Numerical simulation of the in-line pressure jig unit in coal preparation

K. J. Dong; S. B. Kuang; A. Vince; T. Hughes; A. B. Yu

doi:10.1016/j.mineng.2009.10.009

Numerical simulation of the in-line pressure jig unit in coal preparation

K. J. Dong, S. B. Kuang, A. Vince, T. Hughes, A. B. Yu

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

27 Citations (Scopus)

Abstract

This paper presents a numerical study of the multiphase flow in an in-line pressure jig (IPJ), which is a high yield and high recovery gravity separation device widely used in ore processing but may have potential in coal preparation. The mathematical model is developed by use of the combined approach of computational fluid dynamics (CFD) for liquid flow and discrete element method (DEM) for particle flow. It is qualitatively verified by comparing the calculated and measured results under similar conditions. The effects of a few key variables, such as vibration frequency and amplitude, and the size and density of ragging particles, on the flow and separation performance of the IPJ are studied by conducting a series of simulations. The results are analyzed in terms of velocity field, porosity distribution and forces on particles. The findings would be helpful in the design, control and optimisation of an IPJ unit.

Original language	English
Pages (from-to)	301-312
Number of pages	12
Journal	Minerals Engineering
Volume	23
Issue number	4
DOIs	https://doi.org/10.1016/j.mineng.2009.10.009
Publication status	Published - 2010

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10.1016/j.mineng.2009.10.009

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title = "Numerical simulation of the in-line pressure jig unit in coal preparation",

abstract = "This paper presents a numerical study of the multiphase flow in an in-line pressure jig (IPJ), which is a high yield and high recovery gravity separation device widely used in ore processing but may have potential in coal preparation. The mathematical model is developed by use of the combined approach of computational fluid dynamics (CFD) for liquid flow and discrete element method (DEM) for particle flow. It is qualitatively verified by comparing the calculated and measured results under similar conditions. The effects of a few key variables, such as vibration frequency and amplitude, and the size and density of ragging particles, on the flow and separation performance of the IPJ are studied by conducting a series of simulations. The results are analyzed in terms of velocity field, porosity distribution and forces on particles. The findings would be helpful in the design, control and optimisation of an IPJ unit.",

author = "Dong, {K. J.} and Kuang, {S. B.} and A. Vince and T. Hughes and Yu, {A. B.}",

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T1 - Numerical simulation of the in-line pressure jig unit in coal preparation

AU - Dong, K. J.

AU - Kuang, S. B.

AU - Vince, A.

AU - Hughes, T.

AU - Yu, A. B.

PY - 2010

Y1 - 2010

N2 - This paper presents a numerical study of the multiphase flow in an in-line pressure jig (IPJ), which is a high yield and high recovery gravity separation device widely used in ore processing but may have potential in coal preparation. The mathematical model is developed by use of the combined approach of computational fluid dynamics (CFD) for liquid flow and discrete element method (DEM) for particle flow. It is qualitatively verified by comparing the calculated and measured results under similar conditions. The effects of a few key variables, such as vibration frequency and amplitude, and the size and density of ragging particles, on the flow and separation performance of the IPJ are studied by conducting a series of simulations. The results are analyzed in terms of velocity field, porosity distribution and forces on particles. The findings would be helpful in the design, control and optimisation of an IPJ unit.

AB - This paper presents a numerical study of the multiphase flow in an in-line pressure jig (IPJ), which is a high yield and high recovery gravity separation device widely used in ore processing but may have potential in coal preparation. The mathematical model is developed by use of the combined approach of computational fluid dynamics (CFD) for liquid flow and discrete element method (DEM) for particle flow. It is qualitatively verified by comparing the calculated and measured results under similar conditions. The effects of a few key variables, such as vibration frequency and amplitude, and the size and density of ragging particles, on the flow and separation performance of the IPJ are studied by conducting a series of simulations. The results are analyzed in terms of velocity field, porosity distribution and forces on particles. The findings would be helpful in the design, control and optimisation of an IPJ unit.

UR - http://handle.uws.edu.au:8081/1959.7/548276

U2 - 10.1016/j.mineng.2009.10.009

DO - 10.1016/j.mineng.2009.10.009

M3 - Article

SN - 0892-6875

VL - 23

SP - 301

EP - 312

JO - Minerals Engineering

JF - Minerals Engineering

IS - 4

ER -

Numerical simulation of the in-line pressure jig unit in coal preparation

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