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The Effect of Condensation on Hypersonic Laminar Heat Transfer to Cones

Published online by Cambridge University Press:  04 July 2016

N. B. Wood
N. B. Wood*
Affiliation:
Royal Armament Research and Development Establishment, Fort Halstead, Kent, at present with Physiological Flow Studies Unit, Imperial College, London
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Extract

The investigation of Daum focused attention on the problem of condensation in hypersonic wind tunnels. In such tunnels there is often a conflict between the desire to obtain the maximum Reynolds number and the necessity of operating with a sufficiently high stagnation temperature to avoid liquefaction of the working gas. The hypersonic gun tunnel, in which the present tests were made, is capable of running at relatively high Reynolds numbers and to define the operating limits of the RARDE gun tunnel, Bowman made measurements similar to those of Daum, but using nitrogen as the working gas. It will be recalled that Daum made measurements of static and pitot pressures at varying temperatures. He deduced from these measurements that below a certain working section pressure significant degrees of supersaturation could be tolerated before breakdown to the condensed state. Thus three regions can be defined; in order of increasing temperature these are:

(i) condensing flow;

(ii) supersaturated uncondensed flow; and

(iii)unsaturated flow (see Fig. 1).

Type
Technical Notes
Information
The Aeronautical Journal , Volume 72 , Issue 690 , June 1968 , pp. 520 - 521
Copyright
Copyright © Royal Aeronautical Society 1968 

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References

1. Daum, F. L. Air condensation in a hypersonic windtunnel. AIAA Jnl, Vol 1, No 5, pp 1043-6, 1963.Google Scholar
2. Bowman, J. E. Nitrogen condensation in the RARDE hypersonic gun tunnel. ARC CP No 956, 1967.Google Scholar
3. Wood, N. B. Hypersonic laminar heat transfer and boundary layer transition on blunted cones. (To be published in The Aero. Quart) Google Scholar
4. Whitfield, J. D. and Norfleet, G. D. Source flow effects in conical hypervelocity nozzles. AEDC Rep TDR-62-116, 1962.Google Scholar
5. Raat, J. On the effect of transverse curvature in compressible laminar boundary layer flow over slender bodies of revolution. NOL TR 63-68, 1964.Google Scholar
6. Probstein, R. F. Interacting laminar boundary layer over a cone. Brown University TR AF 2798/1, 1955.Google Scholar
7. Griffith, B. J., Deskins, H. E. and Little, H. R. Condensation in Hotshot tunnels. AIAA Jnl, Vol 2, No 9, pp 1645-7, 1964.Google Scholar