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Numerical Study of Compressible Wall-Bounded Turbulence – the Effect of Thermal Wall Conditions on the Turbulent Prandtl Number in the Low-Supersonic Regime

David J. Lusher, Gary N. Coleman

2022International journal of computational fluid dynamics22 citationsDOI

Abstract

Direct numerical simulation is used to determine the turbulent Prandtl number Prt above cold (isothermal) and hot (adiabatic) walls in a family of low-supersonic channel flows. A range of mean temperature/density variations, corresponding to effective/edge Mach numbers between 1.1 to 2.2, and wall-variable-based Reynolds number Reτw from 73 to 3800, is considered. The adiabatic condition is a new feature of special interest. The value of Prt away from the wall approaches 0.85 above both the isothermal and adiabatic walls. The variations of the near-wall Prt profiles in both the present and previous, passive-scalar simulations collapse as a function of the semilocal yw∗ wall scaling proposed in 1995 by [Huang, P. G., G. N. Coleman, and P. Bradshaw. 1995. “Compressible Turbulent Channel Flows: DNS Results and Modelling.” Journal of Fluid Mechanics 305: 185–218. doi:10.1017/S0022112095004599.], with only a weak dependence on Reτw. This leads to a rather simple proposal for a model of heat transfer, attached to an eddy-viscosity model.

Topics & Concepts

Turbulent Prandtl numberAdiabatic wallPrandtl numberMechanicsTurbulenceAdiabatic processPhysicsReynolds numberSupersonic speedDirect numerical simulationMach numberCompressibilityCompressible flowThermodynamicsClassical mechanicsHeat transferNusselt numberFluid Dynamics and Turbulent FlowsComputational Fluid Dynamics and AerodynamicsCombustion and flame dynamics