A numerical method is developed with the capability to predict transient thermal boundary layer response under various flow and thermal conditions. The transient thermal boundary layer variation due to a moving compressible turbulent fluid of varying temperature was numerically studied on a two-dimensional semi-infinite flat plate. The compressible Reynolds-averaged boundary layer equations are transformed into incompressible form through the Dorodnitsyn–Howarth transformation and then solved with similarity transformations. Turbulence is modeled using a two-layer eddy viscosity model developed by Cebeci and Smith, and the turbulent Prandtl number formulation originally developed by Kays and Crawford. The governing differential equations are discretized with the Keller-box method. The numerical accuracy is validated through grid-independence studies and comparison with the steady state solution. In turbulent flow as in laminar, the transient heat transfer rates are very different from that obtained from quasi-steady analysis. It is found that the time scale for response of the turbulent boundary layer to far-field temperature changes is 40% less than for laminar flow, and the turbulent local Nusselt number is approximately 4 times that of laminar flow at the final steady state.

Issue Section:
Forced Convection
Keywords:
boundary layer turbulence, compressible flow, heat transfer, Navier-Stokes equations, numerical analysis, viscosity, boundary layer, turbulent, wave rotor, transient
Topics:
Boundary layers, Temperature, Transients (Dynamics), Turbulence, Flow (Dynamics), Steady state, Laminar flow, Viscosity, Thermal boundary layers, Heat transfer, Boundary layer turbulence
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 by American Society of Mechanical Engineers
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