Lefèbvre, Mathieau
Vanderstraeten, B.
Van Tiggelen, Pierre
[UCL]
A numerical study of detonations in hydrogen-oxygen-argon mixtures containing CF4 or CF3H is presented. Experiments have established the promoting effect of these additives on the detonation velocity. The Chapman-Jouguet model fails to explain the observed behavior and a numerical approach solving the steady equations of the fluid dynamics provides a first grasp of such an unexpected behavior. In this paper, we use a numerical model that solves the unsteady equations of the fluid dynamics to simulate the detonation wave and to predict the stabilized detonation velocity. The chemical model used is a parametric one that takes into account a temperature and composition dependence of the heat capacity. In a serie of one-dimensional calculations, we describe first the numerical ignition of the detonation wave. In particular, we examine the effect of the pressure in the driving gas section of the numerical domain. Then, we examine the influence of the additives on the detonation wave propagating in a mixture of H-2/O-2/Ar. We compare successfully the results of the modeling to experimental data. The promoting behavior of both fluorocarbons is numerically observed up to about 10% of the additives. Our conclusion is that it is possible to model the overall description of a detonation wave in complex reactive system. Prerequisites are the knowledge of the chemical kinetics to within a reasonable accuracy, robust algorithm for computing the fluid dynamics and attention to coupling.
- Baulch, D. L., Drysdale, D. D., Home, D.G., Lloyd, A.C. (1972) Evaluated Kinetic Data for High Temperature Reactions, Homogeneous Gas-Phase Reactions of the H2-O2 Systems. Vol. 1, Butterworths London
- Boris, J.P., Book, D.L. (1976) Solution of the Continuity Equation by the Method of Flux Corrected Transport, Meth. Comput. Physics 16:85
- JANAF Thermochemical Tables (1985) U.S. Department of Commerce, National Bureau of Standards, Washington DC
- Kondratiev, V.N. (1972) Rate Constants of Gase-Phase Reactions, U.S. Department of Commerce, National Bureau of Standards, Washington DC
- Lefebvre, M.H., Nzeyimana, E., Van Tiggelen, P. J. (1993a) Influence of Fluorocarbons on Hydrogen-Oxygen-Argon Detonations, Experiments and Modeling, Prog. Aero. Astro, AIAA 153:144
- Lefebvre, M.H., Oran, E.S., Kailasanath, K., Van Tiggelen, P.J., (1993b) Simulation of Cellular Structure in a Detonation Wave, Prog. Aero. Astro., AIAA 153:64
- Lefebvre, M.H., Oran, E.S., Kailasanath, K., Van Tiggelen, P.J., (1993c)The Influence of the Heat Capacity and Diluent on Detonation Structure, Combust. Flame 95:206
- Nzeyimana, E., Van Tiggelen, P. J. (1991) Influence of Tetrafluoromethane on Hydrogen-Oxygen-Argon Detonation, Prog. Aero. Astro., AIAA 133:77
- Oran, E.S., Boris, J.P., Young, T.R., Picone, J.M. (1981) Numerical Simulations of Detonations in Hydrogen-Air and Methane-Air Mixtures, 18th Symp. (international) on Combustion, The Combustion Institute, Pittsburgh, pp. 1641?1651
- Oran E.S., Young, T.R., Boris, J.P. (1982) Weak and Strong Ignition. II. Sensitivity of the Hydrogen-Oxygen System, Combust. Flame 48:149
- Vandooren, J., da Cruz, F.N., Van Tiggelen, P.J. (1988) The Inhibiting Effect of CF3H on the Structure of a Stoichiometric H2/CO/O2/Ar Flame, 22th Symp. (international) on Combustion, The Combustion Institute, Pittsburgh, pp. 1587?1595
- Westbrook, C.K. (1982) Chemical Kinetics of Hydrocarbon Oxidation in Gaseous Detonations, Combust. Flame, 46:191
Bibliographic reference |
Lefèbvre, Mathieau ; Vanderstraeten, B. ; Van Tiggelen, Pierre. Modeling of Gas-phase Detonation in Complex Reactive Systems. In: Shock Waves : an international journal on shock waves, detonations and explosions, Vol. 4, no. 5, p. 271-276 (1995) |
Permanent URL |
http://hdl.handle.net/2078.1/48080 |