Numerical simulation of flow and heat transfer from slot jets impinging on a cylindrical convex surface

The flow field due to an impinging jet over a moving surface at a moderately high Reynolds number, emanating from a rectangular slot nozzle has been computed using the large eddy simulation technique. A dynamic subgrid-scale stress model has been used for the small scales of turbulence. The velocity

Local and average heat transfer were measured for a system of multiple jets impinging on a moving permeable surface at which there may be throughflow. Multiple jets were confined by a hood, as is required industrially for thermal efficiency. Exhaust ports located symmetrically between the jet nozzle

The ¯ow ®eld due to an impinging jet at a moderately high Reynolds number, emanating from a rectangular slot nozzle has been computed using a large eddy simulation (LES) technique. A dynamic subgrid-scale stress model has been used for the small scales of turbulence. Quite a few successful applicati

The nonlinear flow and heat transfer characteristics for a slot jet impinging on a slightly curved concave surface are experimentally studied here. The effects of jet Reynolds number on the jet velocity distribution and circumferential Nusselt numbers are examined. The nozzle geometry is a rectangul

Several CFD calculations have been performed in order to assess the ability of common __k‐ϵ__ turbulence models to predict heat transfer in impinging‐jet flow. One focus is on the influence of the wall on the flow, calculated either by applying a logarithmic wall function or by resolving the flow do