Two-phase flow of solid hydrogen particles and liquid helium

Cryogenics

Volumn 44, Issue 6-8, 2004, Pages 459-466

  Xu, J ^a   Rouelle, A ^a   Smith, K M ^a   Celik, D ^b   Hussaini, M Y ^a   Van Sciver, S W ^b  

^a FLORIDA STATE UNIVERSITY   (United States)

^b FLORIDA STATE UNIVERSITY   (United States)

Author keywords

Atomic hydrogen propellant feed systems; Continuum simulations; Liquid helium; Slurry flow; Solid hydrogen

Indexed keywords

COMPUTER SIMULATION; HELIUM; HYDROGEN; LIQUID FUELS; SLURRIES; SOLID PROPELLANTS; SOLIDIFICATION; TWO PHASE FLOW;

ATOMIC HYDROGEN PROPELLANT FEED SYSTEMS; CONTINUUM SIMULATIONS; LIQUID HELIUM; SOLID HYDROGEN;

CRYOGENICS;

EID: 2942587371     PISSN: 00112275     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.cryogenics.2004.02.008     Document Type: Conference Paper

References (19)

1. Logos C., Nguyen Q.D. Effect of particle size on the flow properties of a South Australian coal-water slurry. Powder Technology. 88(1):1996;55-58.
2. Massoudi M., Rajagopal K.R., Phuoc T.X. On the fully developed flow of a dense particle mixture in a pipe. Powder Technology. 104(3):1999;258-268.
3. Doron P., Barnea D. Flow pattern maps for solid-liquid flow in pipes. International Journal of Multiphase Flow. 22(2):1996;273-283.
4. Kaushal D.R., Tomita Y. Comparative study of pressure drop in multisized particle slurry flow through pipe and rectangular duct. International Journal of Multiphase Flow. 29(9):2003;1473-1487.
5. Palaszewski B. Solid hydrogen experiments for atomic propellants, AIAA-2000-3855 (NASA TM-2001-211292).
6. Celik D., Van Sciver S.W. Tracer particle generation in superfluid helium through cryogenic liquid injection for particle image velocimetry (PIV) applications. Experimental Thermal and Fluid Science. 26(8):2002;971-975.
7. Palaszewski B. Launch vehicle performance with solid particle feed systems for atomic propellants. AIAA-98-3736 (NASA TM-1998-208498).
8. Crowe C.T., Troutt T.R., Chung J.N. Numerical models for two-phase turbulent flows. Annual Review of Fluid Mechanics. 28:1996;11-43.
9. Elghobashi S.E., Abou-Arab T.W. A two-equation turbulence model for two-phase flows. Physics of Fluids. 26(4):1982;931-938.
10. Grady S., Wesson G.D., Abdullah M.M., Kalu E.E. Prediction of flow field in 10-mm hydrocyclone using computational dynamics. Fluid/Particle Separations Journal. 14:2002;1-10.
11. Kallio S, Manninen M, Taivassalo V. Turbulence in mixture models. Technical research center of Finland. Espoo.
12. Stewart H.B., Wendroff B. Two-phase flow: models and methods. Journal of Computational Physics. 56:1984;363-409.
13. Oey R.S., Mudde R.F., Portela L.M., et al. Simulation of a slurry airlift using a two-fluid model. Chemical Engineering Science. 56:2001;673-681.
14. Manninen M, Taivassalo V, Kallio S. On the mixture model for multiphase flow. 1996. VTT Publications 288. Technical research center of Finland. Espoo.
15. Shirolkar J.S., Coimbra C.F.M., McQuay M.Q. Fundamental aspects of modeling turbulent particle dispersion in dilute flows. Progress in Energy and Combustion Science. 22:1996;363-399.
16. Nigam M.S. Numerical simulation of buoyant mixture flows. International Journal of Multiphase Flow. 29(6):2003;983-1015.
17. Launder B.E., Spalding D.B. The numerical computation of turbulent flows. Computer Methods in Applied Mechanics and Engineering. 3(2):1974;269-289.
18. Launder BE, Spalding DB. Lectures in mathematical models of turbulence. London, England: Academic Press; 1972.
19. Patankar S.V. Numerical heat transfer and fluid flow. 1980;McGraw-Hill, NY.