An Enhanced Bounding Surface Model for Modelling Various Cyclic Behaviour of Clay

An Enhanced Bounding Surface Model for Modelling Various Cyclic Behaviour of Clay

Many results from cyclic triaxial experiments indicate that porous media, such as clays, exhibit various long-term behaviours under different cyclic stress ratios (CSRs). These can be classified into three main categories, namely, cyclic shakedown, cyclic stable and cyclic failure. Modelling these s...

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Bibliographic Details
Published in:Materials Vol. 15; no. 21; p. 7609
Main Authors: Wang, Junxiang, Xotta, Giovanna, De Marchi, Nico, Salomoni, Valentina
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 29-10-2022
MDPI
Subjects:
Analysis
Behavior
Boundary layer
Bounding surface
bounding surface plasticity
Clay
clays
cyclic loading
damage factor
Deformation
Degradation
hardening modulus
Hysteresis loops
Interpolation
Kinematics
Load
Modelling
Ocean waves
Pore water pressure
Porous media
Shear strain
Shear strength
Shear stress
hysteresis loops
cyclic loading
damage factor
hardening modulus
bounding surface plasticity
clays
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Summary:Many results from cyclic triaxial experiments indicate that porous media, such as clays, exhibit various long-term behaviours under different cyclic stress ratios (CSRs). These can be classified into three main categories, namely, cyclic shakedown, cyclic stable and cyclic failure. Modelling these soil deformation responses, along with pore pressure and other fundamental cyclic aspects, such as closed hysteresis cycles and degradation, is still an open challenge, and research to date is limited. In order to properly describe and capture these characteristics, an enhanced plasticity model, based on the bounding surface and stress distance concepts, is developed here. In detail, a new uniform interpolation function of the plastic modulus, suitable for all loading stages, is proposed, and a new damage factor associated with the plastic shear strain and the deformation type parameter, is also incorporated into the plastic modulus. Accordingly, cyclic shakedown and cyclic failure can be distinguished, and degradation is achieved. Closed hysteresis loops, typical of clays, are obtained through a radial mapping rule along with a moving projection centre, located by the stress reversal points. Comparisons between the obtained numerical results and the experimental ones from literature confirm the suitability of the constitutive approach, which is capable of correctly capturing and reproducing the key aspects of clays’ cyclic behaviour.
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ISSN:1996-1944
1996-1944
DOI:10.3390/ma15217609