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Mathematical Modeling of Evolution of Swirling Turbulent Jet in Coflowing Stream. / Chernykh, G. G.; Demenkov, A. G.

In: Journal of Engineering Thermophysics, Vol. 28, No. 3, 01.07.2019, p. 400-409.

Research output: Contribution to journalArticlepeer-review

Harvard

Chernykh, GG & Demenkov, AG 2019, 'Mathematical Modeling of Evolution of Swirling Turbulent Jet in Coflowing Stream', Journal of Engineering Thermophysics, vol. 28, no. 3, pp. 400-409. https://doi.org/10.1134/S181023281903010X

APA

Vancouver

Chernykh GG, Demenkov AG. Mathematical Modeling of Evolution of Swirling Turbulent Jet in Coflowing Stream. Journal of Engineering Thermophysics. 2019 Jul 1;28(3):400-409. doi: 10.1134/S181023281903010X

Author

Chernykh, G. G. ; Demenkov, A. G. / Mathematical Modeling of Evolution of Swirling Turbulent Jet in Coflowing Stream. In: Journal of Engineering Thermophysics. 2019 ; Vol. 28, No. 3. pp. 400-409.

BibTeX

@article{27039dd6cbc4481a8fa44fe1633f2c10,
title = "Mathematical Modeling of Evolution of Swirling Turbulent Jet in Coflowing Stream",
abstract = "A numerical modeling of a swirling turbulent jet in a coflowing stream was carried out. The flow description involved two second-order mathematical models. The first one includes the averaged equations of motion and the differential equations for transfer of normal Reynolds stresses and dissipation rate in the thin shear layer approximation. The second model relies on the far wake approximation. The distances from the source of the jet in the calculations reached very large values. At small distances, the calculated profiles of the averaged velocity components agree well with the known experimental data from Lavrent{\textquoteright}ev Institute of Hydrodynamics SB RAS. At large distances from the source, the flow becomes close to the self-similar one, with degeneration laws and normalized profiles consistent with the known theoretical concepts of the dynamics of swirling turbulent jets in a coflowing stream. The problem of asymptotic behavior of a nonswirling turbulent jet in a coflowing stream was also considered. A self-similar solution based on numerical experiments was obtained.",
author = "Chernykh, {G. G.} and Demenkov, {A. G.}",
year = "2019",
month = jul,
day = "1",
doi = "10.1134/S181023281903010X",
language = "English",
volume = "28",
pages = "400--409",
journal = "Journal of Engineering Thermophysics",
issn = "1810-2328",
publisher = "Maik Nauka-Interperiodica Publishing",
number = "3",

}

RIS

TY - JOUR

T1 - Mathematical Modeling of Evolution of Swirling Turbulent Jet in Coflowing Stream

AU - Chernykh, G. G.

AU - Demenkov, A. G.

PY - 2019/7/1

Y1 - 2019/7/1

N2 - A numerical modeling of a swirling turbulent jet in a coflowing stream was carried out. The flow description involved two second-order mathematical models. The first one includes the averaged equations of motion and the differential equations for transfer of normal Reynolds stresses and dissipation rate in the thin shear layer approximation. The second model relies on the far wake approximation. The distances from the source of the jet in the calculations reached very large values. At small distances, the calculated profiles of the averaged velocity components agree well with the known experimental data from Lavrent’ev Institute of Hydrodynamics SB RAS. At large distances from the source, the flow becomes close to the self-similar one, with degeneration laws and normalized profiles consistent with the known theoretical concepts of the dynamics of swirling turbulent jets in a coflowing stream. The problem of asymptotic behavior of a nonswirling turbulent jet in a coflowing stream was also considered. A self-similar solution based on numerical experiments was obtained.

AB - A numerical modeling of a swirling turbulent jet in a coflowing stream was carried out. The flow description involved two second-order mathematical models. The first one includes the averaged equations of motion and the differential equations for transfer of normal Reynolds stresses and dissipation rate in the thin shear layer approximation. The second model relies on the far wake approximation. The distances from the source of the jet in the calculations reached very large values. At small distances, the calculated profiles of the averaged velocity components agree well with the known experimental data from Lavrent’ev Institute of Hydrodynamics SB RAS. At large distances from the source, the flow becomes close to the self-similar one, with degeneration laws and normalized profiles consistent with the known theoretical concepts of the dynamics of swirling turbulent jets in a coflowing stream. The problem of asymptotic behavior of a nonswirling turbulent jet in a coflowing stream was also considered. A self-similar solution based on numerical experiments was obtained.

UR - http://www.scopus.com/inward/record.url?scp=85069926582&partnerID=8YFLogxK

U2 - 10.1134/S181023281903010X

DO - 10.1134/S181023281903010X

M3 - Article

AN - SCOPUS:85069926582

VL - 28

SP - 400

EP - 409

JO - Journal of Engineering Thermophysics

JF - Journal of Engineering Thermophysics

SN - 1810-2328

IS - 3

ER -

ID: 21059817