Hostname: page-component-848d4c4894-r5zm4 Total loading time: 0 Render date: 2024-06-24T01:59:25.019Z Has data issue: false hasContentIssue false
  • English
  • Français

Two-dimensional flow past bluff flexible membranes of low porosity

Published online by Cambridge University Press:  04 July 2016

H. T. Low  and
B. G. Newman
H. T. Low
Affiliation:
Department of Mechanical Engineering, McGill University, Montreal, Quebec
B. G. Newman
Affiliation:
Department of Mechanical Engineering, McGill University, Montreal, Quebec
Get access Rights & Permissions [Opens in a new window]

Summary

This paper considers two-dimensional flow past flexible membranes whose supports are aligned at right angles to the flow. Unlike a previous study of bluff impervious membranes, the present membranes are slightly porous having a porosity similar to that of parachutes. The drag and base pressure have been measured for various lengths and for a variety of fabrics. The results have been correlated by two theories which are extensions of those already published. When the porosity is not too small the results are shown to depend only on the total volume flow through the membrane. The tendency for the membrane to oscillate in harmony with regular vortex shedding is reduced by the porosity and increased by the length of the membrane. Above a certain porosity oscillation is inhibited for all membrane lengths.

Type
Research Article
Information
The Aeronautical Journal , Volume 90 , Issue 898 , October 1986 , pp. 313 - 334
Copyright
Copyright © Royal Aeronautical Society 1986 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

*

Dept of Mechanical & Production Engineering, National University of Singapore.

McGill University.

References

1. Newman, B. G. and Low, H. T. Two-dimensional flow at right angles to a flexible membrane. Aero Quarterly, 1981, 32, 243 269.Google Scholar
2. Melzig, H. D. The influence of porosity on the performance and properties of parachutes. NASA Tech. Translation F13, 431, 1970.Google Scholar
3. Bearman, P. W. and Fackrell, J. E. Calculation of two-dimensional and axi-symmetric bluff body potential flow. J Fluid Mech, 1975, 72, 229241.Google Scholar
4. Parkinson, G. V. and Jandali, T. A wake source model for bluff body potential flow. J Fluid Mech, 1970, 40, 577594.Google Scholar
5. Taylor, G. I. and Batchelor, G. K. The effect of a gauze on small disturbances in a uniform stream. Q J Mech Appl Math, 1949, 2, 129.Google Scholar
6. Schubauer, G.B., Spangenberg, W. G. and Klebanoff, P. S. Aerodynamics characteristics of damping screens. NACA TN2001, 1948.Google Scholar
7. Gibbings, J. C. The pyramid gauze diffuser. Ing Arch, 42, 225233.Google Scholar
8. Lindsey, W. F. Drag of cylinders of simple shape. NACA Rep 619, 1938.Google Scholar
9. Fage, A. and Johansen, F. C. On the flow of air behind an inclined flat plate of infinite span. Proc R Soc London, 1927, A 116, 170197.Google Scholar
10. Maskell, E. C. A theory of the blockage effects on bluff bodies and stalled wings in a closed wind tunnel. ARC R&M 3400, 1963.Google Scholar
11. Flachsbart, O. Messungen an ebenen und gewolbten Platten. Ergebnisse der Aerodynamischen Versuchanstalt zu Gottingen, 1932, 4, 96100.Google Scholar
12. Fail, R., Lawford, J. A. and Eyre R. C. W., Low speed experiments on the wake characteristics of flat plates normal to an air stream. ARC R&M 3120, 1957.Google Scholar
13. Castro, I. Wake characteristics of two-dimensional perforated plates normal to an air-stream. J Fluid Mech, 1971, 46, 599609.Google Scholar
14. Goglia, M. J., LaVier, H. W. S. and Brown, C. D. Air permeability of parachute cloths. Text Res J, 1955, 25, 296313.Google Scholar
15. Bean, H. S. Fluid meters — their theory and application. Rep of ASME Res Committee on Fluid Meters, 6th ed, 197214, 1971.Google Scholar
16. Klein, W. G., Lermond, C. A. and Platt, M. M. Development of design data on the mechanics of air flow through parachute fabrics. WADC Tech Rep 56-576, Wright Patterson Air Force Base, Ohio, 1957.Google Scholar
17. Payne, P. R. The theory of fabric porosity as applied to parachutes in incompressible flow. Aero Quarterly, 1978, 29, 175206.Google Scholar
18. Glaskin, A. A statistical note on the variation of porosity of nylon fabric to specification DTD 556A. ARC R&M 2313, 1945.Google Scholar
19. Wood, C. J. The effect of base bleed on a periodic wake. J of the RAeS, 1964, 68, 477482.Google Scholar
20. Wood, C. J. Visualisation of an incompressible wake with base bleed. J Fluid Mech, 1967, 29, 259272.Google Scholar
21. Bearman, P. W. The effects of base bleed on the flow behind a two-dimensional model with a blunt trailing edge. Aero Quarterly, 1967, 18, 207224.Google Scholar
22. Bearman, P. W. On vortex street wakes. J Fluid Mech, 1967, 28, 625641.Google Scholar
23. Gerrard, J. H. The mechanics of the formation region of vortices behind bluff bodies. J Fluid Mech, 1966, 25, 401413.Google Scholar
24. Griffins, O. M. Universal similarity in the wakes of stationary and vibrating bluff structures. J Fluid Eng, Trans ASME, 1981, 103, 5258.Google Scholar
25. Awbi, H. B. An assessment of the universal Strouhal number concepts for two-dimensional bluff bodies. Aero Journal, 1981, 85, 467469.Google Scholar
26. Low, H. T. Planar two-dimensional flow past membranes. McGill University. PhD Thesis, 1982.Google Scholar