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Bivol, G. Yu.
48  Ergebnisse:
Personensuche X
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1

Experimental investigation of detonation decay in rough nar..:

Bivol, G.Yu. ; Golovastov, S.V. ; Golub, V.V.
International Journal of Hydrogen Energy.  50 (2024)  - p. 1420-1429 , 2024
Link: https://doi.org/10.1016/..
 
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2

Investigation of hydrogen-air and acetylene-air flame propa..:

Bivol, G. Yu. ; Golovastov, S.V. ; Golub, V.V.
Process Safety and Environmental Protection.  163 (2022)  - p. 368-383 , 2022
Link: https://doi.org/10.1016/..
 
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3

An experimental study of detonation propagation and re-init..:

Golovastov, S. V. ; Bivol, G. Yu. ; Golub, V. V.
Shock Waves.  31 (2021)  1 - p. 49-61 , 2021
Link: https://doi.org/10.1007/..
 
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4

Suppression of hydrogen–air detonation using porous materia..:

Bivol, G. Yu. ; Golovastov, S.V.
International Journal of Hydrogen Energy.  46 (2021)  24 - p. 13471-13483 , 2021
Link: https://doi.org/10.1016/..
 
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5

The effect of porous coating on the flame acceleration in h..:

Bivol, G. Yu. ; Golovastov, S.V.
Process Safety and Environmental Protection.  137 (2020)  - p. 128-139 , 2020
Link: https://doi.org/10.1016/..
 
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6

Detonation Decay and Flame Propagation Through a Channel wi..:

, In: 31st International Symposium on Shock Waves 1,
Bivol, G. Yu ; Golovastov, S. V. ; Golub, V. V. - p. 279-284 , 2019
Link: https://doi.org/10.1007/..
 
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7

Efficiency of the Application of Disperse Materials to Atte..:

Bivol, G. Yu. ; Volodin, V. V. ; Zhilin, Yu. V..
High Temperature.  57 (2019)  1 - p. 130-132 , 2019
Link: https://doi.org/10.1134/..
 
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8

Decaying modes of propagation of detonation and flame front..:

Golovastov, S V ; Bivol, G Yu
Journal of Physics: Conference Series.  1147 (2019)  - p. 012045 , 2019
Link: https://doi.org/10.1088/..
 
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9

Effects of the pore size on hydrogen–air detonation propaga..:

Bivol, G Yu ; Golovastov, S V ; Golub, V V
Journal of Physics: Conference Series.  1147 (2019)  - p. 012046 , 2019
Link: https://doi.org/10.1088/..
 
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10

Decaying Modes of Propagation of Detonation and Flame Front..:

, In: 31st International Symposium on Shock Waves 2,
Golovastov, S. V. ; Bivol, G. Yu. - p. 131-137 , 2019
Link: https://doi.org/10.1007/..
 
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11

Detonation suppression in hydrogen–air mixtures using porou..:

Bivol, G. Yu. ; Golovastov, S. V. ; Golub, V. V.
Shock Waves.  28 (2018)  5 - p. 1011-1018 , 2018
Link: https://doi.org/10.1007/..
 
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12

Impact on blockage of an airflow containing solid particles:

Kotelnikov, A. L. ; Bazhenova, T. V. ; Bivol, G. Yu..
High Temperature.  55 (2017)  1 - p. 162-164 , 2017
Link: https://doi.org/10.1134/..
 
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13

Formation of an overdriven detonation wave in the flow of m..:

Bivol, G. Yu. ; Golovastov, S. V. ; Golub, V. V.
High Temperature.  55 (2017)  4 - p. 561-566 , 2017
Link: https://doi.org/10.1134/..
 
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14

Attenuation and recovery of detonation wave after passing t..:

Bivol, G. Yu. ; Golovastov, S.V. ; Golub, V.V.
Journal of Loss Prevention in the Process Industries.  43 (2016)  - p. 311-314 , 2016
Link: https://doi.org/10.1016/..
 
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15

Prechamber Initiation of Gaseous Detonation in a Channel:

Bivol, G.Yu. ; Golovastov, S. V. ; Golub, V. V.
Combustion Science and Technology.  188 (2016)  7 - p. 1165-1179 , 2016
Link: https://doi.org/10.1080/..
 
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