Your search keyword '"A. S. Tambovzev"' showing total 3 results

1. Hydrogen Micro Jet Diffusion Combustion in a Coaxial Air Jet

Author

M. V. Litvinenko, A. S. Tambovzev, Valery V. Kozlov, Genrich R. Grek, Andrey G. Shmakov, and Yu. A. Litvinenko

Subjects

Jet (fluid), Materials science, Hydrogen, Astrophysics::High Energy Astrophysical Phenomena, Nozzle, Diffusion flame, Computational Mechanics, General Physics and Astronomy, chemistry.chemical_element, Mechanics, Combustion, Physics::Fluid Dynamics, chemistry, Mechanics of Materials, Supersonic speed, Outflow, Physics::Chemical Physics, Coaxial, Physics::Atmospheric and Oceanic Physics, Astrophysics::Galaxy Astrophysics

Abstract

In this paper the results of experimental studies of the combustion of a round microjet of hydrogen in a ring subsonic coaxial air jet are presented. It is shown that the combustion scenario for a subsonic hydrogen jet outflow is associated with the presence of a “bottleneck flame region” and nozzle heating, but the initial spherical shape of the flame region is transformed into a cylindrical one. It was found that the combustion of a round microjet of hydrogen in a satellite ring coaxial air jet at a supersonic outflow velocity is accompanied by the presence of supersonic cells.

Published

2021

2. Diffusion Combustion during Interaction of a Supersonic Round Microjet of Air with a Coaxial (Coflowing Ring) Jet of Hydrogen

Author

Andrey G. Shmakov, A. S. Tambovzev, Yu. A. Litvinenko, M. V. Litvinenko, and Valery V. Kozlov

Subjects

Jet (fluid), Materials science, Hydrogen, 05 social sciences, Diffusion flame, Nozzle, Computational Mechanics, General Physics and Astronomy, chemistry.chemical_element, Laminar flow, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Combustion, chemistry, Mechanics of Materials, 0502 economics and business, Supersonic speed, 050207 economics, Coaxial, 0210 nano-technology

Abstract

The results of experimental investigations of the features of diffusion combustion during the interaction of a round supersonic microjet of air in the center and a coaxial (coflowing ring) jet of hydrogen. Such combustion is accompanied by a number of new phenomena: the formation of a cone-shaped flame near the nozzle сutoff, the locking of the combustion region in this cone, the presence of small-scale supersonic cells in the resulting flow, and the formation of laminar sections and their turbulization.

Published

2021

3. Air Round Microjet Interaction with Coaxial Hydrogen Jet at It Combustion for Supersonic Speed Jets Efflux

Author

A. S. Tambovzev, V. V. Kozlov, Andrey G. Shmakov, M. V. Litvinenko, Genrih R. Grek, and Yu. A. Litvinenko

Subjects

Jet (fluid), Materials science, Hydrogen, chemistry, chemistry.chemical_element, Supersonic speed, Mechanics, Coaxial, Combustion

Abstract

Results of experimental studies of the round air microjet interaction with a coaxial hydrogen jet at its combustion for supersonic speed jets efflux are presented in this work. It is revealed that combustion of the coaxial hydrogen jet with growth of its speed efflux is accompanied by all scenarios, observed at study of the round and plane hydrogen microjets diffusion combustion. However, “bottleneck flame region” undergoes considerable geometrical deformations because of specifics of a flame of a coaxial jet. It is shown that “bottleneck flame region” is transformed from Y-shaped to spherical shape in the activity of growth of a coaxial jet speed efflux. It is found that a round air microjet interaction with a coaxial hydrogen jet at its combustion is accompanied by several new phenomena: existence of cone-shaped area a coaxial jet combustion near a nozzle exit; existence of small-scale supersonic cells on a resultant flame; absence of the hydrogen combustion efflux from combustion region of a coaxial jet near nozzle exit; flame-out from combustion region of a coaxial jet near nozzle exit that leads to hydrogen ignition downstream, its intensive combustion and sharp acoustic noise occurrence; existence of a turbulent flame, to its separation from a nozzle exit and transition to supersonic combustion of a resultant jet.

Published

2019