Numerical Simulation of the Influence of Natural Fractures on Hydraulic Fracture Propagation

Song, Yaobin; Lu, Weiyong; He, Changchun; Bai, Erhu

doi:10.1155/2020/8878548

Cited by 11 publications

(7 citation statements)

References 35 publications

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“…When the elastic modulus increased from 2.6 GPa to 4.6 GPa, the maximum fracture width of the main fracture decreased by about 37.0%, the fracturing fluid injection volume 8 Geofluids decreased by about 23.9%, the main fracture length increased by 13.5%, and the fracture pressure increased by 34.5%. This is because the increase of the elastic modulus of the matrix makes the fluid carry more energy into the fracture [30].…”

Section: Parametric Analysis On Fracture Propagationmentioning

confidence: 99%

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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Section: Parametric Analysis On Fracture Propagationmentioning

confidence: 99%

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

et al. 2021

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“…It is assumed that the leakage point of the LNG pipeline is located at the air inlet end of the tunnel (the other end of the tunnel is the exhaust outlet); the fractures in the LNG pipeline are considered as three different diameters of 100 mm, 50 mm, and 10 mm (recorded as Case 3, Case 2, and Case 1) [15,16]. The tunnel space is meshed with unstructured grids (Figure 5), and numerical simulation is performed with the k-ε turbulence model and SIMPLE algorithm [17].…”

Section: Geometric Modelmentioning

confidence: 99%

Numerical Simulation and Analysis of Diffusion Process for the Leakages of a Tunnel LNG Pipeline

et al. 2020

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Taking a practical project as an example, based on the computational fluid dynamics (CFD), standard k-ε model and finite element method, a mathematical model for the diffusion due to liquefied natural gas (LNG) pipeline leakage in a tunnel was established, and the diffusion process was numerically simulated for three LNG leakage cases. From the simulation results, the variation of CH4 concentration field and explosive gas cloud with time within the tunnel, and the influence of leakage location on the diffusion was analyzed for the three cases. It was shown that the variation of CH4 concentration field had a similar trend for the three cases, but the CH4 explosive gas cloud length increased rapidly with the LNG leakage intensity so that dangerous situations would occur for the medium and large leakages, and a leak location closer to air inlet would lead to a more dangerous situation. When the amount of LNG leakage in the tunnel is large, the effect of mechanical ventilation is obviously weakened. Furthermore, a nitrogen seal precaution was proposed for the situations.

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“…Based on the numerical simulation results, modifying the cavity structure can effectively alleviate stress concentration between cavities, thereby allowing for extensive stress relief and permeability enhancement. Song et al [22] performed numerical simulation experiments to assess the impact of natural fractures on hydraulic fracture propagation. They investigated the effects of various factors, including the approaching angle, differential principal stress, length and strength of natural fractures, reservoir elastic modulus, and Poisson's ratio.…”

Section: Introductionmentioning

confidence: 99%

Research on Hydraulic Fracturing Technology of Long Boreholes along Strata of High Vast Thick Coal Seam

Wang,

Li,

Liu

et al. 2024

Advances in Civil Engineering

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Gas extraction is a major technique for regional gas regulation and coal and gas comining in China. Assuring effective gas extraction operations is a crucial step in ensuring the supply of energy. The effect range of extraction drilling, pressure relief degree, and standard period of gas extraction are all constrained because of the geological constraints affecting coal gas permeability and occurrence. Combined with the advantages of directional drilling and high-efficiency pumping technology and antireflection enhanced pumping technology of hydraulic fracturing, directional long-drilling hydraulic fracturing can effectively improve the efficiency of gas control and expand the scale of gas control. The present study focuses on the exploration of directional long-hole hydraulic fracturing technique in thick coal seams with high gas content using Dafosi Mine as a case study. The research findings demonstrate that hydraulic fracturing contributes to the enlargement of pore size, pore density, and pore connectivity in coal seams. In-depth research was conducted on the expansion of coal seam fractures during the hydraulic fracturing process using the RFPA3D-flow numerical simulation program. Additionally, a comprehensive analysis of stress distribution around the fractures under the flow-solid coupling condition was performed. To further improve the effectiveness of hydraulic fracturing technique, the research team optimized the fracturing tools and construction processes in the four coal seams of Dafosi Mine. The impact of segmented hydraulic fracturing in coal seam bare hole drilling was also studied. Furthermore, an investigation method specific to the coal seam bare hole segmented hydraulic fracturing effects applicable to Dafosi Mine was developed. The maximum fracture extension pressure, minimum fracture closure pressure, and fracture morphology change characteristics during drilling and fracturing were measured, and the fracturing influence radius of coal seam was determined to be 46−58 m, the gas extraction concentration after fracturing increased by 2.20–4.22 times, and the 100-m extraction flow increased by 4.93–11.03 times. It gives other mines technical assistance so they can keep advocating and utilizing the horizontal directional long-drilling stage hydraulic fracturing technique.

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Numerical Simulation of the Influence of Natural Fractures on Hydraulic Fracture Propagation

Cited by 11 publications

References 35 publications

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

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

Numerical Simulation and Analysis of Diffusion Process for the Leakages of a Tunnel LNG Pipeline

Research on Hydraulic Fracturing Technology of Long Boreholes along Strata of High Vast Thick Coal Seam

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