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An asymptotic theory of wind-tunnel-wall interference on subsonic slender bodies

Published online by Cambridge University Press:  21 April 2006

N. D. Malmuth
Affiliation:
Rockwell International Science Center, Thousand Oaks, CA 91360, USA

Abstract

An asymptotic theory of solid cylindrical wind-tunnel-wall interference about subsonic slender bodies has been developed. The basic approximation used is one of large wall-radius to body-length ratio. Matched asymptotic expansions show that in contrast to the analogous two-dimensional problem of a confined airfoil, three regions exist. Besides the incompressible crossflow and nearly axisymmetric zones, a wall layer exists where reflection in the wall of the line source representing the body becomes of dominant importance. From the theory, the interference pressures are shown to be approximately constant for closed bodies. Also demonstrated is that D'Alembert's paradox holds for interference drag of such shapes. Numerical studies comparing the exact theory to the asymptotic model which provides drastic simplifications, show that the latter can be used with reasonable accuracy to describe flows, even where the characteristic tunnel-radius to body-length ratio is as low as 1.5.

Type
Research Article
Copyright
© 1987 Cambridge University Press

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References

Batchelor, G. K. 1967 Introduction to Fluid Dynamics, pp. 124130. Cambridge University Press.
Berndt, S. B. 1977 Inviscid theory of wall interferene in slotted test sections, AIAA J. 15, 12781287.Google Scholar
Blynskaya, A. A. & Lifshits, Y. B. 1981 Transonic flows around an airfoil in wind tunnels. Fluid Dyn. 15, 711718.Google Scholar
Chan, Y. Y. 1980 Singular perturbation analysis of two-dimensional wind tunnel interferences. Z. angew. Math. Phys. 31, 605619.Google Scholar
Cole, J. D. 1968 Perturbation Methods in Applied Mathematics, pp. 182193. Blaisdell, Waltham, MA.
Cole, J. D. 1972 Studies in transonic flow, transonic area rule-bodies. UCLA Rep. ENG-7257.Google Scholar
Cole, J. D., Malmuth, N. D. & Zeigler, F. 1982 An asymptotic theory of solid tunnel wall interference on transonic airfoils. AIAA paper 82093, presented at the AIAA/ASME Joint Thermophysics, Fluids, Plasma and Heat Transfer Conference, St Louis, MO, June 7–11.Google Scholar
Cook, L. P. & Cole, J. D. 1978 Lifting line theory for transonic flow. SIAM J. Appl. Maths 35 (2), 209228.Google Scholar
Ferri, A. & Baronti, P. 1973 A method for transonic wind tunnel corrections. AIAA J. 11, 6371.Google Scholar
Garner, H. C., Rogers, E. W. E., Acum, W. E. A. & Maskell, E. E. 1966 Tunnel wall corrections. AGAR Dograph 109.Google Scholar
Kraft, E. M. & Dahm, W. J. A. 1982 Direct assessment of wall interference in a two-dimensional subsonic wind tunnel. Presented at the AIAA 20th Aerospace Science Meeting, Orlando, Fla, Jan. 1113.
Lifshits, Y. B. & Fonarev, A. S. 1978 Effect of flow boundaries on parameters of transonic flows around bodies of revolution. Fluid Dyn. 13, 393399.Google Scholar
Lo, C. F. 1978 Tunnel interference assessment by boundary measurements. AIAA J. 16, 411413.Google Scholar
Lock, C. N. H. & Beavan, J. A. 1944 Tunnel interference at compressibility speeds using flexible walls of the rectangular high speed tunnel. British ARC R & M 2005.
Malmuth, N. D. & Cole, J. D. 1984 Study of asymptotic theory of transonic wind tunnel interference. Final Report for Period May 30, 1982 through August 30, 1983, Contract No. F40600–82-C–0005, Arnold Engineering Development Center/DOS Report AEDC-TR-84–8. Tullahoma, TN.
Mokry, M., Chan, Y. Y. & Jones, D. V. 1983 Two-dimensional wind tunnel wall interference. AGARD Dograph 281.Google Scholar
Mokry, M., Peake, D. J. & Bowker, A. J. 1974 Wall interference on two-dimensional supercritical airfoils using wall pressure measurements to determine the porosity factors for tunnel and ceiling. NRC (Canada) LR-575.Google Scholar
Parker, R. L. & Erickson, J. C. 1982 Development of a three-dimensional adaptive-wall test section with perforated walls. Presented at the AGARD Meeting on Wall Interference in Wind Tunnels, London, UK, May 19–20.
Pindzola, M. & Lo, C. F. 1979 Boundary interference at subsonic speeds in tunnels with ventilated walls. AEDC-TR-69–47 (AD 687440), May.
Sears, W. R. 1974 Self correcting wind tunnels (the Sixteenth Lanchester Memorial Lecture). Aero. J. 78, 8089.Google Scholar
Sickles, W. L. & Kraft, E. M. 1982 Direct assessment of wall interference in a three-dimensional subsonic wind tunnel. AEDC-TRM-82-P27.