Citations (23)
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Dmitry Tropin. (2023) Numerical Simulation of Plane and Cellular Detonation Wave Suppression in Hydrogen-Air Mixture by Inert Porous Filters. Combustion Science and Technology 195:7, pages 1389-1410.
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D.A. Tropin & I.A. Bedarev. (2021) Problems of Detonation Wave Suppression in Hydrogen-Air Mixtures by Clouds of Inert Particles in One- and Two-dimensional Formulation. Combustion Science and Technology 193:2, pages 197-210.
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Dmitry Tropin & Aleksandr Fedorov. (2019) Physical and mathematical modeling of interaction of detonation waves in mixtures of hydrogen, methane, silane, and oxidizer with clouds of inert micro- and nanoparticles. Combustion Science and Technology 191:2, pages 275-283.
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A.V. Fedorov, D.A. Tropin & P.A. Fomin. (2018) Mathematical modeling of the detonation wave structure in the silane-air mixture. Combustion Science and Technology 190:6, pages 1041-1059.
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Articles from other publishers (19)
Yong Xu, Pikai Zhang, Qingyang Meng, Shangpeng Li & Huangwei Zhang. (2023) Transmission of hydrogen detonation across a curtain of dilute inert particles. Combustion and Flame 254, pages 112834.
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T. A. Khmel & S. A. Lavruk. (2023) Interaction of Cellular Detonation in Aluminum Particle Suspensions with Nonuniform Concentrations and Clouds of Inert Particles. Combustion, Explosion, and Shock Waves 59:3, pages 308-320.
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S. A. Lavruk & D. A. Tropin. Numerical simulation of the interaction of a heterogeneous detonation wave with a porous medium. Numerical simulation of the interaction of a heterogeneous detonation wave with a porous medium.
D. A. Tropin & K. A. Vyshegorodcev. Interaction of cellular detonation wave in hydrogen-air mixture with inert porous filter. Interaction of cellular detonation wave in hydrogen-air mixture with inert porous filter.
Dmitry Tropin. (2022) Numerical modeling of suppression of detonation waves in hydrogen-air mixture by system of inert particles clouds. International Journal of Hydrogen Energy 47:66, pages 28699-28709.
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D. A. Tropin & S. A. Lavruk. (2022) Physicomathematical Modeling of Attenuation of Homogeneous and Heterogeneous Detonation Waves by Clouds of Water Droplets. Combustion, Explosion, and Shock Waves 58:3, pages 327-336.
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U. A. Nazarov. (2022) Interruption of Detonation Wave Propagation in Monofuel–Air Mixtures by a Layer of Inhomogeneous Inert Particles. Combustion, Explosion, and Shock Waves 57:6, pages 693-703.
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Dmitry Tropin & Igor Bedarev. (2021) Physical and mathematical modeling of interaction of detonation waves with inert gas plugs. Journal of Loss Prevention in the Process Industries 72, pages 104595.
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D. A. Tropin & P. A. Fomin. Explosion and detonation characteristics of silane- and propylene-based mixtures. Explosion and detonation characteristics of silane- and propylene-based mixtures.
D. A. Tropin & E. S. Bochenkov. Modeling the interaction of detonation waves in hydrogen-air mixtures with a series of clouds of inert particles. Modeling the interaction of detonation waves in hydrogen-air mixtures with a series of clouds of inert particles.
Sergey Lavruk & Dmitry Tropin. Mathematical model of the interaction of a heterogeneous detonation wave with a suspension of water droplets. Mathematical model of the interaction of a heterogeneous detonation wave with a suspension of water droplets.
S A Lavruk & D A Tropin. (2019) Investigation of the heterogeneous detonation suppression by clouds of inert particles and droplet suspension. Journal of Physics: Conference Series 1404:1, pages 012062.
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I A Bedarev. (2018) Numerical simulation of the suppression of cellular detonation by inert particles. Journal of Physics: Conference Series 1128, pages 012060.
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P. A. Fomin & D. A. Tropin. Explosion and detonation characteristics of silane- and propylene-based mixtures. Explosion and detonation characteristics of silane- and propylene-based mixtures.
Alexander Fedorov & Sergey Lavruk. Propagation of a cloud of inert alumina particles in a plane channel. Propagation of a cloud of inert alumina particles in a plane channel.
A. V. Fedorov, D. A. Tropin & P. A. Fomin. Comparison of detailed and reduced kinetics mechanisms of silane oxidation in the basis of detonation wave structure problem. Comparison of detailed and reduced kinetics mechanisms of silane oxidation in the basis of detonation wave structure problem.
I. A. Bedarev & A. V. Fedorov. (2017) Mathematical modeling of the detonation wave and inert particles interaction at the macro and micro levels. Journal of Physics: Conference Series 894, pages 012008.
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D. A. Tropin, A. V. Fedorov & P. A. Fomin. Physical and mathematical modeling of one-dimensional and two-dimensional structures of detonation waves in a silane-air mixture. Physical and mathematical modeling of one-dimensional and two-dimensional structures of detonation waves in a silane-air mixture.
I. A. Bedarev & A. V. Fedorov. Modeling the suppression of cellular detonation in a hydrogen-air mixture by inert particles. Modeling the suppression of cellular detonation in a hydrogen-air mixture by inert particles.