Comparison of Discrete-Fracture and Dual-Permeability Models for Multiphase Flow in Naturally Fractured Reservoirs

Moinfar, Ali; Narr, Wayne; Hui, Mun-Hong; Mallison, Bradley T.; Lee, Seong Hee

doi:10.2118/142295-ms

Cited by 101 publications

(67 citation statements)

References 20 publications

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“…EDFM (Lee et al, 2001;Li and Lee, 2008;Moinfar et al, 2011Moinfar et al, , 2014, in which fractures are modeled as quadrilateral plates inserted into the structured matrix grid. EDFM captures the geometric details of fractures and meanwhile preserves the structured grid as background.…”

Section: Fracture Modelsmentioning

confidence: 99%

A multi-continuum multiple flow mechanism simulator for unconventional oil and gas recovery

Zhang

2015

Journal of Natural Gas Science and Engineering

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Section: Fracture Modelsmentioning

confidence: 99%

A multi-continuum multiple flow mechanism simulator for unconventional oil and gas recovery

Zhang

2015

Journal of Natural Gas Science and Engineering

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“…The large number of grids is required even if the aperture of the fracture is the smallest mesh scale. Another problem caused by the scale difference is the instability and divergence [12]. Although the equivalent seepage resistance method [13], which enlarges the aperture and reduces the permeability under the conditions of the same fracture flux and can be used, it is limited by the formation coefficient, fracture permeability and many other factors.…”

Section: Introductionmentioning

confidence: 99%

A numerical approach for pressure transient analysis of a vertical well with complex fractures

Wan

Liu

et al. 2016

Acta Mech. Sin.

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A new well test model for a vertical fractured well is developed based on a discrete-fracture model in which the fractures are discretized as one dimensional (1-D) entities. The model overcomes the weakness of complex meshing, a large number of grids, and instability in conventional stripe-fracture models. Then, the discrete-fracture model is implemented using a hybrid element finite-element method. Triangular elements are used for matrix and line elements for the fractures. The finite element formulation is validated by comparing with the semi-analytical solution of a single vertical fractured well. The accuracy of the approach is shown through several examples with different fracture apertures, fracture conductivity, and fracture amount. Results from the discrete-fracture model agree reasonably well with the stripefracture model and the analytic solutions. The advantages of the discrete-fracture model are presented in mesh generation, computational improvement, and abilities to handle complex fractures like wedge-shaped fractures and fractures with branches. Analytical results show that the number of grids in the discrete-fracture model is 10 % less than stripefracture model, and computational efficiency increases by about 50 %. The more fractures there are, the more the computational efficiency increases.

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“…There exist several methods to simulate fluid flow in fractured porous media [6]. Warren and Root introduced the dual continuum concept to characterize naturally fractured reservoirs [7].…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation of Fluid-Solid Coupling in Fractured Porous Media with Discrete Fracture Model and Extended Finite Element Method

Zeng

Yao

2015

Computation

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Fluid-solid coupling is ubiquitous in the process of fluid flow underground and has a significant influence on the development of oil and gas reservoirs. To investigate these phenomena, the coupled mathematical model of solid deformation and fluid flow in fractured porous media is established. In this study, the discrete fracture model (DFM) is applied to capture fluid flow in the fractured porous media, which represents fractures explicitly and avoids calculating shape factor for cross flow. In addition, the extended finite element method (XFEM) is applied to capture solid deformation due to the discontinuity caused by fractures. More importantly, this model captures the change of fractures aperture during the simulation, and then adjusts fluid flow in the fractures. The final linear equation set is derived and solved for a 2D plane strain problem. Results show that the combination of discrete fracture model and extended finite element method is suited for simulating coupled deformation and fluid flow in fractured porous media.

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Comparison of Discrete-Fracture and Dual-Permeability Models for Multiphase Flow in Naturally Fractured Reservoirs

Cited by 101 publications

References 20 publications

A multi-continuum multiple flow mechanism simulator for unconventional oil and gas recovery

A multi-continuum multiple flow mechanism simulator for unconventional oil and gas recovery

A numerical approach for pressure transient analysis of a vertical well with complex fractures

Numerical Simulation of Fluid-Solid Coupling in Fractured Porous Media with Discrete Fracture Model and Extended Finite Element Method

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