Finite-volume computation of merging parallel channel flows by a second-moment turbulence closure model

S. Obi; S. Masuda

doi:10.1016/0167-6105(93)90119-9

Finite-volume computation of merging parallel channel flows by a second-moment turbulence closure model

S. Obi, S. Masuda

Department of Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

The mixing process of turbulent shear layer developing in a plane two-dimensional channel has been numerically investigated. Under the condition of various initial shear rates as accomplished by varying the mass flow rate of the two oncoming parallel channel flows, the performance of a second-moment closure model and the k-ε{lunate} model has been examined in terms of representing the overall streamwise flow development as well as the profiles of individual variables. It is shown that the difference between the two models is largely attributable to the evaluation of the production rate of turbulent kinetic energy, the second-moment closure model ensuring a slightly more realistic simulation of the flows out of the equilibrium state of turbulent kinetic energy.

Original language	English
Pages (from-to)	105-114
Number of pages	10
Journal	Journal of Wind Engineering and Industrial Aerodynamics
Volume	46-47
Issue number	C
DOIs	https://doi.org/10.1016/0167-6105(93)90119-9
Publication status	Published - 1993 Aug

ASJC Scopus subject areas

Civil and Structural Engineering
Renewable Energy, Sustainability and the Environment
Mechanical Engineering

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10.1016/0167-6105(93)90119-9

Cite this

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title = "Finite-volume computation of merging parallel channel flows by a second-moment turbulence closure model",

abstract = "The mixing process of turbulent shear layer developing in a plane two-dimensional channel has been numerically investigated. Under the condition of various initial shear rates as accomplished by varying the mass flow rate of the two oncoming parallel channel flows, the performance of a second-moment closure model and the k-ε{lunate} model has been examined in terms of representing the overall streamwise flow development as well as the profiles of individual variables. It is shown that the difference between the two models is largely attributable to the evaluation of the production rate of turbulent kinetic energy, the second-moment closure model ensuring a slightly more realistic simulation of the flows out of the equilibrium state of turbulent kinetic energy.",

author = "S. Obi and S. Masuda",

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doi = "10.1016/0167-6105(93)90119-9",

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T1 - Finite-volume computation of merging parallel channel flows by a second-moment turbulence closure model

AU - Obi, S.

AU - Masuda, S.

PY - 1993/8

Y1 - 1993/8

N2 - The mixing process of turbulent shear layer developing in a plane two-dimensional channel has been numerically investigated. Under the condition of various initial shear rates as accomplished by varying the mass flow rate of the two oncoming parallel channel flows, the performance of a second-moment closure model and the k-ε{lunate} model has been examined in terms of representing the overall streamwise flow development as well as the profiles of individual variables. It is shown that the difference between the two models is largely attributable to the evaluation of the production rate of turbulent kinetic energy, the second-moment closure model ensuring a slightly more realistic simulation of the flows out of the equilibrium state of turbulent kinetic energy.

AB - The mixing process of turbulent shear layer developing in a plane two-dimensional channel has been numerically investigated. Under the condition of various initial shear rates as accomplished by varying the mass flow rate of the two oncoming parallel channel flows, the performance of a second-moment closure model and the k-ε{lunate} model has been examined in terms of representing the overall streamwise flow development as well as the profiles of individual variables. It is shown that the difference between the two models is largely attributable to the evaluation of the production rate of turbulent kinetic energy, the second-moment closure model ensuring a slightly more realistic simulation of the flows out of the equilibrium state of turbulent kinetic energy.

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VL - 46-47

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JO - Journal of Wind Engineering and Industrial Aerodynamics

JF - Journal of Wind Engineering and Industrial Aerodynamics

IS - C

ER -

Finite-volume computation of merging parallel channel flows by a second-moment turbulence closure model

Abstract

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UN SDGs

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