Numerical simulation of adhesion behavior of micro-particIe to a duct wall in a gas-solid two phase flow

Akira Suzuki; Trisaksono Bagus Priambodo; Tsuyoshi Yamamoto; Hideyuki Aoki; Takatoshi Miura

doi:10.1299/kikaib.67.2985

Numerical simulation of adhesion behavior of micro-particIe to a duct wall in a gas-solid two phase flow

Akira Suzuki, Trisaksono Bagus Priambodo, Tsuyoshi Yamamoto, Hideyuki Aoki, Takatoshi Miura

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

Abstract

This study describes numerical approach for adhesion behavior of micro-particle to a duct wall in gas-solid two-phase turbulent flow in a horizontal duct. Flow field was simulated by low Reynolds number k-ε turbulence model to estimate turbulence boundary layer accurately. The particle trajectories were simulated by means of Lagrangian method. The turbulence fluctuation component of fluid velocity was sampled randomly from the Gaussian probability density function based upon turbulence energy. The particle equation included wall- and shear-induced lift and rotary lift to estimate those effects to the particle adhesion behavior near wall region. It is assumed that the particle will stick to the surface when a particle once contacts to the wall. By the introduction of particle-wall collision model, the effect of particle collision angle on particle adhesion was considered. The simulation result for the particle deposition rate reasonably agrees with the experimental and simulation result of the other researchers.

Original language	English
Pages (from-to)	2985-2992
Number of pages	8
Journal	Nihon Kikai Gakkai Ronbunshu, B Hen/Transactions of the Japan Society of Mechanical Engineers, Part B
Volume	67
Issue number	664
DOIs	https://doi.org/10.1299/kikaib.67.2985
Publication status	Published - Dec 2001
Externally published	Yes

All Science Journal Classification (ASJC) codes

Condensed Matter Physics
Mechanical Engineering

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Numerical simulation of adhesion behavior of micro-particIe to a duct wall in a gas-solid two phase flow. / Suzuki, Akira; Priambodo, Trisaksono Bagus; Yamamoto, Tsuyoshi; Aoki, Hideyuki; Miura, Takatoshi.

In: Nihon Kikai Gakkai Ronbunshu, B Hen/Transactions of the Japan Society of Mechanical Engineers, Part B, Vol. 67, No. 664, 12.2001, p. 2985-2992.

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

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title = "Numerical simulation of adhesion behavior of micro-particIe to a duct wall in a gas-solid two phase flow",

abstract = "This study describes numerical approach for adhesion behavior of micro-particle to a duct wall in gas-solid two-phase turbulent flow in a horizontal duct. Flow field was simulated by low Reynolds number k-ε turbulence model to estimate turbulence boundary layer accurately. The particle trajectories were simulated by means of Lagrangian method. The turbulence fluctuation component of fluid velocity was sampled randomly from the Gaussian probability density function based upon turbulence energy. The particle equation included wall- and shear-induced lift and rotary lift to estimate those effects to the particle adhesion behavior near wall region. It is assumed that the particle will stick to the surface when a particle once contacts to the wall. By the introduction of particle-wall collision model, the effect of particle collision angle on particle adhesion was considered. The simulation result for the particle deposition rate reasonably agrees with the experimental and simulation result of the other researchers.",

author = "Akira Suzuki and Priambodo, {Trisaksono Bagus} and Tsuyoshi Yamamoto and Hideyuki Aoki and Takatoshi Miura",

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AU - Suzuki, Akira

AU - Priambodo, Trisaksono Bagus

AU - Yamamoto, Tsuyoshi

AU - Aoki, Hideyuki

AU - Miura, Takatoshi

PY - 2001/12

Y1 - 2001/12

N2 - This study describes numerical approach for adhesion behavior of micro-particle to a duct wall in gas-solid two-phase turbulent flow in a horizontal duct. Flow field was simulated by low Reynolds number k-ε turbulence model to estimate turbulence boundary layer accurately. The particle trajectories were simulated by means of Lagrangian method. The turbulence fluctuation component of fluid velocity was sampled randomly from the Gaussian probability density function based upon turbulence energy. The particle equation included wall- and shear-induced lift and rotary lift to estimate those effects to the particle adhesion behavior near wall region. It is assumed that the particle will stick to the surface when a particle once contacts to the wall. By the introduction of particle-wall collision model, the effect of particle collision angle on particle adhesion was considered. The simulation result for the particle deposition rate reasonably agrees with the experimental and simulation result of the other researchers.

AB - This study describes numerical approach for adhesion behavior of micro-particle to a duct wall in gas-solid two-phase turbulent flow in a horizontal duct. Flow field was simulated by low Reynolds number k-ε turbulence model to estimate turbulence boundary layer accurately. The particle trajectories were simulated by means of Lagrangian method. The turbulence fluctuation component of fluid velocity was sampled randomly from the Gaussian probability density function based upon turbulence energy. The particle equation included wall- and shear-induced lift and rotary lift to estimate those effects to the particle adhesion behavior near wall region. It is assumed that the particle will stick to the surface when a particle once contacts to the wall. By the introduction of particle-wall collision model, the effect of particle collision angle on particle adhesion was considered. The simulation result for the particle deposition rate reasonably agrees with the experimental and simulation result of the other researchers.

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Numerical simulation of adhesion behavior of micro-particIe to a duct wall in a gas-solid two phase flow

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