfork bifurcations, respectively. Further increasing Re, the flow becomes unsteady and oscillates around either the deflected (small W/H) or the non-deflected (intermediate W/H) wake. For intermediate W/H and Re, a periodic and fully symmetric regime is detected, with hairpin vortices shed from the top and bottom leading-edge (LE) shear layers; its triggering mechanism is discussed. At large Re and for all W/H, the flow approaches a chaotic state characterised by the superposition of different modes: shedding of hairpin vortices from the LE shear layers, and wake oscillations in the horizontal and vertical directions. In some portions of the parameter space the different modes synchronise, giving rise to periodic regimes also at relatively large Re.

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