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Laminar Boundary Layers over Permeable Curved Surfaces

Published online by Cambridge University Press:  07 June 2016

B. R. Clayton
Affiliation:
Department of Mechanical Engineering, University College London
B. S. Massey
Affiliation:
Department of Mechanical Engineering, University College London
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Summary

Steady, constant-density, two-dimensional flow in a laminar boundary layer is considered over a permeable curved surface, for conditions such that the equation of motion has similar solutions. Account is also taken of the displacement of the main stream by the boundary layer.

Integration of the equation of motion on a digital computer yields results indicating that, for given values of curvature and longitudinal pressure gradient, suction reduces the boundary-layer thickness and increases skin friction. Blowing has the reverse effects. The amount of suction or blowing required to produce neutral stability is independent of curvature and so may be deduced from data for flat surfaces.

For a given curvature, blowing reduces, whereas suction increases, the magnitude of the adverse pressure gradient which the boundary layer can withstand before separation occurs. For a surface through which there is blowing or only a small amount of suction, convex curvature also reduces the magnitude of the adverse pressure gradient producing separation; but for larger amounts of suction the effect of surface curvature on separation is reversed.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society. 1969

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References

1. Clayton, B. R. and Massey, B. S. An analogy between the effects of longitudinal surface curvature and of suction or blowing on a laminar boundary layer. AIAA Journal, Vol. 6, pp. 18135, 1968.Google Scholar
2. Emmons, H. W. and Leigh, D. C. Tabulation of the Blasius function with blowing and suction. ARC Current Paper 157, 1954.Google Scholar
3. Holstein, H. Aehnliche laminare Reibungsschichten an durchlässigen Wänden. Untersuchungen und Mitteilungen, deutscher Luftfahrtforschung, No. 3050, 1943.Google Scholar
4. Lin, C. C. The Theory of Hydrodynamic Stability. Cambridge University Press, pp. 5658, 1955.Google Scholar
5. Massey, S. S. and Clayton, B. R. Laminar boundary layers and rtheir separation from curved surfaces. Transactions of the American Society of Mechanical Engineers, Journal of Basic Engineering, Vol. 87, Series D, pp. 483494, 1965.Google Scholar
6. Massey, B. S. and Clayton, B. R. Some properties of laminar boundary layers on curved surfaces. Transactions of the American Society of Mechanical Engineers, Journal of Basic-Engineering, Vol. 90, Series D, pp. 301312, and p. 430, 1968.Google Scholar
7. Massey, B. S. and Clayton, B. R. A note on the accuracy of similar solutions of the equations for laminar boundary layers on curved surfaces. The Aeronautical Journal, Vol. 73, p. 226, 1969.Google Scholar
8. Schlichting, H. Boundary Layer Theory. Chapter 10, 5th edition, McGraw-Hill, New York, 1968.Google Scholar
9. Schultz-Grunow, F. Influence of longitudinal wall curvature on the stability of boundary-layer flow. AIAA Journal, Vol. 5, pp. 20532054, 1967.Google Scholar
10. Terrill, R. M. Laminar boundary-layer flow near separation with and without suction. Philosophical Transactions of the Royal Society, Series A, Vol. 253, pp. 55100, 1960.Google Scholar
11. Zamir, M. and Young, A. D. Similar and asymptotic solutions of the incompressible laminar boundary layer equations with suction. Aeronautical Quarterly, Vol. 18, pp. 103120, 1967.Google Scholar