A fully coupled porous flow and geomechanics model for fluid driven cracks: a peridynamics approach

TitleA fully coupled porous flow and geomechanics model for fluid driven cracks: a peridynamics approach
Publication TypeJournal Article
Year of Publication2015
AuthorsOuchi, H., A. Katiyar, J. York, J. T. Foster, and M. M. Sharma
JournalComputational Mechanics
Volume55
Issue3
Start Page561
Pagination561-576
Date Published03/2015
KeywordsHydraulic Fracturing, Peridynamics
Abstract

A state-based non-local peridynamic formulation is presented for simulating fluid driven fractures in an arbitrary heterogeneous poroelastic medium. A recently developed peridynamic formulation of porous flow has been coupled with the existing peridynamic formulation of solid and fracturemechanics resulting in a peridynamic model that for the first time simulates poroelasticity and fluid-driven fracture propagation. This coupling is achieved by modeling the role of pore pressure on the deformation of porous media and vice versa through porosity variationwith medium deformation, pore pressure and total mean stress. The poroelastic model is verified by simulating the one-dimensional consolidation of fluid saturated rock. An additional porous flow equation with material permeability dependent on fracture width is solved to simulate fluid flow in the fractured region. Finally, single fluid-driven fracture propagation with a twodimensional plane strain assumption is simulated and verified against the corresponding classical analytical solution.

DOI10.1007/s00466-015-1123-8