Immersed boundary method (IBM) based direct numerical simulation of open‐cell solid foams: Hydrodynamics

Das, Soumen; Deen, NG Niels; Kuipers, J.A.M.

doi:10.1002/aic.15487

Cited by 36 publications

(29 citation statements)

References 74 publications

(91 reference statements)

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“…The flow at a length scale inside the particles i.e. d μ is not fully resolved, and represented using closure terms, derived separately from fully resolved computations [18]. However, the inter-particle flow (at the length scale of d P ) is fully resolved.…”

Section: Discussionmentioning

confidence: 99%

“…In the present modeling approach, the flow around the particle will be fully resolved, however, the flow inside the particle will be modeled by closure terms developed separately from fully-resolved simulations. a ( ) Packed bed filled with porous non-spherical particles and a Representative Elementary Volume (REV) of a typical foam sample that is fully resolved in a DNS domain [18,38]. b ( ) Macroscopic modeling of the full bed where flow inside the particles is not resolved and instead modeled using volume averaging theory (VAT).…”

Section: Governing Equations and Solution Methodologymentioning

confidence: 99%

“…Although some details of the flow field are lost due to averaging, the hierarchical modeling technique is essential when two substantially different length scales are persist in the problem. The drag closure (flow resistance) for the fluid-foam interaction at the micro-scale has been obtained separately by performing fully resolved direct numerical simulations using idealized geometry of a single unit-cell of open-cell solid foams [18]. The cylindrical wall effect is important for slender packed beds and in the adopted Cartesian computational domain it is resolved by an implicit, sharp interface immersed boundary method (IBM) [19].…”

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confidence: 99%

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Multiscale modeling of fixed-bed reactors with porous (open-cell foam) non-spherical particles: Hydrodynamics

Das

Deen

Kuipers

2018

Chemical Engineering Journal

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A B S T R A C TAn accurate numerical model is proposed to simulate flow through cylindrical fixed-bed reactors with randomly packed porous non-spherical particles. The length scale for flow outside the porous particles (made of open-cell foam) is O (10 ) 2 higher than the size of the internal micro-pores of the particles. To capture the flow at these two different length scales, a multiscale modeling approach, derived using volume averaging theory (VAT), is developed. The flow through and around the porous particles is computed as a single hydrodynamic field in a Cartesian computational domain. The flow within the inter-particle space is fully resolved, whereas, flow at the scale of the intra-particle micro-pores is not resolved and instead represented by closure terms. Random packings of cubic and cuboid particles in cylindrical columns of different diameter are generated using a glued-sphere Discrete Element Method (DEM) approach. The packing structures for different particle-column combinations are analysed. The effects of particle size/shape, column diameter and internal porosity of the particles on the overall pressure drop and flow distribution are investigated. The macroscopic Reynolds number (based on the particle equivalent diameter and the superficial velocity of the bed) is varied from 0.1 to 400. The effect of Reynolds number on pressure drop is analyzed, as well as the reduction in pressure drop due to the presence of the intra-particle pores. In addition, our numerical simulations have helped to elucidate the detailed fluid-solid interaction in complex bi-disperse, dual porosity porous media.

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Section: Discussionmentioning

confidence: 99%

Section: Governing Equations and Solution Methodologymentioning

confidence: 99%

mentioning

confidence: 99%

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Multiscale modeling of fixed-bed reactors with porous (open-cell foam) non-spherical particles: Hydrodynamics

Das

Deen

Kuipers

2018

Chemical Engineering Journal

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“…To explain the simplicity of the method, we consider two cases shown in Figure 1. One case corresponds to the two-dimensional rectangular plate subjected to Dirichlet boundary conditions on the [6] Khadra et al [7] Discrete forcing (FD, FV) unsteady iterative Mohd-Yosuf, [11] Faldun et al, [12] Balaras [13] Cut-cell method (FV) steady or unsteady iterative Udaykumar et al, [15] Ye et al, [16] Udaykumar et al [17] Flag-matrix concept (FD, FV) steady or unsteady iterative Kuipers et al, [18] Deen et al, [19] Das et al [21][22][23] Implicit fictitious boundary (FEM) steady or unsteady iterative…”

Section: Dirichlet Immersed Boundary Conditionmentioning

confidence: 99%

“…This method was extended to include a 3D finite‐volume formulation applied to the DNS of flow and heat transfer in dense fluid‐particle systems and the DNS of a dispersed gas‐liquid two‐phase flow using a volume‐of‐fluid (VOF) approach. Recently, Das et al developed a new second‐order implicit IB method for a structured grid, enabling the incorporation of the Dirichlet, Neumann, and Robin boundary condition types. This method requires a matrix iterative solver.…”

Section: Introductionmentioning

confidence: 99%

Simple immersed boundary matrix‐cut‐method for cartesian grids using FV and FD discretizations

Dierich

Ananiev

Nikrityuk³

2018

Can J Chem Eng

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This work presents a means of implementing a simple implicit Cartesian grid matrix‐cut method to model the heat and mass transfer in irregular geometries using any implicit Cartesian grid solver in finite‐volume and finite‐difference formulations. This method allows the precise imposing of Dirichlet, Neumann, and Robin boundary conditions in any internal node of the grid. The main idea of this method comes from a finite element method where the coefficients of the implicit matrix of a discretized equation are modified directly to ensure the consistency of the presence of the boundary conditions at immersed boundaries represented by grid nodes. One of the advantages of this method is its capability to solve a transport equation implicitly in steady and unsteady modes, applied to complex geometry immersed into the Cartesian grid. This method can be easily implemented in any direct matrix solver, e.g., Gauss elimination, or any iterative matrix solver. To validate this method, different cases are considered.

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Direct numerical simulation of mass transfer in bidisperse arrays of spheres

Peters

Kuipers

2019

AIChE Journal

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In this study, an efficient ghost cell-based immersed boundary method is used to perform direct numerical simulations of mass-transfer processes in bidisperse arrays. Stationary spherical particles, with a size ratio of 1.5, are homogeneously distributed in a periodic domain in the spanwise directions. Simulations are performed over a range of solids volume fractions, volume fraction ratios of small-to-large particles, and Reynolds numbers. Through our studies, we find that large particles have a negative influence on the overall mass-transfer performance; however, the performance of individual particle species is independent on the relative volume fraction ratios. We propose two correlations: (a) a refitted Gunn correlation for a better description of the interfacial transfer performance based on individual particle species; (b) a fractional calculation for a simple estimation of the overall performance in bidisperse systems using characteristics of individual particle species. We also investigate how well the overall masstransfer coefficient can be predicted by defining an appropriate equivalent diameter.

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Immersed boundary method (IBM) based direct numerical simulation of open‐cell solid foams: Hydrodynamics

Cited by 36 publications

References 74 publications

Multiscale modeling of fixed-bed reactors with porous (open-cell foam) non-spherical particles: Hydrodynamics

Multiscale modeling of fixed-bed reactors with porous (open-cell foam) non-spherical particles: Hydrodynamics

Simple immersed boundary matrix‐cut‐method for cartesian grids using FV and FD discretizations

Direct numerical simulation of mass transfer in bidisperse arrays of spheres

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