Journal
POWDER TECHNOLOGY
Volume 398, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.powtec.2022.117112
Keywords
Granular flow; Cohesion; Viscous liquid; Discrete element model
Categories
Funding
- IChemE Andrew Fellowship
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This study investigates collisions between spherical particles with a thin layer of viscous liquid, where viscous forces dominate. The measurements and simulations show that the viscous force scales with the inverse of the separation distance between particles. Four theoretical models were examined, and the best agreement was obtained when accounting for surface curvature and using an empirically-fitted glass transition pressure model to determine the minimum approach distance.
This study examines granular collisions between spherical particles coated with a thin layer of viscous liquid, such that the capillary number is high and viscous forces dominate. Measurements were performed using high-speed particle tracking velocimetry. The measurements were used to examine four theoretical models that describe the collisions. The viscous force scales with the inverse of the separation distance between particles. The models limit the viscous force by setting a minimum approach distance. A fair match between experiments and simulations was obtained for all models by fitting this minimum approach distance. However, in some cases, to achieve a good match to the experiments, the minimum approach distance had to be set to a non-physical value. The best, and most physically reasonable, agreement was obtained when the viscous force accounted for the curvature of the surface and the minimum approach distance was determined using an empirically-fitted glass transition pressure model. (C) 2022 Elsevier B.V. All rights reserved.
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