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Experimental investigation of shear strength of sands with inherent fabric anisotropy
Abstract Loading direction-dependent strength of sand has been traditionally characterized in the principal stress space as a direct extension of the Mohr–Coulomb criterion. A recent study found that it is more appropriate to define anisotropic strength of sand on failure/shear planes, but this proposition has only been demonstrated with discrete element method (DEM) simulations. The present study experimentally investigates anisotropic shear strength of sands in this new framework. Three granular materials with distinct grain characteristics ranging from smooth and rounded particles to flaky and angular particles are tested with the bedding plane inclination angle ψ b varying over the full range of 0°–180°. The main objective is to study how the peak friction angle ϕ p of sand is affected by the ψ b angle and how the ψ b–ϕ p relationship evolves with the change of characteristics of constituent sand particles. We find that the general trend of ψ b–ϕ p curves for real sands resembles what was predicted by DEM in a previous study, whereas rich anisotropic strength behavior is revealed by the laboratory data. The effects of normal stress and initial density, as well as shear dilation behavior at different shear directions, are also studied.
Experimental investigation of shear strength of sands with inherent fabric anisotropy
Abstract Loading direction-dependent strength of sand has been traditionally characterized in the principal stress space as a direct extension of the Mohr–Coulomb criterion. A recent study found that it is more appropriate to define anisotropic strength of sand on failure/shear planes, but this proposition has only been demonstrated with discrete element method (DEM) simulations. The present study experimentally investigates anisotropic shear strength of sands in this new framework. Three granular materials with distinct grain characteristics ranging from smooth and rounded particles to flaky and angular particles are tested with the bedding plane inclination angle ψ b varying over the full range of 0°–180°. The main objective is to study how the peak friction angle ϕ p of sand is affected by the ψ b angle and how the ψ b–ϕ p relationship evolves with the change of characteristics of constituent sand particles. We find that the general trend of ψ b–ϕ p curves for real sands resembles what was predicted by DEM in a previous study, whereas rich anisotropic strength behavior is revealed by the laboratory data. The effects of normal stress and initial density, as well as shear dilation behavior at different shear directions, are also studied.
Experimental investigation of shear strength of sands with inherent fabric anisotropy
Tong, Zhaoxia (author) / Fu, Pengcheng (author) / Zhou, Shaopeng (author) / Dafalias, Yannis F. (author)
Acta Geotechnica ; 9 ; 257-275
2014-02-01
19 pages
Article (Journal)
Electronic Resource
English
Anisotropic strength , Direct shear test , Fabric anisotropy , Sand strength , Shear strength Engineering , Geoengineering, Foundations, Hydraulics , Continuum Mechanics and Mechanics of Materials , Geotechnical Engineering & Applied Earth Sciences , Soil Science & Conservation , Soft and Granular Matter, Complex Fluids and Microfluidics , Structural Mechanics
Experimental investigation of shear strength of sands with inherent fabric anisotropy
| British Library Online Contents | 2014
Experimental investigation of shear strength of sands with inherent fabric anisotropy
| Online Contents | 2014
| Springer Verlag | 2015
| British Library Online Contents | 2015