International audienceA micro‐hydromechanical model for granular materials is presented. It combines the discrete element method for the modeling of the solid phase and a pore‐scale finite volume formulation for the flow of an incompressible pore fluid. The coupling equations are derived and contrasted against the equations of conventional poroelasticity. An analogy is found between the discrete element method pore‐scale finite volume coupling and Biot's theory in the limit case of incompressible phases. The simulation of an oedometer test validates the coupling scheme and demonstrates the ability of the model to capture strong poromechanical effects. A detailed analysis of microscale strain and stress confirms the analogy with poroelastici...
AbstractThe main purpose of this paper is the formulation of a modeling framework for closed-cell po...
Journal ArticleA detailed understanding of the coupling between fluid and solid mechanics is importa...
Les matériaux granulaires multiphasiques occupent une place très importante dans notre environnement...
International audienceA method is presented for the simulation of pore flow in granular materials. T...
A method is presented for the simulation of pore flow in granular materials. The numerical...
The behaviour of multiphase materials covers a wide range of phenomena of interest to both scientist...
Le comportement des matériaux multiphasiques couvre une multitude de phénomènes qui suscitent un gra...
We present a model for fluid-saturated granular media coupled flow and mechanical deformation. The flui...
Les situations où deux fluides non miscibles sont présents dans un matériau granulaire déformable so...
We propose a numerical model of liquid-saturated porous material, based on a coupled approach combin...
Multiphase granular materials occupy a very important place in our environment that are of great int...
A pore-scale model is presented for simulating two-phase flow in granular materials. The solid phase ...
This paper presents a coupled micro-mechanical technique to model pore water flow and solid phase de...
International audienceThe main purpose of this paper is the formulation of a modeling framework for ...
Abstract: A finite strain multiscale hydro-mechanical model is established via an extended Hill–Mand...
AbstractThe main purpose of this paper is the formulation of a modeling framework for closed-cell po...
Journal ArticleA detailed understanding of the coupling between fluid and solid mechanics is importa...
Les matériaux granulaires multiphasiques occupent une place très importante dans notre environnement...
International audienceA method is presented for the simulation of pore flow in granular materials. T...
A method is presented for the simulation of pore flow in granular materials. The numerical...
The behaviour of multiphase materials covers a wide range of phenomena of interest to both scientist...
Le comportement des matériaux multiphasiques couvre une multitude de phénomènes qui suscitent un gra...
We present a model for fluid-saturated granular media coupled flow and mechanical deformation. The flui...
Les situations où deux fluides non miscibles sont présents dans un matériau granulaire déformable so...
We propose a numerical model of liquid-saturated porous material, based on a coupled approach combin...
Multiphase granular materials occupy a very important place in our environment that are of great int...
A pore-scale model is presented for simulating two-phase flow in granular materials. The solid phase ...
This paper presents a coupled micro-mechanical technique to model pore water flow and solid phase de...
International audienceThe main purpose of this paper is the formulation of a modeling framework for ...
Abstract: A finite strain multiscale hydro-mechanical model is established via an extended Hill–Mand...
AbstractThe main purpose of this paper is the formulation of a modeling framework for closed-cell po...
Journal ArticleA detailed understanding of the coupling between fluid and solid mechanics is importa...
Les matériaux granulaires multiphasiques occupent une place très importante dans notre environnement...