A Three-Dimensional Discrete Element Modeling to Cyclic Response of Geosynthetic-Encased Stone Column

A three-dimensional discrete element modeling of cyclic behavior of geosynthetic-encased stone column (GESC) has been recently conducted to better understand the interaction between geosynthetic encasement and stone aggregates on a microscopic scale. Comparisons between numerical results and laborat...

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Veröffentlicht in:	International journal of geosynthetics and ground engineering 2021-12, Vol.7 (4), Article 75
Hauptverfasser:	Zhang, Ling, Xu, Zeyu, Zhao, Heng, Zhou, Shuai
Format:	Artikel
Sprache:	eng
Schlagworte:	Aggregates Axial compression Axial stress Building Materials Coordination numbers Cyclic loads Densification Discrete element method Engineering Environmental Science and Engineering Foundations Geoengineering Geosynthetics Hydraulics Lateral pressure Model accuracy Original Paper Stiffness Stone Stone columns Three dimensional models
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container_title	International journal of geosynthetics and ground engineering
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creator	Zhang, Ling Xu, Zeyu Zhao, Heng Zhou, Shuai
description	A three-dimensional discrete element modeling of cyclic behavior of geosynthetic-encased stone column (GESC) has been recently conducted to better understand the interaction between geosynthetic encasement and stone aggregates on a microscopic scale. Comparisons between numerical results and laboratory observations indicate a good accuracy of the modeling. Different responses of GESC like deformation characteristics (e.g., axial compression and radial expansion), stress state (e.g., stress and lateral pressure coefficient within the column) are monitored during the simulations for understanding the mechanics of the reinforcement mechanism. To decipher the mechanism of the macro behavior under cyclic loading, the variation of property parameters of stone aggregates on a micro-scale (i.e., porosity and coordination number) within four stages of a loading cycle has been investigated. The stiffness of GESC is found to be prominently improved under cyclic loading as a result of the densification of stone aggregates and increased confinement provided by the geosynthetic encasement.
doi_str_mv	10.1007/s40891-021-00319-1
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J. of Geosynth. and Ground Eng</addtitle><description>A three-dimensional discrete element modeling of cyclic behavior of geosynthetic-encased stone column (GESC) has been recently conducted to better understand the interaction between geosynthetic encasement and stone aggregates on a microscopic scale. Comparisons between numerical results and laboratory observations indicate a good accuracy of the modeling. Different responses of GESC like deformation characteristics (e.g., axial compression and radial expansion), stress state (e.g., stress and lateral pressure coefficient within the column) are monitored during the simulations for understanding the mechanics of the reinforcement mechanism. To decipher the mechanism of the macro behavior under cyclic loading, the variation of property parameters of stone aggregates on a micro-scale (i.e., porosity and coordination number) within four stages of a loading cycle has been investigated. 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J. of Geosynth. and Ground Eng</stitle><date>2021-12-01</date><risdate>2021</risdate><volume>7</volume><issue>4</issue><artnum>75</artnum><issn>2199-9260</issn><eissn>2199-9279</eissn><abstract>A three-dimensional discrete element modeling of cyclic behavior of geosynthetic-encased stone column (GESC) has been recently conducted to better understand the interaction between geosynthetic encasement and stone aggregates on a microscopic scale. Comparisons between numerical results and laboratory observations indicate a good accuracy of the modeling. Different responses of GESC like deformation characteristics (e.g., axial compression and radial expansion), stress state (e.g., stress and lateral pressure coefficient within the column) are monitored during the simulations for understanding the mechanics of the reinforcement mechanism. 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subjects	Aggregates Axial compression Axial stress Building Materials Coordination numbers Cyclic loads Densification Discrete element method Engineering Environmental Science and Engineering Foundations Geoengineering Geosynthetics Hydraulics Lateral pressure Model accuracy Original Paper Stiffness Stone Stone columns Three dimensional models
title	A Three-Dimensional Discrete Element Modeling to Cyclic Response of Geosynthetic-Encased Stone Column
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