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Mean-flow measurements in a supersonic three-dimensional turbulent boundary layer

Published online by Cambridge University Press:  20 April 2006

Anthony Demetriades  and
Glenn McCullough
Anthony Demetriades
Affiliation:
Montana State University, Bozeman, Montana 59717
Glenn McCullough
Affiliation:
Montana State University, Bozeman, Montana 59717
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Abstract

Measurements are presented of the mean flow in a supersonic turbulent boundary layer subjected to a constant weak transverse pressure gradient. The temperature and longitudinal velocity and the axial shear stress were only slightly affected by the three-dimensionality but a clearly defined crossflow component appeared, in the manner suggested by theory and confirmed in earlier experiments. The flow deflection angle and transverse-velocity component achieved a self-preserving form so long as the transverse-pressure gradient remained constant, and both achieved a maximum at the sublayer edge; the deflection angle seemed to decrease again between the latter and the surface. An empirical relation was found between the pressure-gradient strength and the maximum in the crossflow, and the dependence of the latter on distance from the surface was used to test analytical crossflow predictions. The data are in general agreement with Van Den Berg's law of the wall. The data also support the so-called parabolic law following a relaxation distance, especially if inviscid gradients are accounted for, and if the normal coordinate is contracted by the compressibility transformation.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 156 , July 1985 , pp. 401 - 418
Copyright
© 1985 Cambridge University Press

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References

Bradshaw, P. & Unsworth, K. 1974 AIAA J. 12, 1293.
Braun, W. H. 1959 NACA TN 4208.
Cooke, J. C. 1958 Aero Res. Counc. RM 3199.
Demetriades, A. & McCullough, G. H. 1982 Montana State Univ. Rep. SWT TR 82-04.
East, L. F. 1973 Aero Res. Counc. RM 3768.
Fanneløp, T. K. & Krogstad, P. A. 1975 J. Fluid Mech. 71, 815.
Hall, M. G. & Dickens, H. B. 1968 Aero Res. Counc. RM 3537.
Hopkins, E. J. & Inouye, M. 1971 AIAA J. 9, 993.
Johnston, J. P. 1957 MIT Gas Turbine Lab Rep. No. 39.
Laderman, A. J. 1978 AIAA J. 16, 723.
Laderman, A. J. 1980 AIAA J. 18, 1186.
Mager, A. 1952 NACA TN 1067.
Rastogi, A. K. & Rodi, W. 1978 AIAA J. 16, 151.
Spaid, F. W., Hurley, F. W. & Helman, T. H. 1975 AIAA J. 13, 253.
Van Den Berg, B. 1975 J. Fluid Mech. 70, 149.
Van Driest, E. R. 1955 50 Years Boundary Layer Research, p. 257. Vieweg.
Vermeulen, A. J. 1971 Measurements of three-dimensional turbulent boundary layers. Ph.D. Thesis, Cambridge.
Walz, A. 1962 Mécanique de la Turb., p. 300. CNRS Paris.
Whitfield, D. L. & High, M. D. 1977 AIAA J. 15, 431.
Yanta, W. J., Ausherman, D. W. & Hedlund, E. 1982 AIAA Paper No. 82-0289.