"
Stability of Subsonic Microjet Flows and Combustion"
written by Victor V. Kozlov, Genrich R. Grek, Mikchail M. Katasonov, Oleg P. Korobeinichev, Yury A. Litvinenko, Andrey G. Shmakov,
published by
Journal of Flow Control, Measurement & Visualization,
Vol.1 No.3, 2013
has been cited by the following article(s):
[1]
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УСТОЙЧИВОСТЬ ДОЗВУКОВЫХ МИКРО–СТРУЙ И ИХ ГОРЕНИЕ
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МЕХАНИКА НАНОСТРУКТУРИРОВАННЫХ МАТЕРИАЛОВ И СИСТЕМ
NULL |
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[2]
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A numerical study of a lifted H 2 / N 2 flame excited by an axial and flapping forcing
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Scientific Reports,
2022 |
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[3]
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Adjoint-Based Sensitivity and Optimization of Turbulent Reacting Flows
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2022 |
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[4]
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Control of a Lifted H2/N2 Flame by Axial and Flapping Forcing: A Numerical Study
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2021 |
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[5]
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ACOUSTICS ASSISTED PROPAGATING FIRES AND RELATED IMPLICATIONS
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2021 |
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[6]
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Effect of acoustic energy on onset of fire propagation phenomenon
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Journal of Energy Systems,
2021 |
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[7]
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Flow visualization study of a diffusion flame under acoustic excitation
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2019 |
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[8]
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Явление запирания микросопла при диффузионном горении водорода
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2018 |
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[9]
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Micronozzle Chocking under Diffusion Combustion of Hydrogen
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Doklady Physics,
2018 |
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[10]
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Experimental study on diffusion combustion of high-speed hydrogen round microjets
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International Journal of Hydrogen Energy,
2018 |
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[11]
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Diffusion Combustion of a Hydrogen Microjet at Variations of its Velocity Profile and Orientation of the Nozzle in the Field of Gravitation
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Combustion Science and Technology,
2018 |
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[12]
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УСТОЙЧИВОСТЬ ДОЗВУКОВЫХ МАКРО-И МИКРОСТРУЙНЫХ ТЕЧЕНИЙ И МИКРОСТРУЙНОЕ ГОРЕНИЕ (ОБЗОР)
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2017 |
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[13]
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ЭКСПЕРИМЕНТАЛЬНОЕ ИССЛЕДОВАНИЕ ДИФФУЗИОННОГО ГОРЕНИЯ ВЫСОКОСКОРОСТНОЙ КРУГЛОЙ МИКРОСТРУИ ВОДОРОДА ЧАСТЬ 1 …
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2017 |
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[14]
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ЭКСПЕРИМЕНТАЛЬНОЕ ИССЛЕДОВАНИЕ ДИФФУЗИОННОГО ГОРЕНИЯ ВЫСОКОСКОРОСТНОЙ КРУГЛОЙ МИКРОСТРУИ ВОДОРОДА ЧАСТЬ 2 …
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2017 |
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[15]
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Influence of initial and boundary conditions at the nozzle exit upon diffusion combustion of a hydrogen microjet
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International Journal of Hydrogen Energy,
2017 |
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[16]
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Numerical simulation of free jets
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International Journal of Numerical Methods for Heat & Fluid Flow,
2017 |
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[17]
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Влияние начальных условий на срезе микросопла на диффузионное горение водорода
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2016 |
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[18]
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Influence of Co-flow on Flickering Diffusion Flame
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Flow, Turbulence and Combustion,
2016 |
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[19]
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Влияние направления вектора ускорения силы тяжести Земли на диффузионное горение микроструи водорода
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2016 |
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[20]
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Memorial International Collaboration between IFS Tohoku University and ITAM SB RAS for 20 Years–Advanced coating process and powder synthesis using plasma flows and arcs–
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Rep. Inst. Fluid Science,
2015 |
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[21]
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Visualization of arc and plasma flow patterns for advanced material processing
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Journal of Visualization,
2015 |
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[22]
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LES–CMC study of an excited hydrogen flame
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Combustion and Flame,
2015 |
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[23]
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Memorial International Collaboration between IFS Tohoku University and ITAM SB RAS for 20 Years–Advanced coating process and powder synthesis using …
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2015 |
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[24]
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Jet flows stability and their combustion
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2015 |
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[25]
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Round and plane jet flow stability
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2015 |
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[1]
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Effect of Acoustic Energy on Onset of Fire Propagation Phenomenon
Journal of Energy Systems,
2021
DOI:10.30521/jes.954004
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[2]
|
Effect of acoustic energy on onset of fire propagation phenomenon
Journal of Energy Systems,
2021
DOI:10.30521/jes.954004
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|
|
[3]
|
Micronozzle Chocking under Diffusion Combustion of Hydrogen
Doklady Physics,
2018
DOI:10.1134/S1028335818050026
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|
|
[4]
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Diffusion Combustion of a Hydrogen Microjet at Variations of its Velocity Profile and Orientation of the Nozzle in the Field of Gravitation
Combustion Science and Technology,
2018
DOI:10.1080/00102202.2018.1518323
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[5]
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Visualization of arc and plasma flow patterns for advanced material processing
Journal of Visualization,
2015
DOI:10.1007/s12650-014-0221-6
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[6]
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LES–CMC study of an excited hydrogen flame
Combustion and Flame,
2015
DOI:10.1016/j.combustflame.2015.07.024
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