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Effect of contraction on screen-generated turbulence

Published online by Cambridge University Press:  04 July 2016

E. G. Tulapurkara  and
V. Ramjee
E. G. Tulapurkara
Affiliation:
Indian Institute of Technology, Madras
V. Ramjee
Affiliation:
Indian Institute of Technology, Madras
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Extract

Screens and contraction are used to achieve a low level of free-stream turbulence in the test-section of a wind tunnel. The effect of contraction on turbulence was initially studied, theoretically, by Prandtl, Taylor, Ribner and Tucker and Batchelor and Proudman. The last two theories, called rapid distortion theory, take into account the random nature of turbulence, but assume that the turbulence is initially isotropic, the effect of viscosity is small and the distortion is rapid.

Information

Type
Technical Notes
Information
The Aeronautical Journal , Volume 84 , Issue 836 , September 1980 , pp. 290 - 295
Copyright
Copyright © Royal Aeronautical Society 1980 

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Footnotes

*

Lecturer, Department of Aeronautical Engineering.

Assistant Professor, Department of Applied Mechanics.

References

1. Prandtl, L. Attaining steady airstream in wind tunnels. NACA TM 726, 1933.Google Scholar
2. Taylor, G. I. Turbulence in a contracting stream. Zeitschrift fur Angewandte Mathematik Und Mechanik, Vol 15, pp 9196, 1935.Google Scholar
3. Ribner, H. S. and Tucker, M. Sprecturum of turbulence in a contracting stream. NACA TR 1113, 1953.Google Scholar
4. Batchelor, G. K. and Proudman, I. The effect of rapid distortion of a fluid in turbulent motion. Quarterly Journal of Applied Mathematics, Vol 7, pp 83103, 1954.Google Scholar
5. Uberoi, M. S. Effect of wind tunnel contraction on free-stream turbulence. Journal of Aeronautical Sciences, Vol 23, pp 754764, 1956.Google Scholar
6. Klein, A. and Ramjee, V. Effect of contraction geometry on non-isotropic free stream turbulence. The Aeronautical Quarterly, Vol 24, pp 3438, 1973.Google Scholar
7. Voytovich, L. N. Influence of nozzle contraction on damping of turbulent pulsations. NASA TTF-15, 724, 1974.Google Scholar
8. Hussain, A. K. M. F. and Ramjee, V. Effect of axisym- metric contraction shape on incompressible turbulent flow. Journal of Fluids Engineering, Vol 98, pp 5869, 1976.Google Scholar
9. Ramjee, V. and Hussain, A. K. M. F. Influence of axisymmetric contraction ratio on free stream turbulence. Journal of Fluids Engineering, Vol 98, pp 506515, 1976.Google Scholar
10. Sreenivasan, K. R. and Narasimha, R. Rapid distortion of axisymmetric turbulence. Journal of Fluid Mechanics, Vol 84, pp 497516, 1978.Google Scholar
11. Launder, B. E., Reece, G. J. and Rodi, R. Progress in development of Reynolds stress turbulence closure. Journal of Fluid Mechanics, Vol 68, pp 537566, 1975.Google Scholar
12. Thwaites, B. On the design of contractions for wind tunnels. ARC R and M 2278, 1946.Google Scholar
13. Batchelor, G. K. Theory of homogeneous turbulence. Cambridge University Press, p 96, 1959.Google Scholar
14. Uberoi, M. S. and Wallis, S. Small axisymmetric contraction of grid turbulence. Journal of Fluid Mechanics, Vol 24, pp 539543, 1966.Google Scholar