Mechanical strength of wet particle agglomerates

Mechanical strength of wet particle agglomerates

•Agglomerates of wet particles undergo plastic deformation before breaking.•The plastic strength is proportional to the characteristic capillary stress.•The effect of particle size span is mainly included in the characteristic stress.•The amount of liquid affects the strength through the wet coordin...

Full description

Saved in:
Bibliographic Details
Published in:Mechanics research communications Vol. 92; pp. 1 - 7
Main Authors: Vo, Thanh-Trung, Mutabaruka, Patrick, Nezamabadi, Saeid, Delenne, Jean-Yves, Izard, Edouard, Pellenq, Roland, Radjai, Farhang
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-09-2018
Elsevier
Subjects:
Agglomerate
Capillary force law
Civil Engineering
Diametrical compression
Discrete element method
Engineering Sciences
Granular matter
Mechanics
Mechanics of materials
Plastic strength
Plastic strength
Agglomerate
Granular matter
Discrete element method
Diametrical compression
Capillary force law
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Agglomerates of wet particles undergo plastic deformation before breaking.•The plastic strength is proportional to the characteristic capillary stress.•The effect of particle size span is mainly included in the characteristic stress.•The amount of liquid affects the strength through the wet coordination number. Using particle dynamics simulations, we investigate the strength and microstructure of agglomerates of wet frictional particles subjected to axial compression. The numerical model accounts for the cohesive and viscous effects of the binding liquid up to a debonding distance with the liquid assumed to be distributed homogeneously inside the agglomerate. We show that wet agglomerates undergo plastic deformation due to the rearrangements of primary particles during compression. The compressive strength is thus characterized by the plastic threshold before the onset of failure by the irreversible loss of wet contacts between primary particles. We find that the agglomerate plastic threshold is proportional to the characteristic cohesive stress defined from the liquid-vapor surface tension and the mean diameter of primary particles, with a prefactor that is a nearly linear function of the debonding distance and increases with size span. We analyze the agglomerate microstructure and, considering only the cohesive capillary forces at all bonds between primary particles, we propose an expression of the plastic strength as a function of the texture parameters such as the wet coordination number and packing fraction. This expression is shown to be consistent with our simulations up to a multiplicative factor reflecting the distribution of the capillary bridges.
ISSN:0093-6413
1873-3972
DOI:10.1016/j.mechrescom.2018.07.003