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Reynolds-shear-stress measurements in a compressible boundary layer within a shock-wave-induced adverse pressure gradient

Published online by Cambridge University Press:  29 March 2006

W. C. Rose
Affiliation:
Ames Research Center, NASA, Moffett Field, California 94035
M. E. Childs
Affiliation:
University of Washington, Seattle, Washington 98195

Abstract

The results of an experimental investigation of the mean- and fluctuating-flow properties of a compressible turbulent boundary layer in a shock-wave-induced adverse pressure gradient are presented. The turbulent boundary layer developed on the wall of an axially symmetric nozzle and test section whose nominal free-stream Mach number and boundary-layer-thickness Reynolds number were 4 and 105, respectively. The adverse pressure gradient was induced by an externally generated, conical shock wave.

Mean and time-averaged fluctuating-flow data, including the experimental Reynolds shear stresses and experimental turbulent heat-transfer rates, are presented for the boundary layer and external flow, upstream, within and downstream of the pressure gradient. The turbulent mixing properties of the flow were determined experimentally with a hot-wire anemometer. The calibration of the wires and the interpretation of the data are discussed.

From the results of the investigation, it is concluded that the shock-wave/boundary-layer interaction significantly alters the shear-stress characteristics of the boundary layer.

Type
Research Article
Copyright
© 1974 Cambridge University Press

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References

Bradshaw, P. & Ferriss, D. H. 1971 Calculation of boundary-layer development using the turbulent energy equation: compressible flow on adiabatic walls. J. Fluid Mech. 46, 83110.Google Scholar
Donaldson, C. duP. 1972 Calculation of turbulent shear flows for atmospheric and vortex motions A.I.A.A. J. 10, 412.Google Scholar
Kistler, A. L. 1959 Fluctuation measurements in a supersonic turbulent boundary layer Phys. Fluids, 2, 290296.Google Scholar
Laufer, J. 1961 Aerodynamic noise in supersonic wind tunnels J. Aero. Sci. 28, 685692.Google Scholar
Morkovin, M. V. 1956 Fluctuations and hot-wire anemometry in compressible fluids. AGARDograph, no. 24.Google Scholar
Morkovin, M. V. & Phinney, R. E. 1958 Extended applications of hot-wire anemometry to high-speed turbulent boundary layers. Johns Hopkins University, Dept. Aeron. Rep. AFOSR TN-58-469.Google Scholar
Rose, W. C. 1970 A method for analyzing the interaction of an oblique shock wave with a boundary layer. N.A.S.A. Tech. Note, D-6038.Google Scholar
Rose, W. C. 1972 The behaviour of a compressible turbulent boundary layer in a shock-wave induced adverse pressure gradient. Ph.D. thesis, University of Washington. (See also N.A.S.A. Tech. Note, D-7092.)
Sandborn, V. A. & Slogar, R. J. 1955 Study of the momentum distribution of turbulent boundary layers in adverse pressure gradients. N.A.C.A. Tech. Note, no. 3264.Google Scholar