The rapid expansion of a supersonic turbulent flow: role of bulk dilatation-Reference-Cited by-同舟云学术

The rapid expansion of a supersonic turbulent flow: role of bulk dilatation

Published:1987-01 Issue: Volume:174 Page:81-112
ISSN:0022-1120
Container-title:Journal of Fluid Mechanics
language:en
Short-container-title:J. Fluid Mech.

Author:

Dussauge J. P.,Gaviglio J.

Abstract

The rapid expansion of a turbulent boundary layer in supersonic flow is studied analytically and experimentally. Emphasis is placed on the effect of bulk dilatation on turbulent fluctuations. The hypotheses made in the analysis are similar to those in the rapid distortion theory and are used to simplify second-order closures. By assuming that the fluctuating velocity is solenoidal an extension of classical subsonic models is proposed. A new variable is defined, which takes into account the mean density variations, and behaves like the Reynolds stress tensor in subsonic flows with weak inhomogeneities and a weak dissipation rate. The results of the analysis are compared with turbulence measurements performed in a supersonic boundary layer subjected to an expansion fan. The proposed approximations describe correctly the evolution of turbulence intensities: bulk dilatation contributes predominantly to the Reynolds stress evolution. The boundary layer is ‘relaminarized’ by the expansion. Downstream of the latter, the layer returns to equilibrium. Measurements show that the turbulence decays slowly in the outer layer and increases rapidly in the inner layer.

Publisher

Cambridge University Press (CUP)

Subject

Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics

Reference60 articles.

1. Galmes, J. M. , Dussauge, J. P. & Dekeyser, I. 1983 Couches limites turbulentes supersoniques soumises à un gradient de pression: calcul à l'aide d'un modèle.K-. J. Méc. 2 (4), 539–558.

2. Fernholz, H. H. & Finley, P. J. 1981 A further compilation of compressible boundary layer data with a survey of turbulence data.AGAR Dograph 263.

3. Debieve, J. F. , Gouin, M. & Gaviglio, J. 1982 Momentum and temperature fluxes in a shock wave turbulence interaction. Symp. Heat and Mass Transfer and the Structure of Turbulence Dubronik 1980.Hemisphere.

4. Laufer, J. & McClellan, R 1956 Measurements of heat transfer from fine wires in supersonic flows.J. Fluid Mech. 1,276–289.

5. Laufer, J. 1969 Thoughts on compressible turbulent boundary layers. The RAND Corp., Memo RM, 5946 PR. University of California.

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