A Discrete Fracture Network Model for Hydraulically Induced Fractures - Theory, Parametric and Case Studies

Meyer, Bruce R.; Bazan, Lucas W.

doi:10.2118/140514-ms

Cited by 226 publications

(117 citation statements)

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“…Weng et al, 2011a;Meyer and Bazan, 2011). When the fracture height growth is involved during the fracture network formation, the stacked cell model consisting of many rows of elements in the vertical direction was proposed by Cohen et al (2015).…”

Section: Engineering Modelsmentioning

confidence: 99%

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

Lecampion

Bunger

Zhang

2018

Journal of Natural Gas Science and Engineering

335

172

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Section: Engineering Modelsmentioning

confidence: 99%

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

Lecampion

Bunger

Zhang

2018

Journal of Natural Gas Science and Engineering

335

172

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“…There are two primary models. One is the wire mesh model (Xu and Ghassemi 2009;Xu et al 2010;Meyer and Bazan 2011), which can effectively simulate the complexity of fractures and the spacing between perpendicular fractures; another one is the unconventional fracture model , which describes complex geological conditions and evaluates the propagation of complex fractures more strictly. However, the extended finite element and boundary element method may not apply various hydraulic pressures on the fracture surface, and also does not consider the impact of seepage and leak off of fracturing fluids; the discrete element method restricts the path of hydraulic fractures.…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation of hydraulic fracture propagation in tight oil reservoirs by volumetric fracturing

et al. 2015

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Volumetric fracturing is a primary stimulation technology for economical and effective exploitation of tight oil reservoirs. The main mechanism is to connect natural fractures to generate a fracture network system which can enhance the stimulated reservoir volume. By using the combined finite and discrete element method, a model was built to describe hydraulic fracture propagation in tight oil reservoirs. Considering the effect of horizontal stress difference, number and spacing of perforation clusters, injection rate, and the density of natural fractures on fracture propagation, we used this model to simulate the fracture propagation in a tight formation of a certain oilfield. Simulation results show that when the horizontal stress difference is lower than 5 MPa, it is beneficial to form a complex fracture network system. If the horizontal stress difference is higher than 6 MPa, it is easy to form a planar fracture system; with high horizontal stress difference, increasing the number of perforation clusters is beneficial to open and connect more natural fractures, and to improve the complexity of fracture network and the stimulated reservoir volume (SRV). As the injection rate increases, the effect of volumetric fracturing may be improved; the density of natural fractures may only have a great influence on the effect of volume stimulation in a low horizontal stress difference.

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“…(1). According to the theory of Sneddon and Elliot, stress induced by long fracture in home-generous elastic solid can be calculated as follows [19,20].…”

Section: Calculation Of Induced Stressmentioning

confidence: 99%

Study of Cyclic Fracturing in Vertical CBM Wells

Li¹,

Wan²

2017

TOPEJ

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Background:Coal-bed methane productivity of single well is very low, and has been the bottleneck of the coal-bed methane industry in China. Objective:Although hydraulic fracturing is the only stimulation measure to develop CBM, it cannot increase production effectively, conventional fracturing method to create opening fractures should be improved. How to make good use of natural fractures, which are plentiful in CBM reservoirs, is also an important subject for hydraulic fracturing. Method:In this paper, the plastic deformation of coal rock is analyzed by harnessing a pseudo-Maxwell creep phenomenon, which is normally present in rock. The Kelvin-Voigt model is utilized to describe pseudo-plastic behavior of coal rock to determine pressurization and decay cyclic time for cyclic fracturing design. The mechanical requirement for shearing natural fractures is also analyzed, and shearing distance between the faces of natural fracture can be calculated by Westergaard stress function. Ultimately, the cyclic fracturing method is proposed according to theories about stress alteration and shearing of natural fractures. This method includes such periods as fracturing, pumping shut-down and so on. Conclusion:A complex fracture system can be created, which consists of opened and sheared fractures, then, large SRV(stimulated reservoir volume)and flowing drainage area can be acquired. In comparison with conventional fracturing method, this new way can make full use of the characteristics of CBM reservoirs and is more suitable to CBM. This method will lead to a significant increase of CBM production, and will achieve huge economic benefits.

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A Discrete Fracture Network Model for Hydraulically Induced Fractures - Theory, Parametric and Case Studies

Cited by 226 publications

References 0 publications

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

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

Numerical simulation of hydraulic fracture propagation in tight oil reservoirs by volumetric fracturing

Study of Cyclic Fracturing in Vertical CBM Wells

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