Numerical Investigation of Hydraulic Fracture Propagation in Naturally Fractured Reservoirs Based on Lattice Spring Model

Zhao, Kaikai; Jiang, Pengfei; Feng, Yanjun; Sun, Xiaodong; Cheng, Lixing; Zheng, Jianwei

doi:10.1155/2020/8845990

Cited by 5 publications

(3 citation statements)

References 48 publications

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“…In particular, for some wells exploiting the Verey deposits a fracture of the pressure recovery curve was established, which is interpreted according to the Warren-Root model [22,23] as an effect on the flow of fracturing fluids of rocks. Generalization of information on hydrodynamic studies at the reservoir shows that the natural crack opening is quite low and does not exceed 10 μm.…”

Section: Results Of Tomographic Core Studiesmentioning

confidence: 99%

Modeling of Crack Development Associated with Proppant Hydraulic Fracturing in a Clay-Carbonate Oil Deposit

Galkin¹,

Savitckii²,

Shustov³

et al. 2023

Fluid Dynamics &Amp; Materials Processing

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Survey and novel research data are used in the present study to classify/identify the lithological type of Verey age reservoirs' rocks. It is shown how the use of X-ray tomography can clarify the degree of heterogeneity, porosity and permeability of these rocks. These data are then used to elaborate a model of hydraulic fracturing. The resulting software can take into account the properties of proppant and breakdown fluid, thermal reservoir conditions, oil properties, well design data and even the filtration and elastic-mechanical properties of the rocks. Calculations of hydraulic fracturing crack formation are carried out and the results are compared with the data on hydraulic fracturing crack at standard conditions. Significant differences in crack formation in standard and lithotype models are determined. It is shown that the average width of the crack development for the lithotype model is 2.3 times higher than that for the standard model. Moreover, the coverage of crack development in height for the lithotype model is almost 2 times less than that for the standard model. The estimated fracture half-length for the lithotype model is 13.3% less than that of for the standard model. A higher dimensionless fracture conductivity is also obtained for the lithotype model. It is concluded that the proposed approach can increase the reliability of hydraulic fracturing crack models.

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Section: Results Of Tomographic Core Studiesmentioning

confidence: 99%

Modeling of Crack Development Associated with Proppant Hydraulic Fracturing in a Clay-Carbonate Oil Deposit

Galkin¹,

Savitckii²,

Shustov³

et al. 2023

Fluid Dynamics &Amp; Materials Processing

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show abstract

“…The length and maximum width of the primary fracture show a decreasing trend, while the fracture volume also shows a decreasing trend. The total volume of hydraulic fractures decreased with increasing tensile strength of natural fractures, because the volume of fractures within the coal matrix produced per unit energy is smaller than that of hydraulic fractures extending within the natural fractures [31][32][33][34][35].…”

Section: Parametric Analysis On Fracture Propagationmentioning

confidence: 96%

Experimental and Numerical Simulation Study of Hydraulic Fracture Propagation during Coalbed Methane Development

et al. 2021

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The extraction of low-permeability coalbed methane (CBM) has the dual significance of energy utilization and safe mining. Understanding hydraulic fracturing mechanism is vital to successful development of CBM. Therefore, it is important to improve the law of hydraulic fracture propagation in coal and rigorously study the influencing factors. In this paper, laboratory experiments and numerical simulation methods were used to investigate the hydraulic fracture propagation law of coal in coalbed methane reservoir with natural fractures. The results show that the maximum and minimum horizontal in situ stress and the difference in stress significantly affect the direction of crack propagation. The elastic modulus of coal, the mechanical properties of natural fractures, and the injection rate can affect the fracture length, fracture width, and the amount of fracturing fluid injected. To ensure the effectiveness of hydraulic fracturing, a reservoir environment with a certain horizontal stress difference under specific reservoir conditions can ensure the increase of fractured reservoir and the controllability of fracture expansion direction. In order to increase the volume of fractured reservoir and fracture length, the pumping speed of fracturing fluid should not be too high. The existence of stress shadow effect causes the hydraulic fracture to propagate along the main fracture track, where the branch fracture cannot extend too far. Complex fractures are the main hydraulic fracture typology in coalbed methane reservoir with natural fractures. The results can provide a benchmark for optimal design of hydraulic fracturing in coalbed methane reservoirs.

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“…To model the hydraulic fracture, Jiang et al [26] proposed finite volume methods to discretize the flow equation and solved solid medium with cracks by the presented dynamic XFEM. Considering the permeability enhancement in naturally fractured reservoirs, Zhao et al [27] built the lattice spring model to indicate the effect of various influence parameters in the hydraulic fracture propagation. The XFEM and time integration were coupled by Haghani et al [28] to study the dynamic fracture of a cracked concrete dam interacted with the foundation and the reservoir.…”

Section: Introductionmentioning

confidence: 99%

Evaluation Method for Cohesive Crack Propagation in Fragile Locations of RCC Dam Using XFEM

Zhao

2020

Water

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Roller compacted concrete (RCC) dams own a large number of horizontal construction layers, which can easily lead to weak joints among layers and generate interlayer joints with different scales to reduce the dam bearing capacity. In this study, extended finite element method (XFEM) is used to simulate crack propagation, the finite element description is first taken on the strong discontinuity. Subsequently, the displacement function of the crack-tip in the quadrilateral element and the geometric determination method of the crack-tip strengthening region are established. Afterwards, the discrete form of the governing equation is derived and the XFEM increment discretization method of the cohesive crack with the crack-tip reinforcement is proposed using the virtual node method to represent the discontinuity of the fracture element. These methods are validated through simulating mixed-mode cracking of one-sided notched asymmetric four-point bending beam. Eventually, the proposed methods are applied to RCC gravity dam to study the development rule and propagation path of the interlayer joints, so as to evaluate the effect of different lengths of the interlayer joints on the dam structural performance. The estimated critical values of dam deformation are helpful to prevent the dam failure during long term operation.

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Numerical Investigation of Hydraulic Fracture Propagation in Naturally Fractured Reservoirs Based on Lattice Spring Model

Cited by 5 publications

References 48 publications

Modeling of Crack Development Associated with Proppant Hydraulic Fracturing in a Clay-Carbonate Oil Deposit

Modeling of Crack Development Associated with Proppant Hydraulic Fracturing in a Clay-Carbonate Oil Deposit

Experimental and Numerical Simulation Study of Hydraulic Fracture Propagation during Coalbed Methane Development

Evaluation Method for Cohesive Crack Propagation in Fragile Locations of RCC Dam Using XFEM

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