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The Use of Excess Engine Exit Area Over Intake Area to Reduce Zero-Lift Drag at High Supersonic Speeds

Published online by Cambridge University Press:  07 June 2016

L. C. Squire*
Affiliation:
University Engineering Laboratory, Cambridge*
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Summary

At flight speeds above about M=2 the cross-sectional area of the fully-expanded jet nozzle tends to be larger than the intake streamtube. The principle of integrating this increase in area of the propulsion unit with the usable volume in order to reduce the after-body drag of the combination is discussed and calculations are made to establish the order of the effect. It is deduced that successful integration of this type can produce worthwhile increases in lift/drag ratio.

Type
Research Article
Copyright
Copyright © Royal Aeronautical Society. 1965

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References

1. Nicholson, L. F. Engine Airframe Integration. Journal of the Royal Aeronautical Society, Vol. 61, p. 711, November 1957.Google Scholar
2. Jamison, R. R. Hypersonic Air Breathing Engines. Paper in Hypersonic Flow (edited by Collar, A. R. and Tinkler, J.), Colston Papers, Vol. XI. Butterworth, London, 1960.Google Scholar
3. Eggers, A. J. Jr., Some Considerations of Aircraft Configuration Suitable for Long-Range Hypersonic Flight. Paper in Hypersonic Flow (edited by Collar, A. R. and Tinkler, J.), Colston Papers, Vol. XI. Butterworth, London, 1960.Google Scholar
4. Tinkler, J. Impact Theory Calculations of the Lift and Drag of Ducted Bodies. Aeronautical Quarterly, Vol. XIII, p. 327, November 1962.Google Scholar
5. Maskell, E. C. and Weber, J. On the Aerodynamic Design of Slender Wings. Journal of the Royal Aeronautical Society, Vol. 63, p. 709, December 1959.Google Scholar
6. Küchemann, D. Aircraft Shapes and Their Aerodynamics for Flight at Supersonic Speeds. Advances in Aeronautical Sciences, Vol. 3, p. 221. Pergamon Press, 1961.Google Scholar
7. Syvertson, C. A. and Dennis, D. A. A Second Order Shock-Expansion Method Applicable to Bodies of Revolution near Zero Lift. N.A.C.A. Report 1328, 1957.Google Scholar
8. Lord, W. T. and Brebner, G. G. Supersonic Flow Past Slender Pointed Wings with “Similar” Cross Sections at Zero Lift. Aeronautical Quarterly, Vol. X, p. 79, February 1959.CrossRefGoogle Scholar
9. Weber, J. Slender Delta Wings with Sharp Edges at Zero Lift Unpublished R.A.E. paper.Google Scholar
10. Eminton, E. Pressure Distributions at Zero Lift for Delta Wings with Rhombic Cross Sections. A.R.C. C.P. 525, October 1959.Google Scholar
11. Weber, J. Some Notes on the Zero Lift Wave Drag of Slender Wings with Unswept Trailing Edges. R. & M. 3222, December 1959.Google Scholar