Experimental and numerical determination of mechanical properties of polygonal wood particles and their flow analysis in silos

TL;DR

This study measures the mechanical properties of polygonal wood particles for DEM modeling, develops a software tool, and validates flow predictions in silos through experiments and simulations, enhancing understanding of granular flow of angular particles.

Contribution

It introduces methods for determining mechanical parameters of polygonal wood particles and integrates them into a DEM model validated against physical silo experiments.

Findings

DEM model accurately predicts flow rates and clogging thresholds

Good agreement between simulated and experimental flow behavior

Validation supports future use of advanced testing for DEM parameterization

Abstract

Responding to a lack in the literature, mechanical properties of polygonal wood particles are determined for use in a discrete element model (DEM) for flow analysis in silos, and some methods are proposed for determining such parameters. The parameters arrived at here have also formed part of the input to the SPOLY software, developed in-house to compute the DEM model with spheropolyhedron elements. The model is validated using a 2D physical model, where prismatic particles with polygonal cross sections are placed inside a silo with variable aperture and hopper angle. Validation includes comparison of flow-rates computed by SPOLY, displacement profiles, and clogging thresholds with experimental results. The good agreement that emerges will encourage future use of miniature triaxial tests, grain-surface profilometry, inclined slope tests, and numerical analysis of the intragranular stresses - toward a direct construction of the contact-deformation relations required in realistic DEM modelling of particle flow with angular-shaped particles.