Development of hydraulic fracture zone in heterogeneous material based on smeared crack method

This paper presents a hydraulic fracture model based on a fully coupled, pore pressure-effective stress formulation. The stress-strain behavior of the solid phase is modeled using an elasto-plastic, Mohr-Coulomb description. Hydraulic conductivity is related to the difference between mean effective stress and tensile strength via a hyperbolic tangent function that takes into account the relative permeability using the Corey correlation. The effect of the damage coefficient ξ on fracture propagation is studied via the hyperbolic function and the sensitivity of the solution to the aspect ratio of the elements is checked. Three types of material distributions are considered: homogeneous domain in which the material properties are constant; heterogeneous domain where multi-layered materials with strong and weak layers are included; and multi-layered material in which the values of the material properties for each layer are randomly generated using a PYTHON script. The propagation mechanisms and fracture features are discussed. Finally the propagation process, the extent of the fracture zone and pore pressure changes from a series of numerical simulations using ABAQUS are presented.