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Flow about Cones at Very High Speeds

Published online by Cambridge University Press:  07 June 2016

H. K. Zienkiewicz
H. K. Zienkiewicz*
Affiliation:
Department of the Mechanics of Fluids, University of Manchester
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Summary:

Effects of vibrational excitation and dissociation of air on inviscid high speed flow past a circular cone, at zero incidence, with an attached shock wave, are studied on the assumption of thermal equilibrium. A numerical solution of the problem is outlined and an approximate analytic solution for the flow between the surface of the cone and the shock wave is developed. Two numerical examples are given as an illustration and compared with the corresponding solutions assuming constant air properties.

Type
Research Article
Information
Aeronautical Quarterly , Volume 8 , Issue 4 , November 1957 , pp. 384 - 394
Copyright
Copyright © Royal Aeronautical Society. 1957

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References

1. Zienkiewicz, H. K. Aerodynamics at Extreme Speeds. To be published.Google Scholar
2. Kopal, Z. Tables of Supersonic Flow around Cones. Massachusetts Institute of Technology, Centre of Analysis, Report No. 1, 1947.Google Scholar
3. Beattie, J. A. Thermodynamic Properties of Real Gases and Mixtures of Real Gases; Part C of Volume I, High Speed Aerodynamics and Jet Propulsion. Princeton University Press, 1955.Google Scholar
4. Curtiss, C. F. Thermodynamic Properties of Air. University of Wisconsin, Part I— Report No. CM472, Part II—Report No. CM518, 1948.Google Scholar
5. Krieger, F. J. and White, W. B. The Composition and Thermodynamic Properties of Air at Temperatures from 500 to 8000° K and Pressures from 0.0001 to 100 atmospheres. Rand Corporation Report R149, April 1949.Google Scholar
6. Bethe, H. A. The Specific Heat of Air up to 25,000°C. United States Office of Scientific Research and Development, Report No. 369, February 1942.Google Scholar
7. Hilsenrath, J. and Beckett, C. W. Thermodynamic Properties of Argon-Free Air to 15,000°K. National Bureau of Standards, Report 3991, April 1955.Google Scholar
8. Maccoll, J. W. The Conical Shock Wave Formed by a Cone Moving at a High Speed. Proc. Roy. Soc., A. 159, pp. 459472, April 1937.Google Scholar
9. Blackman, V. H. Vibrational Relaxation in Oxygen and Nitrogen. Journal of Fluid Mechanics, Vol. 1, pp. 6185, May 1956.Google Scholar
10. Kantrowitz, A. and Huber, P. Heat Capacity Lag Measurements in Various Gases. Journal of Chemical Physics, Vol. 15, p. 275, 1947.Google Scholar