A numerical study of the transition to oscillatory flow in 3D lid-driven cubic cavity flows

Abstract

In this article, three dimensional (3D) lid-driven cubic cavity flows have been studied numerically for various values of Reynolds number (Re). The numerical solution of the Navier-Stokes equations modeling incompressible viscous fluid flow in a cubic cavity is obtained via a methodology combining a first order accurate operator-splitting, L2-projection Stokes solver, a wave-like equation treatment of the advection and finite element methods. The numerical results obtained for Re=400, 1000, and 3200 show a good agreement with available numerical and experimental results in literature. Simulation results predict that the critical Recr for the transition from steady flow to oscillatory (a Hopf bifurcation) is somewhere in [1870, 1875] for the mesh size h=1/96. Via studying the flow field distortion of fluid flow at Re before and after Recr, the occurrence of the first pair of Taylor-G\"ortler-like vortices is connected to the flow field distortion at the transition from steady flow to oscillatory flow in 3D lid-driven cubic cavity flows for Re < 2000.