A finite element approach to the simulation of hydraulic fractures with lag

Hunsweck, Michael J.; Shen, Yongxing; Lew, Adrián J.

doi:10.1002/nag.1131

Cited by 94 publications

(69 citation statements)

References 40 publications

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“…Note that linear elastic fracture mechanics model also simplifies when the fracture path is predetermined, reducing the complexity of finding the fracture front within a priori known planes (Hunsweck et al, 2013;Golovin et al, 2015).…”

Section: Growth Along a Pre-defined Pathmentioning

confidence: 99%

Numerical methods for hydraulic fracture propagation: A review of recent trends

Lecampion

Bunger

Zhang

2018

Journal of Natural Gas Science and Engineering

333

172

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Section: Growth Along a Pre-defined Pathmentioning

confidence: 99%

Numerical methods for hydraulic fracture propagation: A review of recent trends

Lecampion

Bunger

Zhang

2018

Journal of Natural Gas Science and Engineering

333

172

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“…The boundary condition of zero displacement at infinity is approximated by a finite body and standard finite elements and a local mesh refinement in the area close to the crack interface. Computational evidence of the validity of approximating the infinite medium with a finite block is provided in [13]. The results are scaled to dimensionless quantities in the viscosity scaling.…”

Section: Numerical Resultsmentioning

confidence: 99%

“…The results are scaled to dimensionless quantities in the viscosity scaling. For a detailed description of the scaling for the pressure Π, the opening Ω and the crack length γ see the original publication [13]. The domain and the explicit interface are meshed independently with 5000 and 3000 elements, respectively.…”

Section: Numerical Resultsmentioning

confidence: 99%

The XFEM with an Explicit-Implicit Crack Description for Hydraulic Fracture Problems

Weber¹,

Siebert²,

Willbrand³

et al. 2013

Effective and Sustainable Hydraulic Fracturing

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The Extended Finite Element Method (XFEM) approach is applied to the coupled problem of fluid flow, solid deformation, and fracture propagation. The XFEM model description of hydraulic fracture propagation is part of a joint project in which the developed numerical model will be verified against large-scale laboratory experiments. XFEM forms an important basis towards future combination with heat and mass transport simulators and extension to more complex fracture systems. The crack is described implicitly using three level-sets to evaluate enrichment functions. Additionally, an explicit crack representation is used to update the crack during propagation. The level-set functions are computed exactly from the explicit representation. This explicit/implicit representation is applied to a fluid-filled crack in an impermeable, elastic solid and compared to the early-time solution of a plane-strain hydraulic fracture problem with a fluid lag.

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“…Previous work has been done in the area of developing models that apply adaptive grid refinement as fractures propagate [12,33]. This requires a significant level of computational overhead, and the numerical results have been observed to be grid-dependent.…”

Section: Embedded Fracture Model Descriptionmentioning

confidence: 99%

An embedded fracture modeling framework for simulation of hydraulic fracturing and shear stimulation

Norbeck

McClure

et al. 2015

Comput Geosci

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A numerical modeling framework is described that is able to calculate the coupled processes of fluid flow, geomechanics, and rock failure for application to general engineering problems related to reservoir stimulation, including hydraulic fracturing and shear stimulation. The numerical formulation employs the use of an embedded fracture modeling approach, which provides several advantages over more traditional methods in terms of computational complexity and efficiency. Specifically, the embedded fracture modeling strategy avoids the usual requirement that the discretization of the fracture domain conforms to the discretization of the rock volume surrounding the fractures. As fluid is exchanged between the two domains, conservation of mass is guaranteed through a coupling term that appears as a simple source term in the governing mass balance equations. In this manner, as new tensile fractures nucleate and propagate subject to mechanical effects, numerical complexities associated with the introduction of new fracture control volumes are largely negated. In addition, the ability to discretize the fractures and surrounding rock volume independently provides the freedom to choose an acceptable level of discretization for each domain separately. Three numerical examples were performed to demonstrate the utility of the embedded fracture model for application to problems involving fluid flow, mechanical deformation, and rock failure. The results of the numerical examples confirm that the embedded fracture model was able to capture accurately the complex and nonlinear evolution of reservoir permeability as new fractures propagate through the reservoir and as fractures fail in shear.

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A finite element approach to the simulation of hydraulic fractures with lag

Cited by 94 publications

References 40 publications

Numerical methods for hydraulic fracture propagation: A review of recent trends

Numerical methods for hydraulic fracture propagation: A review of recent trends

The XFEM with an Explicit-Implicit Crack Description for Hydraulic Fracture Problems

An embedded fracture modeling framework for simulation of hydraulic fracturing and shear stimulation

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