Standard

Motion of a spherical particle in a rarefied gas. Part 2. Drag and thermal polarization. / Beresnev, S. A.; Chernyak, V. G.; Fomyagin, G. A.
в: Journal of Fluid Mechanics, Том 219, № -1, 01.10.1990, стр. 405.

Результаты исследований: Вклад в журналСтатьяРецензирование

Harvard

Beresnev, SA, Chernyak, VG & Fomyagin, GA 1990, 'Motion of a spherical particle in a rarefied gas. Part 2. Drag and thermal polarization', Journal of Fluid Mechanics, Том. 219, № -1, стр. 405. https://doi.org/10.1017/S0022112090003007

APA

Beresnev, S. A., Chernyak, V. G., & Fomyagin, G. A. (1990). Motion of a spherical particle in a rarefied gas. Part 2. Drag and thermal polarization. Journal of Fluid Mechanics, 219(-1), 405. https://doi.org/10.1017/S0022112090003007

Vancouver

Beresnev SA, Chernyak VG, Fomyagin GA. Motion of a spherical particle in a rarefied gas. Part 2. Drag and thermal polarization. Journal of Fluid Mechanics. 1990 окт. 1;219(-1):405. doi: 10.1017/S0022112090003007

Author

Beresnev, S. A. ; Chernyak, V. G. ; Fomyagin, G. A. / Motion of a spherical particle in a rarefied gas. Part 2. Drag and thermal polarization. в: Journal of Fluid Mechanics. 1990 ; Том 219, № -1. стр. 405.

BibTeX

@article{e851048cc5754e13a9c64b5b4b52adaa,
title = "Motion of a spherical particle in a rarefied gas. Part 2. Drag and thermal polarization",
abstract = "Kinetic theory for the drag and thermal polarization of a spherical particle in a low-speed flow of a rarefied gas is presented. The problem is solved on the basis of the linearized kinetic equation (Shakhov 1974) with the correct Prandtl number, Pr = §, for monatomic gas. The integral-moment method of solution for arbitrary values of the Knudsen number is employed. The possibility of arbitrary energy, and tangential and normal momentum accommodation of gas molecules on the particle surface is taken into account in the boundary condition. The particle-gas heat conductivity ratio A is assumed to be arbitrary. Numerical results for the isothermal drag, radiometric force affecting a nonuniformly heated particle in a rarefied gas, and temperature drop between the ends of the particle diameter owing to its thermal polarization in a gas flow have been obtained. The analytical expressions approximating the numerical calculations for the whole range of Knudsen numbers are given. The results obtained are compared to the available theoretical and experimental data.",
author = "Beresnev, {S. A.} and Chernyak, {V. G.} and Fomyagin, {G. A.}",
year = "1990",
month = oct,
day = "1",
doi = "10.1017/S0022112090003007",
language = "English",
volume = "219",
pages = "405",
journal = "Journal of Fluid Mechanics",
issn = "0022-1120",
publisher = "Cambridge University Press",
number = "-1",

}

RIS

TY - JOUR

T1 - Motion of a spherical particle in a rarefied gas. Part 2. Drag and thermal polarization

AU - Beresnev, S. A.

AU - Chernyak, V. G.

AU - Fomyagin, G. A.

PY - 1990/10/1

Y1 - 1990/10/1

N2 - Kinetic theory for the drag and thermal polarization of a spherical particle in a low-speed flow of a rarefied gas is presented. The problem is solved on the basis of the linearized kinetic equation (Shakhov 1974) with the correct Prandtl number, Pr = §, for monatomic gas. The integral-moment method of solution for arbitrary values of the Knudsen number is employed. The possibility of arbitrary energy, and tangential and normal momentum accommodation of gas molecules on the particle surface is taken into account in the boundary condition. The particle-gas heat conductivity ratio A is assumed to be arbitrary. Numerical results for the isothermal drag, radiometric force affecting a nonuniformly heated particle in a rarefied gas, and temperature drop between the ends of the particle diameter owing to its thermal polarization in a gas flow have been obtained. The analytical expressions approximating the numerical calculations for the whole range of Knudsen numbers are given. The results obtained are compared to the available theoretical and experimental data.

AB - Kinetic theory for the drag and thermal polarization of a spherical particle in a low-speed flow of a rarefied gas is presented. The problem is solved on the basis of the linearized kinetic equation (Shakhov 1974) with the correct Prandtl number, Pr = §, for monatomic gas. The integral-moment method of solution for arbitrary values of the Knudsen number is employed. The possibility of arbitrary energy, and tangential and normal momentum accommodation of gas molecules on the particle surface is taken into account in the boundary condition. The particle-gas heat conductivity ratio A is assumed to be arbitrary. Numerical results for the isothermal drag, radiometric force affecting a nonuniformly heated particle in a rarefied gas, and temperature drop between the ends of the particle diameter owing to its thermal polarization in a gas flow have been obtained. The analytical expressions approximating the numerical calculations for the whole range of Knudsen numbers are given. The results obtained are compared to the available theoretical and experimental data.

UR - http://www.scopus.com/inward/record.url?partnerID=8YFLogxK&scp=0025505367

U2 - 10.1017/S0022112090003007

DO - 10.1017/S0022112090003007

M3 - Article

VL - 219

SP - 405

JO - Journal of Fluid Mechanics

JF - Journal of Fluid Mechanics

SN - 0022-1120

IS - -1

ER -

ID: 55814655