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Turbulent flow topology in supersonic boundary layer with wall heat transfer

Sharma, S. ; Shadloo, M.S. ; Hadjadj, A.

The International journal of heat and fluid flow, 2019-08, Vol.78, p.108430, Article 108430 [Periódico revisado por pares]

Elsevier Inc

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  • Título:
    Turbulent flow topology in supersonic boundary layer with wall heat transfer
  • Autor: Sharma, S. ; Shadloo, M.S. ; Hadjadj, A.
  • Assuntos: Covariance integrand analysis ; Direct numerical simulation (DNS) ; Engineering Sciences ; Fluid mechanics ; Fluids mechanics ; Joint probability distribution function (JPDF) distribution ; Mechanics ; Physics ; Supersonic boundary layer ; Turbulent flow
  • É parte de: The International journal of heat and fluid flow, 2019-08, Vol.78, p.108430, Article 108430
  • Descrição: •DNS of transitional supersonic boundary layers are performed.•JPDF distribution and covariance integrands’ analyses are used to explain the turbulent flow topology.•Similarities with the case of the incompressible turbulent boundary layers are reported for turbulent shear stress behaviors.•The effects of wall temperature are mainly confined to the near-wall region.•Coherent structures’ orientations are affected by the wall temperature. Direct numerical simulations (DNS) are performed for the supersonic boundary layers (SBLs) with a free-stream Mach number M∞=2.2. Different cases including the adiabatic and the isothermal (cooled and heated) walls are investigated. The laminar boundary layer is excited by means of a blowing and suction strip with single-frequency and multiple spanwise wave-numbers. The incoming laminar flow is strongly perturbed with a perturbation intensity of 2.4% of the free-stream velocity to obtain the turbulent boundary layer. In the fully developed turbulent regions, the joint probability density function (JPDF) distribution and the covariance integrands’ analyses of different parameters are performed to find out the contribution of various physical mechanisms towards different transfer processes. The results reveal that behavior of the turbulent shear stress is similar to its incompressible counterpart and the wall-temperature impacts are dominant in the buffer layer region (at y+= 10). The inclination angles of coherent structures show variations arising from the wall-temperature in both the buffer-layer and the log region. The covariance integrands’ analyses of different components of the heat flux reveal the dominance of a different transfer process in case of the cooled wall, and as a result of this difference, the cooled wall acts as a heat sink.
  • Editor: Elsevier Inc
  • Idioma: Inglês
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