Hostname: page-component-cd9895bd7-fscjk Total loading time: 0 Render date: 2024-12-26T22:21:29.019Z Has data issue: false hasContentIssue false

Future large aircraft design — the delta with suction

Published online by Cambridge University Press:  04 July 2016

Abstract

Since the 1970s, large passenger aircraft design has evolved by modest, but commercially significant, incremental change following the underwing pod concept pioneered by the Boeing 707. In the 21st century, the market is likely to require greater passenger capacity to deal with air-side congestion and higher performance and operational efficiency to justify investment and conserve finite fossil fuel resources. Public opinion will require far greater emphasis on control of noise and engine exhaust pollution. There is likely to be much increased emphasis on pollution in the upper-atmosphere and its environmental impact. In such a situation, it is questionable whether the evolutionary design route can produce the necessary advances and this must stimulate the search for radical design alternatives.

A revolutionary approach, involving the delta planform combined with wing laminar flow control and its impact on overall design, is given a preliminary study in this paper. This has been carried out by assuming that major improvements in drag can be obtained by extensive laminarisation. Using non-dimensional methods, the resulting broad interactive impacts on airframe and engine design and performance are derived. The effect of assuming varying quantities of low-energy air sucked from the foot of the boundary layer is studied and suction-system performance examined.

In addition to the large potential improvements in range, a strong relationship between lower drag, lower cruising altitude and lower cruise engine size is identified. In the study, several factors emerge which may combine to drive large aircraft design towards low aspect ratio and the integrated delta wing planform. This paper is intended as a stimulus and a basis for further study and research.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society 1997 

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.)

References

1. Airway Pollution, Energy Economist. January 1994. (Based on a Paper by ARCHER, L. Aircraft emissions and the environment, COx, SOx,HOx and NOx, Oxford Institute for Energy Studies).Google Scholar
2. Armstrong, F.W., Allen, J.E. and Denning, R.M. Some fuel related issues concerning the future of aviation, Proc Instn Mech Engrs, 1997, 211 Part G.Google Scholar
3. Lowrie, B.W., Denning, R.M. and Gupta, P.C. The next generation supersonic transport — critical issues. Royal Aeronautical Society Symposium, Aerodynamics Design for Supersonic Flight, 19 April 1988.Google Scholar
4. Allen, J.E., Armstrong, F.W. and Denning, R.M. Evolution of aviation and propulsion systems: the next fifty years, Proc Instn Mech Engrs, 1995, 209.Google Scholar
5. Davies, S.D. The history of the Avro Vulcan, 14th Chadwick Memorial Lecture, 12 March 1969, Aeronaut J, May 1970.Google Scholar
6. Laming, T. The Vulcan Story, Arms and Armour Press, London, 1993.Google Scholar
7. Ramsden, J. M. Towards the Megajet, Aerospace, August 1994.Google Scholar
8. Barnes, C.H. Handley Page Aircraft Since 1907, Putnam, 1976.Google Scholar
9. Pfenninger, W. Experiments on a laminar suction airfoil of 17% thick-ness, J Aeronaut Sci, April 1949.Google Scholar
10. Mansfield, E.H. Structural Aspects of Suction Wings, Aeronautical Research Council Technical Rpt CP 87, 1952.Google Scholar
11. Head, M.R. The Boundary Layer with Distributed Suction, Fluid Motion Sub-Committee, Aeronautical Research Council, Paper 13 897, F.M. 1547 (Pcrf. 771), April 1951.Google Scholar
12. Handley Page Bulletin, Autumn 1956.Google Scholar
13. Handley Page Bulletin, Autumn 1957.Google Scholar
14. Lachmann, G.V. Boundary layer control, J R Aeronaut Soc, March 1955.Google Scholar
15. Collier, F.S. An overview of recent subsonic laminar flow control flight experiments, AIAA Paper 93-2987, July 1993.Google Scholar
16. Barry, B. Improving fuel economy through laminar flow, The Rolls-Royce Magazine, September 1994, 62.Google Scholar
17. Krogmann, P., Stanewsky, E. and Thiede, P. Effects of local boundary layer suction on shock boundary layer interaction and shock induced separation, AIAA Paper 84-0098, January 1984.Google Scholar
18. Poll, D.I.A., Walsh, S.A. and Gallagher, M. C. On the effect of uniform suction on stability and transition in zero pressure gradient viscous incompressible flow, Aeronaut J, May 1996, 100, (995).Google Scholar
19. Denning, R.M. Propulsion Research and its Impact on Fuel/Energy Conservation, Annual Lecture to The Institute of Production Engineers (Western Section), 15 April 1980, (Rolls-Royce Reference E/Dng/2763(Bristol)).Google Scholar
20.Royal Aeronautical Society Data Sheets — Aerodynamics.Google Scholar
21. Kuchemann, D. and Weber, J. Aerodynamics of Propulsion, McGraw-Hill, 1953.Google Scholar