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Effect of sandpaper roughness and stream turbulence on the laminar layer and its transition

Published online by Cambridge University Press:  04 July 2016

J. C. Gibbings  and
S. M. Al-Shukri
J. C. Gibbings
Affiliation:
Department of Mechanical EngineeringUniversity of Liverpool, UK
S. M. Al-Shukri
Affiliation:
Department of Mechanical EngineeringUniversity of Liverpool, UK
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Abstract

The work reported here was an experimental study of the combined influence of a sandpaper rough surface and a stream turbulence upon laminar and transitional boundary layers. Data correlations were obtained using the previously determined parameter of an equivalent Nikuradse size of roughness. These correlations are derived for the development of the laminar layer in thickness and profile shape factor, for the onset and the length of transition and for the distribution of intermittency through transition. Further fundamental differences in flow behaviour from those in a rough pipe have been found to add to those already reported.

Type
Research Article
Information
The Aeronautical Journal , Volume 101 , Issue 1001 , January 1997 , pp. 17 - 24
Copyright
Copyright © Royal Aeronautical Society 1997 

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References

1. Gibbings, J.C. and Al-Shukri, S.M. Characterisation of sandpaper roughness under a turbulent incompressible boundary layer, Aeronaut J, June/July 1996, 100, (996), pp 235239.Google Scholar
2. Gibbings, J.C. On boundary layer transition wires, Brit Aeronaut Res Council, Cur Pap No 462, 1959.Google Scholar
3. Gibbings, J.C., Goksel, O.T. and Hall, D.J. The influence of rough ness trips upon boundary layer transition, Pts 1, 2, 3, Aeronaut J, 1986, 90, (898, 899 and 900), pp 289301, 357-367 and 393-398.Google Scholar
4. Abu-Ghannam, B.J. Boundary Layer Transition in Relation to Turbo- machinery Blades, PhD thesis, University of Liverpool, 1979.Google Scholar
5. Al-Shukri, S.M. The Effect of Sandpaper-Type Roughness on Boundary Layer Transition for Turbomachinery Blades, PhD thesis, University of Liverpool, 1983.Google Scholar
6. Goldstein, S. Modem Developments in Fluid Dynamics, Oxford, 1938 (Dover, 1965).Google Scholar
7. Gibbings, J.C. A generalised iteration method for deriving multiple regression curves of non-linear functions, J Appl Statistics, 1993, 20, (l),pp 5767.Google Scholar
8. Nikuradse, J. Gesetzmassigkeiten der turbulenten strömung in glatten rohren, Forschungsheft 356, Ver deutsh Ing, 1932 Google Scholar
9. Nikuradse, J. Strömungsgesetze in rauhen rohren, Förschungsheft 361, Ver deutsh Ing, 1933.Google Scholar
10. Hall, D.J. and Gibbings, J.C. Influence of stream turbulence and pres sure gradient upon boundary layer transition, J Mech Eng Sci, 1972, 14, (2),pp 134146.Google Scholar
11. Fiendt, E.G. Investigation on the dependence of laminar-turbulent-tran sition on surface roughness and pressure gradient, Schiffbautecnischen geselsohaft Jahrbuch, 1956, 5O.Google Scholar
12. Evans, B.J. Effect of Freestream Turbulence on Blade Performance in a Compressor Cascade, PhD thesis, University of Cambridge, 1971.Google Scholar
13. Hislop, G.S. The Transition of a Laminar Boundary Layer in a Wind- tunnel, PhD thesis, University of Cambridge, 1940.Google Scholar
14. Mayle, R.E. The role of laminar-turbulent transition in gas turbine engines, ASME J Turbomac, October 1991, 113, pp 509537.Google Scholar
15. Abu-Ghannam, B.J. and Shaw, R. Natural transition of boundary layers — the effects of turbulence, pressure gradient and flow history, J Mech Eng Sci, 1980, 22, (5), pp 213228.Google Scholar
16. Riley, S. Three-Dimensional Boundary Layer Transition, PhD thesis, University of Liverpool, September 1985.Google Scholar
17. Madadnia, J. Experimental Study of Stability and Transition of Boundary Layer Flow, PhD thesis, University of Liverpool, 1989.Google Scholar
18. Dhawan, S. and Narasimha, R. Some properties of boundary layer flow during transition from laminar to turbulent motion, J Fluid Mech, 1958, 3, pp 418436.Google Scholar
19. Winter, K.W. An outline of the techniques available for the measure ment of skin friction in turbulent boundary layers, Prg Aerospace Sci, 1977, 18, pp 137.Google Scholar
20. Mabey, D.G. and Gaudet, L. Some applications of small skin friction balances at supersonic speeds, JAircr, 1975, 12, (10), pp 819825.Google Scholar
21. Coles, D.E. The Turbulent Boundary Layer in a Compressible Fluid, Rand Corp. Rep R-403-PR, USA, September 1962.Google Scholar
22. Preston, J.H. The determination of turbulent skin friction by means of pitot tubes, J RAeS, 1954, 58, pp 109121.Google Scholar
23. Gibbings, J.C., Madadnia, J., Riley, S. and Yousif, A.H. The proximity probe for measuring surface shear in air flows, Flow Meas Instrum, 1995, 6, (3), pp 201206.Google Scholar
24. Preston, J.H. The minimum Reynolds number for a turbulent boundary layer and the selection of a transition device, J Fluid Mech, 1958, 3, pp 373384.Google Scholar