Micro–macro transition and simplified contact models for wet granular materials

Roy, Sudeshna; Singh, Abhinendra; Luding, Stefan; Weinhart, Thomas

doi:10.1007/s40571-015-0061-8

Cited by 33 publications

(46 citation statements)

References 47 publications

(107 reference statements)

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“…Split-Bottom Ring Shear Cell: We use MercuryDPM [4,5], an open-source implementation of the Discrete Particle Method, to simulate a shear cell with annular geometry and a split bottom plate, as explained in [6]. Earlier studies used similar rotating set-ups, including [7,8].…”

Section: Geometrymentioning

confidence: 99%

“…Thus, the shear band remains far away from the inner wall. The inter-particle friction coefficient is μ p = 0.01 and other parameters are detailed in [6].…”

Section: Geometrymentioning

confidence: 99%

“…We use a linear visco-elastic frictional contact model in combination with Willet's capillary bridge model [3,6,10]. In order to see the effect of varying cohesive strength on the macroscopic rheology of wet materials, we vary the intensity of the maximum capillary force f max cap = πdσ cos θ, by varying the surface tension of the liquid σ, while keeping the volume of liquid bridges constant, (V b = 75 nl), corresponding to a liquid saturation of 8% of the voidage.…”

Section: Contact Model and Parametersmentioning

confidence: 99%

“…The macroscopic quantities are obtained by spatial coarse graining with temporal averaging of the system in steady state as detailed in [6,10]. We study the effect of the above mentioned dimensionless numbers on the local volume fraction φ in the critical state [10].…”

Section: Rheological Modelmentioning

confidence: 99%

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Effect of cohesion on local compaction and granulation of sheared soft granular materials

2017

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Abstract. This paper results from an ongoing investigation of the effect of cohesion on the compaction of sheared soft wet granular materials. We compare dry non-cohesive and wet moderately-to-strongly cohesive soft almost frictionless granular materials and report the effect of cohesion between the grains on the local volume fraction. We study this in a three dimensional, unconfined, slowly sheared split-bottom ring shear cell, where materials while sheared are subject to compression under the confining weight of the material above. Our results show that inter-particle cohesion has a considerable impact on the compaction of soft materials. Cohesion causes additional stresses, due to capillary forces between particles, leading to an increase in volume fraction due to higher compaction. This effect is not visible in a system of infinitely stiff particles. In addition, acting oppositely, we observe a general decrease in volume fraction due to increased cohesion for frictional particle, which we attribute to the role of contact friction that enhances dilation.

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Section: Geometrymentioning

confidence: 99%

“…Thus, the shear band remains far away from the inner wall. The inter-particle friction coefficient is μ p = 0.01 and other parameters are detailed in [6].…”

Section: Geometrymentioning

confidence: 99%

Section: Contact Model and Parametersmentioning

confidence: 99%

Section: Rheological Modelmentioning

confidence: 99%

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Effect of cohesion on local compaction and granulation of sheared soft granular materials

2017

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“…[1][2][3]5,6]. With attractive forces involved, like van-der Waals forces or liquid-bridges, this leads to cohesion added on top of the already non-trivial dynamics of granular matter [2,[6][7][8]. Dependent on the energy input (e.g.…”

Section: Introductionmentioning

confidence: 99%

From Particles in Steady State Shear Bands via Micro-Macro to Macroscopic Rheology Laws

Luding

Singh

Roy

et al. 2016

Springer Proceedings in Physics

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Abstract. Particulate systems and granular matter are discrete systems made of many particles; they display interesting dynamic or static, fluid-or solid-like states, respectively -or both together. The challenge of bridging the gap between the particulate, microscopic picture towards their continuum description (via the so-called micro-macro transition) is one of today's challenges of modern research. This short paper gives a brief overview of recent progress and some new insights about local granular flow rules for soft particles.

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Capillary‐bridge forces between solid particles: Insights from lattice Boltzmann simulations

2021

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Liquid capillary-bridge formation between solid particles has a critical influence on the rheological properties of granular materials and, in particular, on the efficiency of fluidized bed reactors. The available analytical and semi-analytical methods have inherent limitations, and often do not cover important aspects, like the presence of non-axisymmetric bridges. Here, we conduct numerical simulations of the capillary bridge formation between equally and unequally-sized solid particles using the lattice Boltzmann method, and provide an assessment of the accuracy of different families of analytical models. We find that some of the models taken into account are shown to perform better than others. However, all of them fail to predict the capillary force for contact angles larger than π/2, where a repulsive capillary force attempts to push the solid particle outwards to minimize the surface energy, especially at a small separation distance. We then apply the most suitable model to study the impact of capillary interactions on particle clustering using a coupled lattice Boltzmann and Discrete Element method. 1This article has been accepted for publication and undergone full peer review but has not been through the copyediting, typesetting, pagination and proofreading process which may lead to differences between this version and the Version of Record. Please cite this article as

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Micro–macro transition and simplified contact models for wet granular materials

Cited by 33 publications

References 47 publications

Effect of cohesion on local compaction and granulation of sheared soft granular materials

Effect of cohesion on local compaction and granulation of sheared soft granular materials

From Particles in Steady State Shear Bands via Micro-Macro to Macroscopic Rheology Laws

Capillary‐bridge forces between solid particles: Insights from lattice Boltzmann simulations

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