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

Lecampion, Brice; Bunger, Andrew P.; Zhang, Xi

doi:10.1016/j.jngse.2017.10.012

Cited by 350 publications

(196 citation statements)

References 208 publications

(227 reference statements)

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“…Mass conservation is a difficult issue when using mesh adaptivity as stated in Lecampion et al, and therefore, it was verified for the examples presented in this manuscript. The biggest errors at a propagation step are 0.06 % for the penny‐shaped problem, 0.08 % for the planar elliptical problem, and 0.009 % for the leak‐off verification problem.…”

Section: Discussionsupporting

confidence: 65%

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Improved algorithms for generalized finite element simulations of three‐dimensional hydraulic fracture propagation

Shauer

Duarte

2019

Num Anal Meth Geomechanics

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Summary This paper reports improvements to algorithms for the simulation of 3‐D hydraulic fracturing with the Generalized Finite Element Method (GFEM). Three optimizations are presented and analyzed. First, an improved initial guess based on solving a 3‐D elastic problem with the pressure from the previous step is shown to decrease the number of Newton iterations and increase robustness. Second, an improved methodology to find the time step that leads to fracture propagation is proposed and shown to decrease significantly the number of iterations. Third, reduced computational cost is observed by properly recycling the linear part of the coupled stiffness matrix. Two representative examples are used to analyze these improvements. Additionally, a methodology to include the leak‐off term is presented and verified against asymptotic analytical solutions. Conservation of mass is shown to be well satisfied in all examples.

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Section: Discussionsupporting

confidence: 65%

“…These schemes produce very accurate solutions even for coarse meshes. However, it is still unclear how to extend the algorithm to nonplanar 3‐D fractures with mixed mode loading …”

Section: Introductionmentioning

confidence: 99%

Improved algorithms for generalized finite element simulations of three‐dimensional hydraulic fracture propagation

Shauer

Duarte

2019

Num Anal Meth Geomechanics

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“…Additionally, it is important to note that the leak‐off coefficient C L is coupled with the fluid viscosity, that is, higher viscosity leads to lower leak‐off. Neglecting any accumulation of particulate/polymer on the fracture comprising a low‐permeability “filter cake,” and further assuming that the fluid injected to the fracture is not too dissimilar in viscosity to the native fluid in the reservoir, the viscosity and leak‐off rate are coupled via Carter's leak‐off parameter (Carter, ; Lecampion et al, ).

C_{L} = \sqrt{\frac{k c_{r} ϕ}{italicπμ}} p_{∆}, p_{∆} = σ_{o} - p_{o}

where k is the rock permeability, c r is the reservoir compressibility, combining the reservoir fluid and pore compressibility, ϕ is the rock porosity, σ o is the in situ stress, and p o is the reservoir pressure.…”

Section: Resultsmentioning

confidence: 99%

“…As an illustrative example, we show that injection volume can vary significantly depending upon both the nominal regime (location in the plots in Figure as defined by Φ and τ in equations and , respectively) and the fracture spacing. Specifically, we contrast uniformly spaced and a particular nonuniform spacing, which is inspired from prior work (Cheng & Bunger, ; Cheng & Bunger, , b; Lecampion et al, ), demonstrating that some nonuniform spacing configurations can balance the impact of stress shadow acting on the fractures, thereby leading to more uniform fracture growth. This parametric study entails varying viscosity and characteristic leak‐off parameter C L 0 , keeping all other quantities unchanged with practically relevant values given by

R_{W} = 0.2 normalm, K_{IC} = 1 MPa \cdot m^{\frac{1}{2}}, E = 10 GPa, ν = 0.2, σ_{o} = 70 MPa, Q_{o} = 0.2 m^{3} / normals, A_{T O T} = 100, 000 m^{2}, normalZ = 50 normalm

until a fracture surface area of 100,000 m 2 is achieved.…”

Section: Resultsmentioning

confidence: 99%

“…To summarize, the model requires simultaneous solution of 6 N equations corresponding to the following physical laws: Volume balance , where in our ROM we adopt a weak form wherein volume balance is assured globally but not at every location. Additionally, volume balance must account for fluid loss to the formation and here we follow the widely used Carter's method to describe the history‐dependent leak‐off under the assumptions that the hydraulic fracture velocity greatly exceeds the characteristic fluid diffusion velocity in the rock and that the transient fluid net pressure (difference between fluid pressure and in situ stress in the rock) is much smaller than the difference between the in situ stress and the undisturbed pore pressure in the reservoir rock (Carter, ; Lecampion et al, ). Laminar fluid flow describing a Newtonian fluid flowing within the fracture according to the classical Poiseuille law. In our ROM we avoid discretization by assuming a functional form that is consistent with known inlet and tip asymptotic behavior, which are the two locations where energy is predominantly dissipated. Crack propagation imposing a condition for crack extension according to linear elastic fracture mechanics.…”

Section: Methodsmentioning

confidence: 99%

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Model‐Based Evaluation of Methods for Maximizing Efficiency and Effectiveness of Hydraulic Fracture Stimulation of Horizontal Wells

Cheng

Bunger

2019

Geophysical Research Letters

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Hydraulic fracturing enables oil and gas extraction from low‐permeability reservoirs, but there remains a need to reduce the environmental footprint. Resource use, contaminant‐bearing flowback water, and potential for induced seismicity are all scaled by the volume of injected fluid. Furthermore, the greenhouse gas emissions associated with each extracted unit of energy can be decreased by improving resource recovery. To minimize fluid use while maximizing recovery, a rapidly computing model is developed and validated to enable the thousands of simulations needed to identify opportunities for optimization. Lower pumping pressure approaches that minimize pressure loss through the wellbore perforations combined with nonuniform spacing are shown to be capable of substantially reducing fluid consumption and/or increasing created fracture surface area when the stress variation is mainly from fracture interaction instead of in situ stress. When in situ stress variation is dominant, “limited entry” methods promote more uniform growth but with higher pumping pressures and energy consumption.

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Optimizing fluid viscosity for systems of multiple hydraulic fractures

Cheng

Bunger

2019

AIChE Journal

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Optimal hydraulic fracturing stimulations of horizontal oil and gas wells maximize created fracture surface area and/or maximize the uniformity of stimulation. Here, we use a new, rapidly‐computing hydraulic fracture model to investigate how surface area and uniformity are impacted by interplay among multiple growing hydraulic fractures driven through permeable rocks by fluids of various viscosities. The results show the existence of a surface‐area‐optimizing viscosity that is large enough to control leak‐off but not so large that leads to unnecessarily large fracture aperture.

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

Cited by 350 publications

References 208 publications

Improved algorithms for generalized finite element simulations of three‐dimensional hydraulic fracture propagation

Improved algorithms for generalized finite element simulations of three‐dimensional hydraulic fracture propagation

Model‐Based Evaluation of Methods for Maximizing Efficiency and Effectiveness of Hydraulic Fracture Stimulation of Horizontal Wells

Optimizing fluid viscosity for systems of multiple hydraulic fractures

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