Heat transfer and flow characteristics of impinging jet on a concave surface at small nozzle to surface distances

Experimental and numerical investigations were carried out to analyze the flow and heat transfer characteristics of an impinging jet on a concave surface at small jet-to-surface distances. Constant heat flux of 2000 W/m(2) is applied on the concave surface using a silicon rubber heater mat. In the steady-state condition, the temperature distribution of the concave surface is measured with an infrared camera. In the experimental study, a jet with 24 mm diameter and cylindrical surface with the curvature radius of 12 cm (C-r = 0.1) has been considered. The study of flow and heat transfer characteristics have been performed for different jet Reynolds numbers (10,000-35,000) and various nozzle diameters (18-30 mm). The distributions of velocity and Nusselt number for small jet-to-surface distances (H/D < 1.0) have been compared with large jet-to-surface distances (H/D >= 1.0). Comparisons between numerical results and experimental data confirm that the numerical predictions performed by SST k-omega model fairly predict the velocity and Nusselt number distributions. Experimental and numerical results confirm that the jets with small nozzle-to-surface distances (H/D = 0.1, 0.2 and 0.4) provide a much more Nusselt number distributions in comparison with the surfaces with the large nozzle-to-surface distances (H/D = 1.0, 2.0 and 4.0). The correlated equations of the averaged Nusselt number reveal that the <(Nu)over bar>is related to (H/D)(-054) and (H/D)(-014) for small (H/D < 1.0) and large (H/D > 1.0) jet-to-surface distances respectively.