Mathematical modelling and numerical solution of swelling of cartilaginous tissues. part i: modelling of incompressible charged porous media ∗
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In this paper, the swelling and shrinkage of biological tissues are modelled by a four-component mixture theory in which a deformable and charged porous medium is saturated with a fluid with dissolved ions.Abstract:
The swelling and shrinkage of biological tissues are modelled by a four-component mixture theory in which a deformable and charged porous medium is saturated with a fluid with dissolved ions Four components are defined: solid, liquid, cations and anions The aim of this paper is the construction of the Lagrangian model of the four-component system It is shown that, with the choice of Lagrangian description of the solid skeleton, the motion of the other components can be described in terms of Lagrangian initial system of the solid skeleton as well Such an approach has a particularly important bearing on computer-aided calculations Balance laws are derived for each component and for the whole mixture In cooperation of the second law of thermodynamics, the constitutive equations are given This theory results in a coupled system of nonlinear parabolic differential equations together with an algebraic constraint for electroneutrality In this model, it is desirable to obtain an accurate approximation of the fluid flow and ions flow Such an accurate approximation can be determined by the mixed finite element method Part II is devoted to this taskread more
Citations
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The Effects of Swelling and Porosity Change on Capillarity: DEM Coupled with a Pore-Unit Assembly Method
TL;DR: A formula for the Van Genuchten parameter $$\alpha $$α (which is related to the inverse of the entry pressure) as a function of porosity and the amount of absorbed water is developed.
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A large deformation formulation for fluid flow in a progressively fracturing porous material
TL;DR: In this article, a general numerical model has been developed for fluid flow in a progressively fracturing porous medium subject to large deformations, where the nucleation and the opening of micro-cracks are modelled by a traction-separation relation.
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Grain-scale modelling of swelling granular materials; application to super absorbent polymers
TL;DR: In this article, a grain-scale model based on a combination of the discrete element method (DEM) and the Pore Finite Volume (PFV) method was developed to account for the swelling of individual super absorbent polymers.
Journal ArticleDOI
Mathematical modelling and numerical solution of swelling of cartilaginous tissues. Part II: Mixed-hybrid finite element solution
TL;DR: In this article, the swelling and shrinkage of biological tissues are modelled by a four-component mixture theory, which results in a coupled system of nonlinear parabolic differential equations together with an algebraic constraint for electroneutrality.
Journal ArticleDOI
General coupling extended multiscale FEM for elasto‐plastic consolidation analysis of heterogeneous saturated porous media
TL;DR: Numerical results show that the newly developed GCEMs can almost preserve the same convergent property as the standard FEM and also possesses the advantages of high computational efficiency.
References
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Book ChapterDOI
The Thermodynamics of Elastic Materials with Heat Conduction and Viscosity
TL;DR: The basic physical concepts of classical continuum mechanics are body, configuration of a body, and force system acting on a body as mentioned in this paper, which can be expressed as follows: a body is regarded as a smooth manifold whose elements are the material points; a configuration is defined as a mapping of the body into a three-dimensional Euclidean space, and a force system is defined to be a vector-valued function defined for pairs of bodies.
Journal ArticleDOI
A triphasic theory for the swelling and deformation behaviors of articular cartilage.
W. M. Lai,J. S. Hou,Van C. Mow +2 more
TL;DR: The results show that all three mechanisms are important in determining the overall compressive stiffness of cartilage.
Journal ArticleDOI
Incompressible porous media models by use of the theory of mixtures
TL;DR: In this paper, the use of the thermodynamics of mixtures to formulate incompressible porous media models is discussed. But the model is restricted to the case where the mixture is a mixture where the solid and the fluid constituents are each incompressibly.