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A bounding surface model for anisotropically overconsolidated clay incorporating thermodynamics admissible rotational hardening rule
Author(s) -
Chen Yanni,
Yang Zhongxuan
Publication year - 2019
Publication title -
international journal for numerical and analytical methods in geomechanics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.419
H-Index - 91
eISSN - 1096-9853
pISSN - 0363-9061
DOI - 10.1002/nag.3032
Subject(s) - yield surface , anisotropy , hardening (computing) , consolidation (business) , critical state soil mechanics , geotechnical engineering , softening , mechanics , hydrostatic equilibrium , stress path , bounding overwatch , stress space , materials science , plasticity , constitutive equation , geology , thermodynamics , physics , composite material , computer science , finite element method , accounting , layer (electronics) , quantum mechanics , business , artificial intelligence
Summary A bounding surface model is formulated to simulate the behavior of clays that are subject to an anisotropic consolidation stress history. Conventional rotational hardening is revisited from the perspective of thermodynamics. As the free energy cannot be accumulated infinitely upon critical state failure, the deviatoric back stress must vanish. This requires the rotated yield surface to be turned back to eventually align on the hydrostatic axis in the stress plane. Noting that most of the previous propositions violate this restriction, an innovative rotational hardening rule is formulated that is thermodynamically admissible. The bounding surface framework that employs the modified yield surface is applied to simulate elastoplastic deformations for overconsolidated clays, with which the overprediction of strength on the “dry” side can be greatly improved with reasonable results. Other important features, including contractive or dilative response and hardening or softening behavior, can also be well‐captured. It has been shown that the model can simulate three types of reconstituted clays that are sheared with initial conditions over a wide range of anisotropic consolidation stress ratios and overconsolidation ratios under both triaxial undrained and drained conditions. Limitations and potential improvement of the model regarding the fabric anisotropy at critical state have been discussed.

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