A micromechanical-based constitutive model for fibrous fine-grained composite soils

A micromechanical-based constitutive model for fibrous fine-grained composite soils

Composite soils such as municipal solid wastes (MSWs), peats, and reinforced soils are generally composed of multiple phases with different properties. Numerical modeling of these soils which takes the individual constituents into account might be impractical as it requires great computational effor...

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Bibliographic Details
Published in:International journal of plasticity Vol. 89; pp. 150 - 172
Main Authors: Dejaloud, Hesam, Jafarian, Yaser
Format: Journal Article
Language:English
Published: New York Elsevier Ltd 01-02-2017
Elsevier BV
Subjects:
Clay
Constitutive model
Constitutive models
Fibers
Fine-grained fibrous soil
Fine-grained soils
Geotechnical engineering
Homogenization
Mathematical models
Micromechanics
Municipal solid waste
Numerical analysis
Phases
Reinforced soils
Slippage
Soil mechanics
Soils
Solid wastes
Stiffness
Strain concentration
Stress state
Studies
Triaxial compression tests
Volumetric analysis
Micromechanics
Homogenization
Constitutive model
Fine-grained fibrous soil
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Summary:Composite soils such as municipal solid wastes (MSWs), peats, and reinforced soils are generally composed of multiple phases with different properties. Numerical modeling of these soils which takes the individual constituents into account might be impractical as it requires great computational efforts. Hence, geotechnical practitioners may prefer to treat a representative material which accounts for the whole mechanical aspects of the composite soil. In the current study, a constitutive model has been developed which treats the fine-grained composite soils in two general phases: matrix (paste) and fiber. To represent the behavior of these phases, two distinct constitutive models are used: (1) an anisotropic critical state-based constitutive model for matrix phase and (2) a Von-Mises type model for fiber phase. In order to consider the composite soil as a single phase homogeneous material, a volumetric homogenization procedure is used based on the micromechanical theories. Accordingly, strain concentration tensor is developed which determines the equivalent stiffness tensor for the homogenized soil. Based on the hypotheses derived from the experimental observations, the basic model is gradually enhanced in order to account for some important aspects of composite matters including fibers orientation, fibers discontinuity, and slippage-mobilization of fibers within the matrix phase. The effect of these aspects on the overall response of soil under monotonic loading is studied. Reasonable performance of the proposed model is demonstrated by the results of triaxial compression tests on reinforced clay with nylon and palm fibers. •A hybrid constitutive model for fibrous fine-grained soil is developed.•Constitutive models of matrix and fibers are critical state and Von-Mises types.•A volumetric homogenization procedure is used based on micromechanical theories.•The model is applicable for clays with discontinuous randomly oriented fibers.•Verification of the model is demonstrated by compression triaxial tests results.
ISSN:0749-6419
1879-2154
DOI:10.1016/j.ijplas.2016.11.008