Experiments versus theory for the initiation and propagation of radial hydraulic fractures in low‐permeability materials

Lecampion, Brice; Desroches, J.; Jeffrey, Robert G.; Bunger, Andrew P.

doi:10.1002/2016jb013183

Cited by 81 publications

(75 citation statements)

References 49 publications

(82 reference statements)

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“…Each of these studies found a linear increase in breakdown pressure with confining pressure, and rapid, uncontrolled breakdown once the peak injection pressure was reached. Zoback et al (1977), Bunger and Detournay (2008), Stanchits et al (2015), and Lecampion et al (2017) found that for experiments injecting higher-viscosity fluids, the breakdown pressure can be higher than the fracture initiation pressure, in agreement with the models summarized by Detournay (2016).…”

Section: Laboratory-scale Fluid Injection Experimentssupporting

confidence: 62%

Fluid Injection Experiments in Shale at Elevated Confining Pressures: Determination of Flaw Sizes From Mechanical Experiments

et al. 2019

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Triaxial experiments and direct fluid injection experiments have been conducted at confining pressures up to 100 MPa on Mancos shale, Whitby mudstone, Penrhyn slate, and Pennant sandstone. Experiments were conducted with sample axes lying both parallel and perpendicular to layering in the materials. During triaxial failure Penrhyn slate was stronger for samples with cleavage parallel to maximum principal stress, but the two orientations in the shales displayed similar failure stresses. Initial flaw sizes of around 40 μm were calculated from the triaxial data using the wing crack model, with the shales having shorter initial flaws than the nonshales. During direct fluid injection, breakdown was rapid, with no discernible gap between fracture initiation and breakdown. Breakdown pressure increased linearly with confining pressure but was less sensitive to confining pressure than expected from existing models. A fracture mechanics‐based model is proposed to determine the initial flaw size responsible for breakdown in injection experiments. Flaw sizes determined in this way agree reasonably with those determined from the triaxial data in the nonshales at low confining pressures. As confining pressure rises, a threshold is reached, above which the fluid injection experiments suggest a lower initial flaw length of around 10 μm. This threshold is interpreted as being due to the partial closure of flaws. In the shales an initial flaw length of around 10 μm was determined at all confining pressures, agreeing reasonably with those determined through the triaxial experiments.

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Section: Laboratory-scale Fluid Injection Experimentssupporting

confidence: 62%

Fluid Injection Experiments in Shale at Elevated Confining Pressures: Determination of Flaw Sizes From Mechanical Experiments

et al. 2019

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“…It is also important to note that the compressibility of gas or supercritical CO 2 may effect early‐time crack propagation. However, for the intermediate/long time, compressibility is expected to have a negligible impact on the solution …”

Section: Resultsmentioning

confidence: 99%

“…However, for the intermediate/long time, compressibility is expected to have a negligible impact on the solution. 52 The first comparison between laminar and turbulent flows is for the normalized opening. Figure 5 illustrates that the difference between normalized opening along the crack is relatively subtle; the scaled turbulent crack width is just slightly narrower.…”

Section: Comparison Between Turbulent and Laminar Solutionsmentioning

confidence: 99%

Solution for a plane strain rough‐walled hydraulic fracture driven by turbulent fluid through impermeable rock

Zolfaghari

Dontsov

Bunger

2017

Num Anal Meth Geomechanics

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Summary The impact of turbulent flow on plane strain fluid‐driven crack propagation is an important but still poorly understood consideration in hydraulic fracture modeling. The changes that hydraulic fracturing has experienced over the past decade, especially in the area of fracturing fluids, have played a major role in the transition of the typical fluid regime from laminar to turbulent flow. Motivated by the increasing preponderance of high‐rate, water‐driven hydraulic fractures with high Reynolds number, we present a semianalytical solution for the propagation of a plane strain hydraulic fracture driven by a turbulent fluid in an impermeable formation. The formulation uses a power law relationship between the Darcy‐Weisbach friction factor and the scale of the fracture roughness, where one specific manifestation of this generalized friction factor is the classical Gauckler‐Manning‐Strickler approximation for turbulent flow in a rough‐walled channel. Conservation of mass, elasticity, and crack propagation are also solved simultaneously. We obtain a semianalytical solution using an orthogonal polynomial series. An approximate closed‐form solution is enabled by a choice of orthogonal polynomials embedding the near‐tip asymptotic behavior and thus giving very rapid convergence; a precise solution is obtained with 2 terms of the series. By comparison with numerical simulations, we show that the transition region between the laminar and turbulent regimes can be relatively small so that full solutions can often be well approximated by either a fully laminar or fully turbulent solution.

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“…Different confining stresses are applied in three layers with the upper layer having a larger confining stress layer of 11 MPa, the lower layer having a confining stress of 5 MPa, and the layer in the middle (of 50 mm height) that contains the injection point having a confining stress of 7 MPa (see Figure ). The others parameters are as follows:

E^{'} = 3.9 \times 1 0^{10} Pa, K_{I c} = 0, C_{L} = 0, μ = 30 Pa \cdot s, Q_{o} = 0.0023 mL/s .

Due to a rather large injection line, the effective injection rate entering the fracture varies with time due to fluid compressibility effects during the initial pressurization phase (see Lecampion et al for discussion). The evolution of the injection rate into the fracture can be approximated here by three constant injection steps: 0.0009 mL/s for the first 31 seconds, 0.0065 mL/s for the next 120 seconds, and 0.0023 mL/s for the rest of the experiment.…”

Section: Verification and Test Casesmentioning

confidence: 99%

Explicit versus implicit front advancing schemes for the simulation of hydraulic fracture growth

Zia

Lecampion

2019

Num Anal Meth Geomechanics

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Summary The proper computation of the time evolution of the fracture front is the main challenge of three‐dimensional (3D) hydraulic fracture growth simulation. We discuss explicit and implicit variants of a hydraulic fracture propagation scheme based on a level set representation of the fracture. Such a scheme couples a finite discretization of the governing equations and the near‐tip hydraulic fracture asymptotes. We benchmark the accuracy, robustness, and stability of these different front advancing schemes on a number of test cases. Our results indicate a large computational gain of the explicit scheme at the expense of a slightly less accurate solution (few percent less accuracy over few time steps) when crossing heterogeneities. The predictor corrector scheme combines at least an approximately 25% computational gain while retaining the stability and accuracy of the fully implicit version of the scheme in all cases.

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Experiments versus theory for the initiation and propagation of radial hydraulic fractures in low‐permeability materials

Cited by 81 publications

References 49 publications

Fluid Injection Experiments in Shale at Elevated Confining Pressures: Determination of Flaw Sizes From Mechanical Experiments

Fluid Injection Experiments in Shale at Elevated Confining Pressures: Determination of Flaw Sizes From Mechanical Experiments

Solution for a plane strain rough‐walled hydraulic fracture driven by turbulent fluid through impermeable rock

Explicit versus implicit front advancing schemes for the simulation of hydraulic fracture growth

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