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TECHNICAL PAPERS

Effect of Slip Velocity and Heat Transfer on the Condensed Phase Momentum Flux of Supersonic Nozzle Flows

[+] Author and Article Information
S. A. Sherif

W. E. Lear

Department of Mechanical Engineering, 237 MEB, Box 116300, University of Florida, Gainesville, FL 32611-6300

N. S. Winowich

Department of Mechanical and Aerospace Engineering and Engineering Science, University of Tennessee–Knoxville, 414 Dougherty Engineering Bldg., Knoxville, TN 37006-2210

J. Fluids Eng 122(1), 14-19 (Dec 07, 1999) (6 pages) doi:10.1115/1.483240 History: Received June 02, 1997; Revised December 07, 1999
Copyright © 2000 by ASME
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References

Sherif, S. A., 1993, “Optimization Analysis of Supersonic Flow of Nitrogen/Water Mixtures Through Converging-Diverging Nozzles” 1993 Research Report, NASA/ASEE Summer Faculty Fellowship Program, E. R. Hosler, C. Valdes, and T. Brown, eds., NASA Contractor Report No. CR-194678 (Supplement 11), Grant No. NASA-KSC-NGT-60002, National Aeronautics and Space Administration John F. Kennedy Space Center, Cape Canaveral, Fl.
Finnie,  I., 1972, “Some Observations on the Erosion of Ductile Metals,” Wear, 19, pp. 81–90.
Klausner, J. F., Mei, R., Near, S., and Stith, R., 1998, “Two-Phase Jet Impingement for Non-Volatile Residue Removal,” Proceedings of the Insitution of Mechanical Engineers - Part E, Vol. 212, pp. 271–279.
Goodwin, J. E., Sage, W., and Tilly, G. P., 1969, Proceedings of Institution of Mechanical Engineers, Vol. 184, pp. 279–292.
Sheldon,  G. L., 1970, “Similarities and Differences in the Erosion Behavior of Materials,” ASME J. Basic Eng., 92, pp. 619–626.
Tilly,  G. P., and Sage,  W., 1970, “The Interaction of Particle and Material Behaviour in Erosion Processes,” Wear, 16, pp. 447–465.
Caimi, R. E., and Thaxton, E. T., 1993, “Supersonic Gas-Liquid Cleaning System,” Proceedings of the Technology 2003 Conference, NASA Conference Publication 3249, Vol. 1, Anaheim, CA, Dec. 7–9, pp. 232–240.
Dearing, W. L., Bales, L. D., Bassett, C. W., Caimi, R. E., Lafferty, G. M., Melton, G. S., Sorrell, D. L., and Thaxton, E. T., 1993, “Methods for Using Water Impingement in Lieu of Chlorofluorocarbon 113 for Determining the Non-Volatile Residue Level on Precision Cleaning Hardware,” Alternatives to Chlorofluorocarbon Fluids in the Cleaning of Oxygen and Aerospace Systems and Components, ASTM STP 1181, pp. 66–77.
Melton, G. S., Caimi, R. E. B., Littlefield, M. D., and Thaxton, E. T., 1994, “Cleaning Verification by Air/Water Impingement,” Proceedings of the 1994 Precision Cleaning Conference, May, pp. 97–107.
Melton, G. S., Caimi, R. E., and Thaxton, E. T., 1993, “Determination of Non-Volatile Residue on Precision Cleaned Oxygen and Aerospace Systems and Components by Means of Water Impingement and Total Organic Carbon Analysis,” Proceedings of the 1993 International CFC and Halon Alternatives Conference, Washington, DC, October, pp. 642–650
Lear, W. E., Sherif, S. A., and Langford, J., 1996, “Efficiency and Gasdynamic Analysis of Two-Phase Mixtures in Supersonic Nozzles with Inter-Phase Heat Transfer and Slip,” AIAA Paper 96-0119, 34th AIAA Aerospace Sciences Meeting and Exhibit, Reno, NV, Jan. 15–18.
Jackson, C. R., Lear, W. E., and Sherif, S. A., 1996, “Rankine-Hugoniot Analysis of Two-Phase Flow,” Developments in Theoretical and Applied Mechanics, Vol. XVIII, Wilson, H. B., Batra, R. C., Bert, C. W., Davis, A. M. J., Schapery, R. A., Stewart, D. S., and Swinson, F. F., eds., School of Engineering, The University of Alabama, Tuscaloosa, AL, pp. 10–22.
Jackson, C. R., Lear, W. E., and Sherif, S. A., 1996, “Rankine-Hugoniot Analysis of Two-Phase Flow With Inter-Phase Heat Transfer and Slip,” AIAA Paper 96-2959, AIAA/SAE/ASME/ASEE 32nd Joint Propulsion Conference and Exhibit, Lake Buena Vista, FL, July 1–3.

Figures

Grahic Jump Location
Effect of the heat transfer parameter on the exit liquid momentum flux
Grahic Jump Location
Effect of the gas specific heat ratio on the exit liquid momentum flux
Grahic Jump Location
Profiles of exit liquid momentum flux and stagnation-to-exit pressure ratio: effect of volume parameter at a liquid mass injection ratio of 0.9
Grahic Jump Location
Profiles of exit liquid momentum flux and stagnation-to-exit pressure ratio: effect of volume parameter at a liquid mass injection ratio of 0.5
Grahic Jump Location
Profiles of exit liquid momentum flux and stagnation-to-exit pressure ratio: effect of slip parameter at a liquid mass injection ratio of 0.9
Grahic Jump Location
Profiles of exit liquid momentum flux and stagnation-to-exit pressure ratio: effect of slip parameter at a liquid mass injection ratio of 0.5
Grahic Jump Location
Profiles of exit liquid momentum flux and stagnation-to-exit pressure ratio: effect of heat transfer parameter at a liquid mass injection ratio of 0.9
Grahic Jump Location
Profiles of exit liquid momentum flux and stagnation-to-exit pressure ratio: effect of heat transfer parameter at a liquid mass injection ratio of 0.5
Grahic Jump Location
Effect of the slip parameter on the exit liquid momentum flux
Grahic Jump Location
Effect of stagnation-to-exit pressure ratio on the exit liquid momentum flux
Grahic Jump Location
Effect of the liquid-to-gas specific heat ratio on the exit liquid momentum flux
Grahic Jump Location
Effect of the volume parameter on the exit liquid momentum flux

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