Effect of Particle Shape and Confining Pressure on Breakage and Deformation of Artificial Rockfill

Effect of Particle Shape and Confining Pressure on Breakage and Deformation of Artificial Rockfill

The rockfill exhibits a substantial amount of particle breakage when subjected to higher range of stresses. The deformations of rockfill under such excessive stresses often lead to failure and cannot be ignored. The degree of particle breakage is related to the type of the material as well as the pa...

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Veröffentlicht in:International journal of geosynthetics and ground engineering 2019-06, Vol.5 (2), p.1-10, Article 15
Hauptverfasser: Yang, Gui, Yan, Xing, Nimbalkar, Sanjay, Xu, Jianbao
Format: Artikel
Sprache:eng
Schlagworte:
Breakage
Building Materials
Confining
Cylinders
Deformation effects
Engineering
Environmental Science and Engineering
Foundations
Geoengineering
Hydraulics
Modulus of deformation
Original Paper
Particle shape
Pressure effects
Rockfill
Roundness
Shape
Shape effects
Shear tests
Stresses
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Zusammenfassung:The rockfill exhibits a substantial amount of particle breakage when subjected to higher range of stresses. The deformations of rockfill under such excessive stresses often lead to failure and cannot be ignored. The degree of particle breakage is related to the type of the material as well as the particle shape. Based on this, artificially simulated rockfill materials with three different aggregate shapes (prism, cube, and cylinder) were prepared by cement paste-casting method. Through a series of medium-sized triaxial shear tests, the effects of confining pressure and particle shape on the fracture characteristics of the artificial rockfill and its secant modulus were investigated. The useful relationships between particle sphericity and roundness with deformation modulus and particle breakage rate were proposed.
ISSN:2199-9260
2199-9279
DOI:10.1007/s40891-019-0164-z