Numerical simulation of formation of cellular heterogeneous detonation of aluminum particles in oxygen

Combustion, Explosion and Shock Waves

Volumn 41, Issue 4, 2005, Pages 435-448

  Fedorov, A V ^a   Khmel, T A ^a  

^a KHRISTIANOVICH INSTITUTE OF THEORETICAL AND APPLIED MECHANICS   (Russian Federation)

Author keywords

Cellular detonation; Gas suspensions; Numerical simulation

Indexed keywords

CELLULAR DETONATION; CHANNEL WIDTH; GAS SUSPENSIONS; THERMAL RELAXATION;

ALUMINUM; COMBUSTION; NUMERICAL ANALYSIS; OXYGEN; SHOCK WAVES; STOICHIOMETRY; SUSPENSIONS (FLUIDS);

COMPUTER SIMULATION;

EID: 23944507153     PISSN: 00105082     EISSN: 15738345     Source Type: Journal    
DOI: 10.1007/s10573-005-0054-7     Document Type: Article

References (32)

1. R. A. Strechlov, "Gas phase detonations: Recent developments," Combust. Flame, 12, No. 2, 81-101 (1968).
2. A. A. Vasil'ev, V. V. Mitrofanov, and M. E. Topchiyan, "Detonation waves in gases," Combust., Expl., Shock Waves, 23, No. 5, 605-623 (1987).
3. E. Oran, "The structure of propagating detonation," in: G. Roy et al. (eds.), Gaseous and Heterogeneous Detonations, ENAS, Moscow (1999), pp. 97-120.
4. M. A. Nettleton, "Recent work on gaseous detonations," Shock Waves, 12, No. 1, 3-12 (2002).
5. K. I. Shchelkin and Ya. K. Troshin, Gas-Dynamics of Combustion [in Russian], Izd. Akad. Nauk SSSR, Moscow (1963).
6. V. V. Mitrofanov, Theory of Detonation [in Russian], Novosibirsk Univ., Novosibirsk (1982).
7. A. A. Vasil'ev and Yu. A. Nikolaev, "Model of the nucleus of a multifront gas detonation," Combust., Expl., Shock Waves, 12, No. 5, 667-674 (1976).
8. D. Desbordes, "Transmission of overdriven plane detonations: Critical diameter as a function of cell regularity and size," in: Progress in Astronautic and Aeronautic, Vol. 114: Dynamics of Explosions, AIAA Inc., New York (1988), pp. 170-185.
9. H. O. Barthel, "Predicted spacings in hydrogen-oxygen-argon detonations," Phys. Fluids, 17, No. 8, 1547-1553 (1974).
10. J. E. Shepherd, "Chemical kinetics of hydrogen-air-diluent detonations," in: Progress in Astronautic and Aeronautic, Vol. 106: Dynamics of Explosions, AIAA Inc., New York (1985), pp. 263-293.
11. A. I. Gavrikov, A. A. Efimenko, and S. B. Dorofeev, "A model for detonation cell size prediction from chemical kinetics," Combust. Flame, 120, 19-33 (2000).
12. B. A. Khasainov and B. Veyssiere, "Initiation of detonation regimes in hybrid two-phase mixtures," Shock Waves, 6, 9-15 (1996).
13. B. Veyssiere and W. Ingignoli, "Existence of the detonation cellular structure in two-phase hybrid mixtures," Shock Waves, 12, 291-299 (2003).
14. W. Ingignoli, B. Veyssiere, and B. A. Khasainov, "Study of detonation initiation in unconfined aluminum dust clouds," in: G. Roy et al. (eds.), Gaseous and Heterogeneous Detonations, ENAS, Moscow (1999), pp. 337-350.
15. F. Zhang and H. Grönig, "Transition and structure of dust detonations," in: A. A. Borisov (ed.), Dynamic Structure of Detonation in Gaseous and Dispersed Media, Kluwer Academic Publ. (1991), pp. 157-213.
16. B. A. Khasainov, B. Veyssiere, and W. Ingignoli, "Numerical simulation of detonation cell structure in hydrogen-air mixture loaded by aluminum particles," in: G. Roy et al. (eds.), High-Speed Deflagration and Detonation, Fundamental and Control, ELEX-KM, Moscow (2001), pp. 163-174.
17. K. Benkiewicz and A. K. Hayashi, "Two-dimensional numerical simulations of multi-headed detonations in oxygen-aluminum mixtures using an adaptive mesh refinement," Shock Waves, 13, 385-402 (2003).
18. A. A. Borisov, B. A. Khasainov, B. Veyssiere, et al., "Detonation of aluminum suspensions in air and oxygen," Khim. Fiz., 10, No. 2, 250-272 (1991).
19. M. Nikolis, D. N. Williams, and L. Bauwens, "Simulation of detonation cells in wide channel," in: G. Roy et al. (eds.), Gaseous and Heterogeneous Detonations, ENAS, Moscow (1999), pp. 153-162.
20. L. Hemeryck, M. N. Lefebre, and P. J. Van Tiggelen, "Numerical investigation of transient detonation waves," in: G. Roy et al. (eds.), High-Speed Deflagration and Detonation. Fundamental and Control, ELEX-KM, Moscow (2001), pp. 81-96.
21. W. A. Strauss, "Investigation of the detonation of aluminum powder-oxygen mixtures," AIAA J., 6, No. 12, 1753-1761 (1968).
22. A. E. Eremeeva, A. V. Medvedev, A. V. Fedorov, and V. M. Fomin, "On the theory of ideal and nonideal detonation of aerosuspensions," Preprint No. 37-86, Inst. Theor. Appl. Mech., Sib. Div., Acad. of Sci. of the USSR, Novosibirsk (1986).
23. A. V. Fedorov, "Structure of heterogeneous detonation of aluminum particles dispersed in oxygen," Combust., Expl., Shock Waves, 28, No. 3, 277-286 (1992).
24. A. V. Fedorov, V. M. Fomin, and T. A. Khmel', "Nonequilibrium model of steady detonations in aluminum particle-oxygen suspensions," Shock Waves, 9, No. 5, 313-318 (1999).
25. A. V. Fedorov and T. A. Khmel', "Numerical simulation of shock-wave initiation of heterogeneous detonation in aerosuspensions of aluminum particles," Combust, Expl., Shock Waves, 35, No. 3, 288-295 (1999).
26. T. A. Khmel' and A. V. Fedorov, "Numerical simulation of detonation initiation with a shock wave entering a cloud of aluminum particles," Combust., Expl., Shock Waves, 38, No. 1, 101-108 (2002).
27. T. A. Khmel' and A. V. Fedorov, "Interaction of a shock wave with a cloud of aluminum particles in a channel," Combust., Expl., Shock Waves, 38, No. 2, 206-214 (2002).
28. E. L. Dreizin, "On the mechanism of asymmetric aluminum particle combustion," Combust. Flame, 117, 841-850 (1999).
29. V. M. Boiko, V. P. Kiselev, S. P. Kiselev, et al, "Interaction of a shock wave with a cloud of particles," Combust, Expl., Shock Waves, 32, No. 2, 191-203 (1996).
30. A. Harten, "High resolution schemes for hyperbolic conservation laws," J. Comp. Phys., 49, No. 3, 357-393 (1983).
31. P. J. Roache, Computational Fluid Mechanics, Hermosa, Albuquerque (1976).
32. T. A. Khmel', "Numerical simulation of two-dimensional detonation flows in a gas suspension of reacting solid particles," Mat. Model., 16, No. 6, 73-77 (2004).