Distinct element method analysis of true triaxial test with membrane boundary and its application to failure criteria of soil

Several types of true triaxial test apparatus have been used for real materials with a membrane boundary (flexible boundary). However, the friction at the end face of the specimen have influence on the true triaxial stress state. In this study, a true triaxial test with a membrane boundary was repro...

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Veröffentlicht in:	Japanese Geotechnical Journal 2022/03/01, Vol.17(1), pp.101-113
Hauptverfasser:	HAN, Yusong, KATO, Shoji, KIM, Byeong-Su, PARK, Seong-Wan
Format:	Artikel
Sprache:	jpn
Schlagworte:	Axial stress Boundary conditions Criteria Discrete element method distinct element method Distribution failure criterion Force distribution Friction membrane boundary Membranes Stress Stress-strain relationships Triaxial tests true triaxial test Void ratio
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creator	HAN, Yusong KATO, Shoji KIM, Byeong-Su PARK, Seong-Wan
description	Several types of true triaxial test apparatus have been used for real materials with a membrane boundary (flexible boundary). However, the friction at the end face of the specimen have influence on the true triaxial stress state. In this study, a true triaxial test with a membrane boundary was reproduced without end-face friction using the distinct element method, and the true triaxial tests with constant Lode angle stress paths were simulated. The obtained stress-strain relationship of specimens is similar to that obtained under the wall-element boundary (rigid boundary) condition. This indicates that the difference in boundary conditions does not significantly affect the macroscopic behavior. On the other hand, the micromechanical properties for the inside of the specimen indicate that the membrane boundary contributes to the uniformity of the boundary force distribution, the void ratio distribution near the boundary, and the uniformity of the void ratio inside the specimen. These results suggest that the present analytical conditions reproduce a more ideal true triaxial test. Furthermore, from the examination of three different failure criteria, it was found that the Matsuoka-Nakai’s criterion could be the most suitable for the critical state under an intermediate magnitude of confining pressure used in this study.
doi_str_mv	10.3208/jgs.17.101
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subjects	Axial stress Boundary conditions Criteria Discrete element method distinct element method Distribution failure criterion Force distribution Friction membrane boundary Membranes Stress Stress-strain relationships Triaxial tests true triaxial test Void ratio
title	Distinct element method analysis of true triaxial test with membrane boundary and its application to failure criteria of soil
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