Population Balance Models for Particulate Flows in Porous Media: Breakage and Shear-Induced Events

Icardi, Matteo; Pasquale, Nicodemo Di; Crevacore, Eleonora; Marchisio, Daniele; Bäbler, Matthäus U.

doi:10.1007/s11242-022-01793-5

Cited by 3 publications

(2 citation statements)

References 44 publications

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“…Shear can detach pieces from an isolated aggregate, if the hydrodynamic drag force exerted on the cubes exposed to the flow exceeds their characteristic binding force F bind . We describe this event through the kernel 56 with shear rate .…”

Section: Model and Methodsmentioning

confidence: 99%

Aggregation of amphiphilic nanocubes in equilibrium and under shear

et al. 2023

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Section: Model and Methodsmentioning

confidence: 99%

Aggregation of amphiphilic nanocubes in equilibrium and under shear

et al. 2023

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“…In order to obtain the solution of the PBE, different methods can be employed for different industrial applications. [1][2][3] The quadrature-based moments method (QBMM) accurately captures the dynamics of the particle size distribution while reducing computational complexity compared to other methods, attracting more attention. 4 The most popular QBMM is the quadrature method of moments (QMOM), [5][6][7][8] whereas it is worth mentioning that other moment methods exist beyond QBMM, as, for example, the Taylorseries expansion method of moment (TEMOM).…”

Section: Introductionmentioning

confidence: 99%

Numerical treatments for large eddy simulations of liquid–liquid dispersions via population balance equation

2023

Physics of Fluids

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In this work, we employ the two-fluid model under the large eddy simulations (LES) framework to investigate liquid–liquid dispersions in stirred tanks. The population balance equation was solved by the one primary and one secondary particle method, which was proven as identical as one-node quadrature method of moments. First, Aiyer's break-age kernel was investigated for its capability in the context of chemical stirred tank applications [Aiyer et al., “A population balance model for large eddy simulation of polydisperse droplet evolution,” J. Fluid Mech. 878, 700–739 (2019)]. Second, two new methods were proposed to handle the consistency problem and boundedness problem. These numerical problems were shown in our previous studies but had never been discussed in detail. Three test cases were launched, and results showed that our implementation ensures the moments' boundedness. The inconsistency problem was also treated properly. The predicted diameter also agrees well with experiments. Meanwhile, the phase segregation problem as observed in the unsteady Reynolds-Averaged Navier–Stokes simulations disappeared when a LES turbulence model was employed.

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Editorial to the Special Issue: Mixing in Porous Media

2023

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Mixing in porous media is a key process for a wide range of natural and engineered systems in geological, biological and synthetic porous media. It is a multi-scale phenomenon with spatial scales ranging from micrometers (pores and capillaries) to kilometers (aquifers and reservoirs), and temporal scales that range from seconds to years. Mixing in porous media is an interdisciplinary subject with a diversity of scientific and engineering applications that include the understanding of karst formation, groundwater and soil remediation, underground hydrogen storage, geological radioactive waste storage, geothermal energy production, mining, oil and gas production, porous reactors and batteries, as well as drug delivery, and nutrient transport in biological tissue and capillaries.The quantitative understanding and prediction of mixing is complicated due to the presence of spatial heterogeneity inherent to natural and engineered porous media. Heterogeneity leads to transport, mixing and reaction behaviors that cannot be accounted for using the conventional upscaling paradigm based on constant hydrodynamic dispersion coefficients. In the past two decades, advances in the imaging of porous media structure and processes, and increased computational capabilities (Blunt et al. 2013) have facilitated new experimental, numerical and theoretical approaches (Rolle and Le Borgne 2019) to probe the mechanisms and controls of mixing, and cast them into predictive mathematical models. These developments were discussed at the Lorentz Center workshop on Mixing in Porous Media that was held in Leiden, The Netherlands, from 3 to 7 February 2020. There, the idea for this Special Issue originated with the aim to give an account of recent developments in the field of Mixing in Porous Media. This special issue consists of twenty-two contributions that cover different aspects of mixing in porous and fractured media at the pore and continuum scales, in single fractures and fracture networks.Two review papers report on concepts and approaches for mixing in porous media (Dentz et al. 2022) and the dynamical system approach to transport in porous media (Metcalfe et al. 2022). Nine articles focus on hydrodynamic flow, mixing and dispersion processes on the pore scale and their upscaling to the continuum scale. The papers by Sole-Mari et al. (2022) andOliveira et al. (2022) investigate mixing, reaction and dispersion in the pore space of highly resolved three-dimensional synthetic porous media. The direct numerical * Marco Dentz

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Population Balance Models for Particulate Flows in Porous Media: Breakage and Shear-Induced Events

Cited by 3 publications

References 44 publications

Aggregation of amphiphilic nanocubes in equilibrium and under shear

Aggregation of amphiphilic nanocubes in equilibrium and under shear

Numerical treatments for large eddy simulations of liquid–liquid dispersions via population balance equation

Editorial to the Special Issue: Mixing in Porous Media

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