Abstract
Stress–strain and volume change behavior for clean sands which have distinct particle shape (rounded and angular) with very similar chemical (mineralogical) composition, size, and texture in one-dimensional (1D) compression and drained triaxial compression are presented. The effect of particle morphology on the crushing behavior in one-dimensional loading is explored using laser light diffraction technique which is suitable for particle crushing because of its high resolution and small specimen volume capability. Particle size distribution in both volume/mass and number distributions are considered for improved understanding associated with the process of comminution. Number distributions present a clearer picture of particle crushing. It is argued that particle crushing in granular assemblies initiates in larger particles, rather than in smaller particle. It was found that rounded sand specimens showed greater crushing than angular sand specimens with higher uniformity coefficient. In 1D compression, loose specimens compress approximately 10% more than dense specimens irrespective of particle shape. Densification of angular sand results in improvement in stiffness (approximately 40%) and is comparable to that of loose rounded sand. In general, density has a greater influence on the behavior of granular materials than particle morphology. The effect of particle shape was found to be greater in loose specimens than in dense specimens. The effect of grain shape on critical state friction angle is also quantified.
Highlights
Understanding the depositional characteristics of granular materials and their response to external load is important in many geotechnical applications
This paper presents the role of particle shape on the behavior of granular materials via results of experiments performed on two unground sands with the same mineralogy, similar surface roughness and particle size distribution
One-dimensional compression of rounded and angular sands at loose and dense packing confirm the existence of a unique normal compression lines (NCL) line for similar grading irrespective of particle shape
Summary
Understanding the depositional characteristics of granular materials and their response to external load is important in many geotechnical applications. The angle of shearing resistance is an important measure of the shear strength of granular materials. Attempts have been made to investigate the role of roughness on peak friction angle and dilatancy angle [23]; the effects of roughness and angularity were not decoupled. These studies have generally concluded index densities (emin , emax ) increase with increasing angularity and for a given particle size rounded grains packs more densely than angular grains. The peak friction angle increases with increasing grain angularity
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