Two-phase turbulence models for simulating dense gas-particle flows

Lixing Zhou; Yong Yu; Feipeng Cai; Zhuoxiong Zeng

doi:10.1016/j.partic.2013.06.007

Two-phase turbulence models for simulating dense gas-particle flows

Lixing Zhou^*, Yong Yu, Feipeng Cai, Zhuoxiong Zeng

^*Corresponding author for this work

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

5 Citations (Scopus)

Abstract

The two-fluid model is widely adopted in simulations of dense gas-particle flows in engineering facilities. Present two-phase turbulence models for two-fluid modeling are isotropic. However, turbulence in actual gas-particle flows is not isotropic. Moreover, in these models the two-phase velocity correlation is closed using dimensional analysis, leading to discrepancies between the numerical results, theoretical analysis and experiments. To rectify this problem, some two-phase turbulence models were proposed by the authors and are applied to simulate dense gas-particle flows in downers, risers, and horizontal channels; Experimental results validate the simulation results. Among these models the USM-Θ and the two-scale USM models are shown to give a better account of both anisotropic particle turbulence and particle-particle collision using the transport equation model for the two-phase velocity correlation.

Original language	English
Pages (from-to)	100-107
Number of pages	8
Journal	Particuology
Volume	16
DOIs	https://doi.org/10.1016/j.partic.2013.06.007
Publication status	Published - 1 Oct 2014
Externally published	Yes

Keywords

Anisotropic turbulence
Dense gas-particle flows
Two-phase turbulence models

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title = "Two-phase turbulence models for simulating dense gas-particle flows",

abstract = "The two-fluid model is widely adopted in simulations of dense gas-particle flows in engineering facilities. Present two-phase turbulence models for two-fluid modeling are isotropic. However, turbulence in actual gas-particle flows is not isotropic. Moreover, in these models the two-phase velocity correlation is closed using dimensional analysis, leading to discrepancies between the numerical results, theoretical analysis and experiments. To rectify this problem, some two-phase turbulence models were proposed by the authors and are applied to simulate dense gas-particle flows in downers, risers, and horizontal channels; Experimental results validate the simulation results. Among these models the USM-Θ and the two-scale USM models are shown to give a better account of both anisotropic particle turbulence and particle-particle collision using the transport equation model for the two-phase velocity correlation.",

keywords = "Anisotropic turbulence, Dense gas-particle flows, Two-phase turbulence models",

author = "Lixing Zhou and Yong Yu and Feipeng Cai and Zhuoxiong Zeng",

note = "Publisher Copyright: {\textcopyright} 2013 Chinese Society of Particuology and Institute of Process Engineering, Chinese Academy of Sciences.",

year = "2014",

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doi = "10.1016/j.partic.2013.06.007",

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T1 - Two-phase turbulence models for simulating dense gas-particle flows

AU - Zhou, Lixing

AU - Yu, Yong

AU - Cai, Feipeng

AU - Zeng, Zhuoxiong

PY - 2014/10/1

Y1 - 2014/10/1

N2 - The two-fluid model is widely adopted in simulations of dense gas-particle flows in engineering facilities. Present two-phase turbulence models for two-fluid modeling are isotropic. However, turbulence in actual gas-particle flows is not isotropic. Moreover, in these models the two-phase velocity correlation is closed using dimensional analysis, leading to discrepancies between the numerical results, theoretical analysis and experiments. To rectify this problem, some two-phase turbulence models were proposed by the authors and are applied to simulate dense gas-particle flows in downers, risers, and horizontal channels; Experimental results validate the simulation results. Among these models the USM-Θ and the two-scale USM models are shown to give a better account of both anisotropic particle turbulence and particle-particle collision using the transport equation model for the two-phase velocity correlation.

AB - The two-fluid model is widely adopted in simulations of dense gas-particle flows in engineering facilities. Present two-phase turbulence models for two-fluid modeling are isotropic. However, turbulence in actual gas-particle flows is not isotropic. Moreover, in these models the two-phase velocity correlation is closed using dimensional analysis, leading to discrepancies between the numerical results, theoretical analysis and experiments. To rectify this problem, some two-phase turbulence models were proposed by the authors and are applied to simulate dense gas-particle flows in downers, risers, and horizontal channels; Experimental results validate the simulation results. Among these models the USM-Θ and the two-scale USM models are shown to give a better account of both anisotropic particle turbulence and particle-particle collision using the transport equation model for the two-phase velocity correlation.

KW - Anisotropic turbulence

KW - Dense gas-particle flows

KW - Two-phase turbulence models

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VL - 16

SP - 100

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JO - Particuology

JF - Particuology

ER -

Two-phase turbulence models for simulating dense gas-particle flows

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Keywords

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