G. Yu. Bivol, S. V. Golovastov, V. V. Golub, “Formation of an overdriven detonation wave in the flow of methane–oxygen mixtures in a variable cross section channel”, TVT, 55:4 (2017), 576–581; High Temperature, 55:4 (2017), 561

Teplofizika vysokikh temperatur

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Teplofizika vysokikh temperatur, 2017, Volume 55, Issue 4, Pages 576–581
DOI: https://doi.org/10.7868/S0040364417030036 (Mi tvt8737)

This article is cited in 11 scientific papers (total in 11 papers)

Heat and Mass Transfer and Physical Gasdynamics

Formation of an overdriven detonation wave in the flow of methane–oxygen mixtures in a variable cross section channel

G. Yu. Bivol^ab, S. V. Golovastov^a, V. V. Golub^a

^a Joint Institute for High Temperatures, Russian Academy of Sciences, Moscow
^b Moscow Institute of Physics and Technology

Full-text PDF (552 kB) Citations (11)

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DOI: https://doi.org/10.7868/S0040364417030036

Abstract: The formation of an overdriven detonation wave in methane-oxygen mixtures in an axially symmetrical channel with a variable cross section was experimentally investigated. The ignition of gas mixture was carried out using the spark gap, located at the closed end of the channel. To create the overcompressed shock detonation wave, the decay of the stationary detonation wave was performed at the transition to the channel of a larger cross section. The created complex of shock wave and flame front, moving behind it, propagated in a channel with conical narrowing. The formation of the overdriven detonation wave, with parameters exceeding the parameters of Chapman–Jouguet stationary detonation by a few times, was registered at the outlet of conical narrowing. The rates and pressures on the front of the detonation wave were determined, depending on the mixture composition. The sizes of detonation cells, diagrams of compression waves propagation, flame front, and detonation wave in a combustion chamber, depending on the mixture composition, were presented.

Funding agency	Grant number
Russian Foundation for Basic Research	13-08-01227
Russian Academy of Sciences - Federal Agency for Scientific Organizations	``Горение и взрыв''

Received: 07.05.2015
Accepted: 13.10.2015

English version:
High Temperature, 2017, Volume 55, Issue 4, Pages 561–566
DOI: https://doi.org/10.1134/S0018151X17030038

Bibliographic databases:

Document Type: Article

UDC: 544.454.3

Language: Russian

Citation: G. Yu. Bivol, S. V. Golovastov, V. V. Golub, “Formation of an overdriven detonation wave in the flow of methane–oxygen mixtures in a variable cross section channel”, TVT, 55:4 (2017), 576–581; High Temperature, 55:4 (2017), 561–566

Citation in format AMSBIB

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Linking options:

https://www.mathnet.ru/eng/tvt8737

https://www.mathnet.ru/eng/tvt/v55/i4/p576

This publication is cited in the following 11 articles:

Yasong Qi, Yaqi Zhao, Kaiyuan Tan, Yong Han, “Detonation product equation of state for overdriven detonations in triaminotrinitrobenzene-based plastic-bonded explosive”, Physics of Fluids, 37:1 (2025)
A. Yu. Varaksin, TVT, 61:6 (2023), 803–806
A. Yu. Varaksin, “Heat and Mass Transfer and Physical Gas Dynamics in the Pages of the Journal High Temperature on the Journal's 60th Anniversary”, High Temp, 61:6 (2023), 739
B. Zhang, Yu. Li, H. Liu, “Ignition behavior and the onset of quasi-detonation in methane-oxygen using different end wall reflectors”, Aerosp. Sci. Technol., 116 (2021), 106873
D. Chen, X. Gao, B. Xue, H.-H. Ma, L.-Q. Wang, “Experimental study on the propagation characteristics of detonation wave in annular channels with convergent cross-sections”, Fuel, 300 (2021), 120946
A. Yu. Varaksin, “Two-phase flows with solid particles, droplets, and bubbles: Problems and research results (review)”, High Temperature, 58:4 (2020), 595–614
V. Yu. Gidaspov, D. S. Kononov, N. S. Severina, “Simulation of the ignition and detonation of methane–air mixtures behind a reflected shock wave”, High Temperature, 58:6 (2020), 846–851
V. Yu. Gidaspov, N. S. Severina, “Modeling of detonation of metal-gas combustible mixtures in high-speed flow behind a shock wave”, High Temperature, 57:4 (2019), 514–524
Ya. Liu, J. Yin, Zh. Wang, “Study on the overdriven detonation wave propagation in double-layer shaped charge”, Phys. Fluids, 31:9 (2019), 092110
V. Yu. Gidaspov, O. A. Moskalenko, N. S. Severina, “Numerical study of the influence of water droplets on the structure of a detonation wave in a hydrogen–air fuel mixture”, High Temperature, 56:5 (2018), 751–757
S. V. Golovastov, G. Yu. Bivol, “Deficit of Stationary Detonation Velocity in Hydrogen-oxygen Mixtures Propagated in a Detonation Pipe of a Subcritical Diameter”, Nauka obraz. (Mosk.), 2018, no. 12, 22

Citing articles in Google Scholar: Russian citations, English citations
Related articles in Google Scholar: Russian articles, English articles

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References:	51
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