Three-dimensional simulation of turbulent separated and reattached flow and heat transfer over a blunt flat plate is presented. The Reynolds number analyzed is 5000. The vortices shed from the reattachment flow region exhibit a hairpin-like structure. These large-scale vortex structures greatly influence the heat transfer in the reattachment region. Present results are compared with the previous three-dimensional calculations at low Reynolds number and it is found that there is no essential difference between two results with respect to the flow structure. The reattachment length is about five plate thicknesses, which is nearly equal to the previous experimental ones. The velocity distributions and turbulence intensities are in good agreement with the experimental data. Further, it is clarified that Nusselt number and temperature distributions greatly depend upon the Reynolds number, though their characteristic behaviors are qualitatively well simulated.

Issue Section:
Forced Convection
Keywords:
flow visualisation, flow simulation, turbulence, vortices, flow separation, heat transfer, external flows, temperature distribution, Computational, Heat Transfer, Reattachment, Separated, Turbulent
Topics:
Flat plates, Flow (Dynamics), Heat transfer, Reynolds number, Turbulence, Vortices, Temperature
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