Particle-resolved simulations and measurements of the flow through a uniform packed bed

Sadowski, Wojciech; Sayyari, Mohammed; di Mare, Francesca; Velten, Christin; Zähringer, Katharina

doi:10.1063/5.0188247

Physics of Fluids

2024

DOI: 10.1063/5.0188247

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Particle-resolved simulations and measurements of the flow through a uniform packed bed

Wojciech Sadowski,

Mohammed Sayyari,

Francesca di Mare

et al.

Abstract: The present study focuses on the assessment of the performance of a finite volume method based, particle-resolved simulation approach to predict the flow through a model packed-bed consisting of 21 layers of spheres arranged in the body centered cubic packing. The unsteady flow developing in the freeboard is also considered. Two highly resolved large eddy simulation were preformed, for two Reynolds numbers, 300 and 500, based on the particle diameter, employing a polyhedral, boundary-conforming mesh. The geome… Show more

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Cited by 2 publications

References 40 publications

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An open-source, adaptive solver for particle-resolved simulations with both subcycling and non-subcycling methods

Li,

et al. 2024

Physics of Fluids

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We present the IAMReX (incompressible flow with adaptive mesh refinement for the eXascale), an adaptive and parallel solver for particle-resolved simulations on the multi-level grid. The fluid equations are solved using a finite-volume scheme on the block-structured semi-staggered grids with both subcycling and non-subcycling methods. The particle-fluid interaction is resolved using the multidirect forcing immersed boundary method. The associated Lagrangian markers used to resolve fluid-particle interface only exist on the finest-level grid, which greatly reduces memory usage. The volume integrals are numerically calculated to capture the free motion of particles accurately, and the repulsive potential model is also included to account for the particle–particle collision. We demonstrate the versatility, accuracy, and efficiency of the present multi-level framework by simulating fluid-particle interaction problems with various types of kinematic constraints. The cluster of monodisperse particles case is presented at the end to show the capability of the current solver in handling multiple particles. It is demonstrated that the three-level AMR (Adaptive Mesh Refinement) simulation leads to a 72.46% grid reduction compared with the single-level simulation. The source code and testing cases used in this work can be accessed at https://github.com/ruohai0925/IAMR/tree/development. Input scripts and raw postprocessing data are also available for reproducing all results.

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An open-source, adaptive solver for particle-resolved simulations with both subcycling and non-subcycling methods

Li,

et al. 2024

Physics of Fluids

View full text Add to dashboard Cite

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A one-field fluid/meso-structure coupling approach for multiscale transport in heterogeneous porous media

Ou,

Xue,

Wan

et al. 2024

Physics of Fluids

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Modeling transport phenomena within heterogeneous porous media poses considerable challenges, particularly on account of the complexity of the involved geometries combined with nonlinear transport interactions. In the present study, a novel one-field modeling approach for multiscale fluid–solid interactions is proposed that does not need any a priori information on permeability. This approach implicitly considers the existence of multiscale structures through a penalization function that encompasses merely one single effective parameter. The definition, determination, as well as the response of the effective parameter to influencing factors are elaborated in detail. It is demonstrated that this approach is effective in representing properly the heterogeneity of solids. The method has been successfully applied to both nonlinear porous media flows and Darcian transport problems, exhibiting comparable accuracy but substantial computational savings as opposed to pore-scale simulations. It leads to more accurate interphase mass transfer predictions and lower computational cost in comparison with the Darcy–Brinkmann–Stokes approach. Overall, this method appears to be highly effective in forecasting realistic, industrial-scale porous media transport problems.

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Particle-resolved simulations and measurements of the flow through a uniform packed bed

Cited by 2 publications

References 40 publications

An open-source, adaptive solver for particle-resolved simulations with both subcycling and non-subcycling methods

An open-source, adaptive solver for particle-resolved simulations with both subcycling and non-subcycling methods

A one-field fluid/meso-structure coupling approach for multiscale transport in heterogeneous porous media

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