Direct numerical simulation of turbulent flow in a vertical channel with buoyancy orthogonal to mean flow

Abstract

The effect of buoyancy on turbulent air flowing horizontally between two differentially heated vertical plates has been investigated using direct numerical simulation. Grashof number ranges between zero and 4.0 × 10 6 and the Boussinesq approximation is used in the buoyant term. In this particular configuration, the buoyancy forces result in skewed mean velocity profiles with non-zero anti-symmetric spanwise component W. The resulting flow has the features of three-dimensional turbulent boundary layer flows. In particular, suppression of the primary Reynolds stress in near-wall region is observed. Titled streaks with significant destruction of the associated vortical structures are highlighted. The induced mean spanwise strain enhances the turbulence intensities in the channel core. The effect of buoyancy on mean quantities and second-order statistics including Reynolds stress components and turbulent heat fluxes are presented and analyzed with detailed budgets of their transport equations which are believed to be helpful to testify and improve turbulence models incorporating buoyancy effect.