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Three-Dimensional Direct-Shear Behaviors of a Gravel–Structure Interface

AbstractGravel–structure interfaces exist widely in civil engineering practices, and their mechanical behaviors are crucial items in soil–structure interaction analysis. The interfaces are always characterized by three-dimensional (3D) features, which seldom have been explored. This paper presents t...

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Published in:	Journal of geotechnical and geoenvironmental engineering 2018-12, Vol.144 (12)
Main Authors:	Feng, Da-Kuo, Zhang, Jian-Min, Hou, Wen-Jun
Format:	Article
Language:	English
Subjects:	Civil engineering Displacement Gravel Hysteresis Interfaces Mechanical properties Mohr-Coulomb theory Shear strength Shear stress Shear tests Soil Soil analysis Soil mechanics Soil-structure interaction Technical Papers
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container_title	Journal of geotechnical and geoenvironmental engineering
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creator	Feng, Da-Kuo Zhang, Jian-Min Hou, Wen-Jun
description	AbstractGravel–structure interfaces exist widely in civil engineering practices, and their mechanical behaviors are crucial items in soil–structure interaction analysis. The interfaces are always characterized by three-dimensional (3D) features, which seldom have been explored. This paper presents the 3D behaviors of a gravel–structure interface from large-scale two-way beeline, cross, circular, and arc shear tests. The normal displacement can be divided into irreversible and reversible components. The shear stress–displacement hysteretic relationship exhibits an elliptical response in circular shear paths, other than the hyperbolic trend observed in linear shear paths. The shear strength is isotropic, and behaves in accordance with the Mohr–Coulomb failure criterion. The shear path plays a significant role in the 3D interface behaviors. Good consistency is found to exist in the irreversible normal displacement versus shear work density relationship, the reversible normal displacement versus resultant tangential displacement relationship, and the resultant shear stress versus resultant tangential displacement hysteretic relationship, regardless of the shear paths.
doi_str_mv	10.1061/(ASCE)GT.1943-5606.0001968
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The interfaces are always characterized by three-dimensional (3D) features, which seldom have been explored. This paper presents the 3D behaviors of a gravel–structure interface from large-scale two-way beeline, cross, circular, and arc shear tests. The normal displacement can be divided into irreversible and reversible components. The shear stress–displacement hysteretic relationship exhibits an elliptical response in circular shear paths, other than the hyperbolic trend observed in linear shear paths. The shear strength is isotropic, and behaves in accordance with the Mohr–Coulomb failure criterion. The shear path plays a significant role in the 3D interface behaviors. Good consistency is found to exist in the irreversible normal displacement versus shear work density relationship, the reversible normal displacement versus resultant tangential displacement relationship, and the resultant shear stress versus resultant tangential displacement hysteretic relationship, regardless of the shear paths.</abstract><cop>New York</cop><pub>American Society of Civil Engineers</pub><doi>10.1061/(ASCE)GT.1943-5606.0001968</doi></addata></record>
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source	American Society Of Civil Engineers ASCE Journals
subjects	Civil engineering Displacement Gravel Hysteresis Interfaces Mechanical properties Mohr-Coulomb theory Shear strength Shear stress Shear tests Soil Soil analysis Soil mechanics Soil-structure interaction Technical Papers
title	Three-Dimensional Direct-Shear Behaviors of a Gravel–Structure Interface
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