Rheology of weakly wetted granular materials: a comparison of experimental and numerical data

Schwarze, Rüdiger; Gladky, Anton; Uhlig, Fabian; Luding, Stefan

doi:10.1007/s10035-013-0430-z

Cited by 41 publications

(42 citation statements)

References 42 publications

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“…Earlier studies on wet granular materials have shown that the presence of liquid bridges between the particles results in an increasing steady-state cohesion of the materials [12,13,15,27]. Our earlier studies show that the steady-state cohesion c * increases non-linearly with increasing liquid bridge volume.…”

Section: Steady-state Cohesion and Its Correlation With Liquid Bridgementioning

confidence: 94%

“…This model equation is applicable for mono-disperse particles [12,19], which has been actually extended to poly-disperse system of particles Ref. [14].…”

Section: Liquid Bridge Capillary Force Modelmentioning

confidence: 99%

“…In earlier studies [12,27,40,41], the shear band region was identified by the criterion of large strain rate, e.g., higher than a critical strain rate of 0.08 s −1 . In this paper, the shear band center region is defined by strain rates higher 80 % of the maximum for different heights in the shear cell.…”

Section: Steady-state Cohesion and Its Correlation With Liquid Bridgementioning

confidence: 99%

“…The tensile forces generated at particle level result in cohesion at macroscopic scale. Earlier studies have been done for liquid bridge in the pendular regime to understand the effect of liquid bridge volume and contact angle on different macroscopic quantities like the steady-state cohesion, torque, and shear band properties [12][13][14][15][16]. Other studies for unsaturated granular media observe fluid depletion in shear bands [17,18].…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2015

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Wet granular materials in a quasistatic steadystate shear flow have been studied with discrete particle simulations. Macroscopic quantities, consistent with the conservation laws of continuum theory, are obtained by time averaging and spatial coarse graining. Initial studies involve understanding the effect of liquid content and liquid properties like the surface tension on the macroscopic quantities. Two parameters of the liquid bridge contact model have been identified as the constitutive parameters that influence the macroscopic rheology (i) the rupture distance of the liquid bridge model, which is proportional to the liquid content, and (ii) the maximum adhesive force, as controlled by the surface tension of the liquid. Subsequently, a correlation is developed between these microparameters and the steady-state cohesion in the limit of zero confining pressure. Furthermore, as second result, the macroscopic torque measured at the walls, which is an experimentally accessible parameter, is predicted from our simulation results with the same dependence on the microparameters. Finally, the steady-state cohesion of a realistic non-linear liquid bridge contact model scales well with the steady-state cohesion for a simpler linearized irreversible contact model with the same maximum adhesive force and equal energy dissipated per contact. B Sudeshna Roy

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Section: Steady-state Cohesion and Its Correlation With Liquid Bridgementioning

confidence: 94%

“…This model equation is applicable for mono-disperse particles [12,19], which has been actually extended to poly-disperse system of particles Ref. [14].…”

Section: Liquid Bridge Capillary Force Modelmentioning

confidence: 99%

Section: Steady-state Cohesion and Its Correlation With Liquid Bridgementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

et al. 2015

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“…So far, only a few attempts have been made to answer this question, concerning dense metallic glasses [27,28], adhesive emulsions [29,30], attractive colloids [31][32][33], cemented granular media [34], wet granular media [35,36] and clayey soils [37]. Recently, rheological studies on adhesive emulsions and colloids [29][30][31]33] reported that the presence of attractive forces at contact affects shear banding by affecting flow heterogeneity and wall slip.…”

Section: Introductionmentioning

confidence: 99%

Effect of cohesion on shear banding in quasistatic granular materials

et al. 2014

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It is widely recognized in particle technology that adhesive powders show a wide range of different bulk behavior due to the peculiarity of the particle interaction. We use Discrete Element simulations to investigate the effect of contact cohesion on the steady state of dense powders in a slowly sheared split-bottom Couette cell, which imposes a wide stable shear band. The intensity of cohesive forces can be quantified by the granular Bond number (Bo), namely the ratio between maximum attractive force and average force due to external compression. We find that the shear banding phenomenon is almost independent of cohesion for Bond numbers Bo < 1, but for Bo ≥ 1 cohesive forces start to play an important role, as both width and center position of the band increase for Bo > 1. Inside the shear band, the mean normal contact force is always independent of cohesion and depends only on the confining stress. In contrast, when the behavior is analyzed focusing on the eigen-directions of the local strain rate tensor, a dependence on cohesion shows up. Forces carried by contacts along the compressive and tensile directions are symmetric about the mean force (larger and smaller respectively), while the force along the third, neutral direction follows the mean force. This anisotropy of the force network increases with cohesion, just like the heterogeneity in all (compressive, tensile and neutral) directions.

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Effects of Shear Rate during Energetic Material Processing on Reactivity

et al. 2019

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Energetic materials are often processed at high rates of deformation as colloidal slurries and then cured. The slurries are non-Newtonian colloidal solutions that exhibit changes in microstructure with variations in applied flow. This study shows that changes to microstructure due to applied flow affect the reactivity of energetic thin films. Energetic thin films of identical composition and geometry are prepared with different applied shear rates, which produce variations in the film microstructure by segregating smaller particles toward surfaces. Results show that films exhibit significant gains in flame speed with increasing shear rate. The differences in flame speed are linked to variations in microstructure. Specifically, densification of smaller particles near a boundary promote increased flame speeds. However, when particles become segregated, larger particles tend to contribute less to the overall reaction because they burn slowly compared to the smaller particles. When segregated, the larger particles may not be adding chemical energy to the reaction front because propagation is dominated by the more ignition sensitive smaller particles. This study demonstrates explicit changes in reactivity arising from changes in processing conditions that affect microstructure. Controlling applied shear rate introduces a new approach to regulating energetic material reactivity when processed using extrusion-based advanced manufacturing techniques.

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Rheology of weakly wetted granular materials: a comparison of experimental and numerical data

Cited by 41 publications

References 42 publications

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

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

Effect of cohesion on shear banding in quasistatic granular materials

Effects of Shear Rate during Energetic Material Processing on Reactivity

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