Numerical Simulation and Microscopic Stress Mechanism for the Microscopic Pore Deformation during Soil Compression

Pore structure is closely related with strength, constitutive relation, consolidation characteristics, and permeability properties of soil. Consequently, improving the understanding of the relationship between microscopic structure and macroscopic physical and mechanical properties has extremely imp...

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Main Authors: Gaoliang Tao, Wan Peng, Henglin Xiao, Xiaokang Wu, Yin Chen
Format: Article
Language:English
Published: Hindawi Limited 2019-01-01
Series:Advances in Civil Engineering
Online Access:http://dx.doi.org/10.1155/2019/1542797
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spelling doaj-f38130a69d7d4b338934c65cc6f809d62020-11-25T02:26:23ZengHindawi LimitedAdvances in Civil Engineering1687-80861687-80942019-01-01201910.1155/2019/15427971542797Numerical Simulation and Microscopic Stress Mechanism for the Microscopic Pore Deformation during Soil CompressionGaoliang Tao0Wan Peng1Henglin Xiao2Xiaokang Wu3Yin Chen4Hubei Provincial Ecological Road Engineering Technology Research Center, Hubei University of Technology, Wuhan 430068, ChinaHubei Provincial Ecological Road Engineering Technology Research Center, Hubei University of Technology, Wuhan 430068, ChinaHubei Provincial Ecological Road Engineering Technology Research Center, Hubei University of Technology, Wuhan 430068, ChinaHubei Provincial Ecological Road Engineering Technology Research Center, Hubei University of Technology, Wuhan 430068, ChinaHubei Provincial Ecological Road Engineering Technology Research Center, Hubei University of Technology, Wuhan 430068, ChinaPore structure is closely related with strength, constitutive relation, consolidation characteristics, and permeability properties of soil. Consequently, improving the understanding of the relationship between microscopic structure and macroscopic physical and mechanical properties has extremely important scientific significance. A large number of studies have shown that pores of soil have fractal features, and hence, the carpet model can be used to approximately simulate the fractal structure of clay. In the present study, ANSYS software was selected to establish a microscopic model of clay to study the distribution of microscopic stress and microscopic deformation characteristics of pores under different consolidation pressures. Besides, the variation law of microscopic pore size was quantitatively determined by using IPP (Image-Pro Plus) software. Combined with the fractal theory, the changes of microscopic pore of numerical simulation and that of physical experiment during compression of clay are studied. All the results indicated that the microscopic stress distribution of clay is not uniform on the compaction process. The larger the pore size is, the bigger the compression stress on both sides and the greater the bending deformation of upper part of the pore is, which leads to the deformation of larger pores which is bigger than that of smaller pores. Based on the results, issues about the microscopic mechanism of the difference in vertical and horizontal permeability under compression of clay, the relationship between the changes of pore shape and microscopic stress, the preliminary principle of “preferential crush of larger particles” for granular soil, skeleton stress across the region where stiffness is relative larger, and the self-protection of particles and pores are also discussed. The results of this study are of great importance in understanding of soil compression and related physical and mechanical properties from the microscopic view.http://dx.doi.org/10.1155/2019/1542797
collection DOAJ
language English
format Article
sources DOAJ
author Gaoliang Tao
Wan Peng
Henglin Xiao
Xiaokang Wu
Yin Chen
spellingShingle Gaoliang Tao
Wan Peng
Henglin Xiao
Xiaokang Wu
Yin Chen
Numerical Simulation and Microscopic Stress Mechanism for the Microscopic Pore Deformation during Soil Compression
Advances in Civil Engineering
author_facet Gaoliang Tao
Wan Peng
Henglin Xiao
Xiaokang Wu
Yin Chen
author_sort Gaoliang Tao
title Numerical Simulation and Microscopic Stress Mechanism for the Microscopic Pore Deformation during Soil Compression
title_short Numerical Simulation and Microscopic Stress Mechanism for the Microscopic Pore Deformation during Soil Compression
title_full Numerical Simulation and Microscopic Stress Mechanism for the Microscopic Pore Deformation during Soil Compression
title_fullStr Numerical Simulation and Microscopic Stress Mechanism for the Microscopic Pore Deformation during Soil Compression
title_full_unstemmed Numerical Simulation and Microscopic Stress Mechanism for the Microscopic Pore Deformation during Soil Compression
title_sort numerical simulation and microscopic stress mechanism for the microscopic pore deformation during soil compression
publisher Hindawi Limited
series Advances in Civil Engineering
issn 1687-8086
1687-8094
publishDate 2019-01-01
description Pore structure is closely related with strength, constitutive relation, consolidation characteristics, and permeability properties of soil. Consequently, improving the understanding of the relationship between microscopic structure and macroscopic physical and mechanical properties has extremely important scientific significance. A large number of studies have shown that pores of soil have fractal features, and hence, the carpet model can be used to approximately simulate the fractal structure of clay. In the present study, ANSYS software was selected to establish a microscopic model of clay to study the distribution of microscopic stress and microscopic deformation characteristics of pores under different consolidation pressures. Besides, the variation law of microscopic pore size was quantitatively determined by using IPP (Image-Pro Plus) software. Combined with the fractal theory, the changes of microscopic pore of numerical simulation and that of physical experiment during compression of clay are studied. All the results indicated that the microscopic stress distribution of clay is not uniform on the compaction process. The larger the pore size is, the bigger the compression stress on both sides and the greater the bending deformation of upper part of the pore is, which leads to the deformation of larger pores which is bigger than that of smaller pores. Based on the results, issues about the microscopic mechanism of the difference in vertical and horizontal permeability under compression of clay, the relationship between the changes of pore shape and microscopic stress, the preliminary principle of “preferential crush of larger particles” for granular soil, skeleton stress across the region where stiffness is relative larger, and the self-protection of particles and pores are also discussed. The results of this study are of great importance in understanding of soil compression and related physical and mechanical properties from the microscopic view.
url http://dx.doi.org/10.1155/2019/1542797
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