On artificial density treatment for the pressure Poisson equation in the DEM-CFD simulations

The discrete element method (DEM) coupled with computational fluid dynamics (CFD) is regarded to be a standard approach in a numerical calculation of gas-solid flow. When the DEM-CFD method is applied to the simulation of industrial systems, we cannot shy away from the modeling of arbitrary shape wa...

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Bibliographic Details
Published in:Powder technology 2020-07, Vol.372, p.48-58
Main Authors: Mori, Yuki, Takabatake, Kazuya, Tsugeno, Yoshiharu, Sakai, Mikio
Format: Article
Language:English
Subjects:
Coefficients
Computational fluid dynamics
Computer applications
DEM-CFD method
Density
Density scaling technique
Discrete element method
Flow system
Fluid dynamics
Fluid flow
Hydrodynamics
Immersed boundary method
Mathematical models
Poisson equation
Pressure Poisson equation
Scalars
Scaling
Simulation
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Summary:The discrete element method (DEM) coupled with computational fluid dynamics (CFD) is regarded to be a standard approach in a numerical calculation of gas-solid flow. When the DEM-CFD method is applied to the simulation of industrial systems, we cannot shy away from the modeling of arbitrary shape wall boundaries. Very recently, we have developed an innovative wall boundary model in the DEM-CFD simulations, where the signed distance function (SDF) and the immersed boundary method (IBM) are used for the wall boundary in the DEM and CFD. The SDF makes it possible to create an arbitrary shape wall boundary based on the scalar field. The IBM can be used for the wall boundary model by reflecting the number of the SDF points on the local volume fraction in CFD grid. Thus, the arbitrary shape wall boundary can be easily created in the DEM-CFD method by combining the SDF with the IBM. On the other hand, the authors' group has pointed out the necessity of the density scale technique in CFD. In the density scale technique, the density scale coefficient is considered in the calculation of the pressure Poisson equation. When the SDF/IBM is applied to CFD without density scaling technique, an unnatural fluid flow might occur through the wall boundary object. The effect of the density scaling coefficient on a gas-solid flow has not been examined so far. From this background, the influence of the density scale coefficient on a gas-solid flow is investigated in the present study. Through this study, introduction of the density scaling technique is designated to be crucial when the IBM is used for the wall boundary in the DEM-CFD simulation. The density scaling coefficient is shown to be decided not by theory but by experience, and the value should become 100 to 1000 in a typical gas-solid flow system. Besides, it is illustrated that the calculation cost is not influenced by the value of the density scale coefficient in the DEM-CFD simulations. [Display omitted] •The density scaling technique is indispensable in the Advanced DEM-CFD method.•In the Advanced DEM-CFD method, wall boundary can be created by SDF/IBM.•Influence of the density scale coefficient on a gas solid flow is investigated.•Unrealistic gas-solid flow is observed without the density scale technique.•The calculation cost is hardly influenced even if the density scale technique was employed.
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2020.05.116