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Fourth International Seminar on Flame Structure, Novosibirsk, August, 18-21, 1992
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Fourth International Seminar on Flame Structure, Novosibirsk, August 18–21, 1992
V. I. Babushok, V. E. Zarko
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3–4 |
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Is turbulent burning velocity a meaningful parameter?
D. Bradley
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5–7 |
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Combustion wave structure in heterogeneous solid propellants
O. B. Kovalev, A. P. Petrov, V. M. Fomin
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8–16 |
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Numerical simulation of transients in the ignition of two-component propellants by intense heat fluxes
A. G. Knyazeva, V. E. Zarko
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16–20 |
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Study of solid propellant ignition by a hot gas stream
A. A. Zenin, S. V. Finjakov
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20–26 |
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Thermal decomposition of Gap and Gap based double base propellants
S. S. Dhar, S. N. Asthana, H. Singh, G. N. Natu
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27–31 |
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Unsteady combustion of solid propellants subject to dynamic external radiant heating
S. F. Son, M. Q. Brewster
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31–36 |
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Experimental and numerical approach to the study of the frequency response of solid propellants
P. Giuliani, C. Zanotti
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36–41 |
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A method for determining the pressure response function using the data on burning rate under irradiation
A. B. Kiskin
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41–43 |
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Modeling of nonsteady-state combustion of solid propellants with subsurface gasification of volatiles
V. N. Bukharov, L. K. Gusachenko, V. E. Zarko
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43–48 |
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Combustion wave propagation through deformed solids
A. G. Knyazeva
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48–53 |
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The effect of particle size and component concentration on the nonstationary combustion characteristics of heterogeneous propeplants
V. N. Simonenko, V. V. Chertishchev
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53–55 |
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Structure of diffusion and premixed laminar counterflow flames including molecular radiativa transfer
T. Dagusé, A. Soufiani, N. Darabiha, J. C. Rolon
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55–60 |
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Experimental and numerical study of transient laminar counterflow diffusion flames
F. Aguerre, N. Darabiha, J. C. Rolon, S. Candel
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61–66 |
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Recent advances in computational analysis of hypersonic vehicles
R. F. Walter
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66–71 |
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Determination of heat input to duct flow with pseudoshock
P. K. Tret'yakov
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71–77 |
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Numerical modeling of nitrogen oxide formation in turbulent combustion of a premixed gas mixture
A. N. Lipatnikov
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78–81 |
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Ignition and flame propagation in halocarbon-chlorine mixtures subject to UV radiation
O. L. Gromovenko, I. R. Begishev, V. I. Babushok
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82–84 |
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Stability and interval selection in the numerical integration of the equations describing ignition in a turbulent flow
N. K. Bryksenkova, R. S. Tyul’panov
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85–88 |
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Numerical modeling of the ignition of a liquid hydrocarbon layer by a radiant heat pulse
Yu. V. Agabekov, F. G. Yagafarov
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89–93 |
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Ionic structure and sequence of ion formation in acetylene flames
I. A. Larionova, B. S. Fialkov, A. B. Fialkov, K. Ya. Kalinich, B. S. Ospanov
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93–97 |
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Early soot formation stages in low-pressure diffusional counterflow hydrocarbon flames
A. F. Baranov, V. F. Prisnyakov, E. N. Taran
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98–100 |
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Effect of an alternating electric field on soot formation in diffusional low-pressure counterflow hydrocarbon flames
E. N. Taran
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100–105 |
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Free-osciliation regime of diffusional gas combustion in an electric field focused on the preignition zone
V. N. Dashevskii, B. S. Fialkov
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105–110 |
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Formation of NO and NH$^+_4$ ions in the low-temperature peripheral zone of a flame
A. B. Fialkov, K. Ya. Kalinich
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111–115 |
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Investigation on aluminum particles combustion in the flame of solid rocket propellants
R. Akiba, M. Kohno, A. Volpi, S. Tokudome, T. Shibata
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115–119 |
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Mathematical modeling of nonstationary effects at flow around a single burning particle
M. P. Strongin, K. B. Koshelev
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120–123 |
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Calculation of ignition parameters and the transition to combustion in a heterogeneous system
I. G. Dik, A. M. Selikhovkin
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124–129 |
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Physical and chemical transformations of Al–Al$_3$O$_3$ droplets in an active gas flow
V. A. Babuk, V. A. Vasil'ev, O. Ya. Romanov, V. I. Mar'yash, G. A. Tolmachev
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129–133 |
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Self-ignition of dusty media
V. A. Sobolev, E. A. Shchepakina
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133–136 |
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A kinetic model for the combustion of carbon in a porous medium
E. M. Tonkopii, G. B. Manelis, S. V. Kulikov
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136–139 |
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Effects of kinetic-equation form on catalytic combustion parameters in a stationary bed
G. V. Vanin, A. S. Noskov, E. S. Borisova, Yu. Sh. Matros
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139–143 |
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Mechanism of dust ignition in incident shock waves
V. M. Boiko, A. N. Papyrin, S. V. Poplavskii
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144–148 |
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Mechanism of low-speed detonation wave propagation in gas-drop mixtures
V. M. Boiko, V. V. Lotov, A. N. Papyrin
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149–154 |
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Mixing of unburnt gas with reaction products as an explosion mechanism
V. A. Subbotin
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154–158 |
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Modeling of transition from regular structure of cellular gas detonation front to irregular one
A. A. Borisov, O. V. Sharypov
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159–164 |
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Plane initiation of a detonation
N. V. Bannikov, A. A. Vasil'ev
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164–170 |
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Combustion and the transition to detonation in a gas mixture in a closed space
V. I. Makeev, A. A. Ponomarev, V. V. Strogonov
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171–174 |
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