Axial segregation of granular mixtures in laterally shaken multi-trapezium channels

TL;DR

This study explores how granular mixtures segregate axially in a laterally shaken trapezium-channel, revealing optimal shaking frequencies and geometric conditions that enhance segregation, supported by experiments and discrete element simulations.

Contribution

It introduces a combined experimental and simulation analysis of granular segregation in trapezium channels, linking segregation quality to interfacial pressure gradients and channel geometry.

Findings

Segregation quality depends on shaking frequency with an optimal value.

Optimal frequency decreases as grain size ratio increases.

Segregation improves with increased axial offset of sidewalls.

Abstract

We investigate axial segregation of binary mixtures in a laterally shaken horizontal channel formed by ratchet-like sidewalls that appear as concatenated trapeziums when not offset axially. Grain mixtures shaken in such a channel are observed to segregate in two stages: they first separate rapidly into two vertically arranged layers and, then, these layers move axially in opposite directions, segregating the two species. Here, we conduct experiments to study the influence on the segregation process of various parameters: the size ratio of grains, the shaking frequency and the channel's geometry. We find that (a) segregation quality depends upon shaking frequency and it is possible to find a unique optimal frequency for segregation, (b) the optimal frequency lowers with increase in size ratio, (c) segregation is generally poorer when the sidewalls are more inclined to each other, and (d) segregation is improved when the sidewalls are axially offset from each other. We then carry out discrete element simulations of the segregation process in order to relate the experimental observations to the interfacial pressure gradient mechanism of Bhateja et al. [Bhateja, A., I. Sharma and J. K. Singh 2017. Segregation physics of a macroscale granular ratchet, Phys. Rev. Fluids 2, 052301]. We demonstrate that the segregation quality correlates well with the scaled interfacial pressure gradient, which is the ratio of the interfacial pressure gradient between the layers, formed in the first stage of the segregation process, to the axial body force provided by the tapered sidewalls.