Analysis on the mechanical jamming of particle flow using impeller-based rheometer

TL;DR

This study uses DEM simulations and experiments to analyze mechanical jamming in particle flow within an impeller-based rheometer, revealing transient jamming behavior influenced by particle stiffness and flow patterns.

Contribution

It provides new insights into the conditions and dynamics of particle jamming in rheometer flows, highlighting limitations of scaling laws in simulations.

Findings

Jamming occurs transiently and intermittently near the constriction.

Larger particle stiffness and lifting flow increase jamming likelihood.

Jamming frequency is less than 50 Hz, lasting under 0.04 seconds.

Abstract

We simulated the cohesive particle flow in an impeller-based rheometer using Discrete Element Method (DEM), and we focus on the dynamics of particles around the constriction between the blade and its surrounding vessel wall. The results show that mechanical jamming could transiently and intermittently occur in the constriction, but it is limited in a narrow region and short duration. Larger stiffness of particles and lifting flow pattern are more prone to the occurrence of jamming. The scaling law used to speed up the DEM simulation by reducing particle stiffness may fail for particle flow passing through clearance. The mechanical jamming of particles is in low frequency with value less than 50 Hz and the duration of an individual jamming event is usually less than 0.04 s. The existence of mechanical jamming is also illustrated by the experiment, where the wear of particle surface is clearly observed with scratches and pits.