A three-dimensional numerical model for determining the pressure drops in porous media consisting of obstacles of different sizes

Y. Fumoto; R. Liu; Y. Sano; X. Huang

doi:10.2174/1877729501204010001

A three-dimensional numerical model for determining the pressure drops in porous media consisting of obstacles of different sizes

Y. Fumoto, R. Liu, Y. Sano, X. Huang

Faculty of Engineering

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

2 Citations (Scopus)

Abstract

A three-dimensional numerical model is proposed to determine the pressure drops in porous media consisting of obstacles of different sizes. A series of full three-dimensional numerical calculations were performed to reveal complex three-dimensional velocity and pressure fields within three-dimensional porous structures consisting of spheres of different sizes. These numerical results are processed to obtain the macroscopic pressure gradients. An effective diameter concept has been proposed to correlate the resulting macroscopic pressure gradients with the Ergun equation. The most appropriate definition of the effective diameter has been found such that it, when substituted in the Ergun formula, gives the most reasonable estimate on the pressure drop for the given porosity and diameter distribution.

Original language	English
Pages (from-to)	1-8
Number of pages	8
Journal	Open Transport Phenomena Journal
Volume	4
Issue number	1
DOIs	https://doi.org/10.2174/1877729501204010001
Publication status	Published - 2012

Keywords

Ergun equation
Numerical simulation
Permeability
Pressure drop

ASJC Scopus subject areas

Fluid Flow and Transfer Processes

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10.2174/1877729501204010001

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abstract = "A three-dimensional numerical model is proposed to determine the pressure drops in porous media consisting of obstacles of different sizes. A series of full three-dimensional numerical calculations were performed to reveal complex three-dimensional velocity and pressure fields within three-dimensional porous structures consisting of spheres of different sizes. These numerical results are processed to obtain the macroscopic pressure gradients. An effective diameter concept has been proposed to correlate the resulting macroscopic pressure gradients with the Ergun equation. The most appropriate definition of the effective diameter has been found such that it, when substituted in the Ergun formula, gives the most reasonable estimate on the pressure drop for the given porosity and diameter distribution.",

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AU - Sano, Y.

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N2 - A three-dimensional numerical model is proposed to determine the pressure drops in porous media consisting of obstacles of different sizes. A series of full three-dimensional numerical calculations were performed to reveal complex three-dimensional velocity and pressure fields within three-dimensional porous structures consisting of spheres of different sizes. These numerical results are processed to obtain the macroscopic pressure gradients. An effective diameter concept has been proposed to correlate the resulting macroscopic pressure gradients with the Ergun equation. The most appropriate definition of the effective diameter has been found such that it, when substituted in the Ergun formula, gives the most reasonable estimate on the pressure drop for the given porosity and diameter distribution.

AB - A three-dimensional numerical model is proposed to determine the pressure drops in porous media consisting of obstacles of different sizes. A series of full three-dimensional numerical calculations were performed to reveal complex three-dimensional velocity and pressure fields within three-dimensional porous structures consisting of spheres of different sizes. These numerical results are processed to obtain the macroscopic pressure gradients. An effective diameter concept has been proposed to correlate the resulting macroscopic pressure gradients with the Ergun equation. The most appropriate definition of the effective diameter has been found such that it, when substituted in the Ergun formula, gives the most reasonable estimate on the pressure drop for the given porosity and diameter distribution.

KW - Ergun equation

KW - Numerical simulation

KW - Permeability

KW - Pressure drop

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A three-dimensional numerical model for determining the pressure drops in porous media consisting of obstacles of different sizes

Abstract

Keywords

ASJC Scopus subject areas

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