Direct Numerical Simulation of Channel Flow with Transpired Wall

Abstract

The present work investigates turbulent velocity and temperature fields subject to strong wall injection in a channel using a Direct Numerical Simulation technique. A simplified model problem of the internal flows inside the hybrid rocket motors where a regression process at the wall is idealized by the wall blowing has been considered to gain a better understanding of how the turbulent structures are modified. Since the near-wall state of turbulence is likely to be modified due to the effect of wall blowing and the mean flow dynamics differ significantly from those in typical non-transpired channel flows, caution needs to be made when the RANS type calculations are to be performed. As the strength of wall blowing increases, the flow experiences stronger streamwise acceleration or inhomogeneity and both the wall shear and friction temperature decrease significantly, but many of the higher order statistics such as turbulence intensities, turbulent heat flux, r.m.s. temperature fluctuations and Reynolds shear stress increase rapidly as the flow moves downstream, and this is thought to result from the shear instability induced by wall injection. Also, turbulent viscosity and turbulent diffusivity grow rapidly. Thus, the effect of wall-blowing modifies the state of turbulence significantly and more sophisticated turbulence modeling is required to predict this type of flow accurately.

Document Details

Document Type

Technical Report

Publication Date

Apr 14, 2005

Accession Number

ADA447129

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