The Ludwieg Pressure-Tube Supersonic Wind Tunnel

A. J. Cable; R. N. Cox

doi:10.1017/S0001925900002729

Summary

A description is given of a supersonic pressure-tube wind tunnel which has been constructed at A.R.D.E. This is a blow-down tunnel which uses as a reservoir a long tube filled with gas under pressure. A quasi-steady supersonic flow is achieved by expanding in a convergent-divergent nozzle the subsonic flow behind rarefaction waves which propagate down the tube when a diaphragm at the nozzle exit is burst. The theory of the operation of the tunnel is given and calculations are made of the boundary-layer growth along the tube. Pressure-time records were obtained in the tube, and a high speed camera was used to obtain pictures of the flow round a model. Measurements also included a pitot-tube traverse of the nozzle exit, and the Mach number distribution was determined from the ratio of the pitot to the stagnation pressure. Tests showed that, as predicted, a constant stagnation pressure was obtained ahead of the nozzle, and it is considered that a tunnel of this type would be a cheap and simple way of obtaining an intermittent tunnel with adequate running time for many types of test, and capable of operating at a Reynolds number of more than 107 per inch at a Mach number of about 3·5.

References

1. Ludwieg, H. Der Rohrwindkanal. Zeitschift für Flugwissenschaften, Jahrgang 3, Heft 7, p. 206, July 1955.Google Scholar

2. Ludwieg, H. The Tube Wind Tunnel—A Special Type of Blowdown Tunnel. AGARD Report 143, July 1957.Google Scholar

3. Cox, R. N. Discussion Following the Presentation of Papers on Hypersonics. AGARD Reports 132-147, p, 28, July 1957.Google Scholar

4. Becker, E. Das Anwachsen der Grenzschicht in und hinter einer Expansionswelle. Ingenieur-Archiv, Part XXV, Heft 3, p. 155, 1957.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

SHEERAN, W. J. HENDERSHOT, K. C. and MARTIN, J. F. 1968. A perforated-wall nozzle for variable Mach number testing.. Journal of Spacecraft and Rockets, Vol. 5, Issue. 9, p. 1101.

FLETCHER, R. F. 1968. Liquid-propellant explosions.. Journal of Spacecraft and Rockets, Vol. 5, Issue. 10, p. 1227.

FELD, DENIS J. 1968. Steering control of skid-equipped horizontally landing spacecraft.. Journal of Spacecraft and Rockets, Vol. 5, Issue. 9, p. 1103.

DAVIS, JOHN W. 1968. A high Reynolds number wind tunnel and its operating concept.. Journal of Spacecraft and Rockets, Vol. 5, Issue. 10, p. 1225.

HENDERSHOT, K. 1969. Applications of a tube wind tunnel in supersonic testing.

SHEERAN, WILLIAM J. and HENDERSHOT, KENNETH C. 1970. A tube wind-tunnel technique for rocket propulsion testing. Journal of Spacecraft and Rockets, Vol. 7, Issue. 8, p. 1008.

Schneiderman, A. M. and Sutton, G. W. 1970. Laser Planogram Measurements of Turbulent Mixing Statistics in the Near Wake of a Supersonic Cone. The Physics of Fluids, Vol. 13, Issue. 7, p. 1679.

McBRIDE, DONALD D. 1970. A simplified method for determining stagnation- point heat transfer to an elliptical model. Journal of Spacecraft and Rockets, Vol. 7, Issue. 8, p. 1010.

JOHNSON, J. A. and CAGLIOSTRO, D. 1971. Starting phenomena in a supersonic tube wind tunnel. AIAA Journal, Vol. 9, Issue. 1, p. 101.

WEGENER, PETER P. and CAGLIOSTRO, DOMINIC J. 1973. Periodic Nozzle Flow with Heat Addition. Combustion Science and Technology, Vol. 6, Issue. 5, p. 269.

Tong, Kwok-On and Russell, David A. 1977. Viscous effects in tube flow initiated by an expansion wave. AIAA Journal, Vol. 15, Issue. 12, p. 1763.

Merkli, Peter E. and Abuaf, Nesim 1977. Flow starting times in constant-area supersonic diffusers. AIAA Journal, Vol. 15, Issue. 12, p. 1718.

Sato, Junzo and Taneda, Hiroshi 1986. Mach number control of Ludwieg tubes. AIAA Journal, Vol. 24, Issue. 3, p. 459.

Johnson, J. A. Zhang, Y. and Johnson, L. E. 1988. Evidence of Reynolds number sensitivity in supersonic turbulent shocklets. AIAA Journal, Vol. 26, Issue. 4, p. 502.

SCHNEIDER, STEVEN 1991. A quiet-flow Ludwieg tube for experimental study of high speed boundary layer transition.

Baum, M R and Parry, A A 1992. The Thrust Exerted on a Gas-Pressurized Vessel During Axial Rupture. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, Vol. 206, Issue. 1, p. 15.

Baum, M R 1994. Branch Line Pipewhip Following Rupture at the Junction with the Main Pipe. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, Vol. 208, Issue. 2, p. 103.

Baum, M.R. 1995. Rupture of a gas-pressurized cylindrical vessel: the velocity of a detached end-cap. Journal of Loss Prevention in the Process Industries, Vol. 8, Issue. 3, p. 149.

Schneider, Steven 1998. Design of a Mach-6 quiet-flow wind-tunnel nozzle using the e**N method for transition estimation.

Matsuo, Shigeru Tanaka, Masanori and Setoguchi, Toshiaki 2002. Effect of non-equilibrium condensation of moist air on flow field in Ludwieg tube. Journal of Thermal Science, Vol. 11, Issue. 2, p. 104.

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The Ludwieg Pressure-Tube Supersonic Wind Tunnel

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