Numerical Investigation of the Gas Production Efficiency and Induced Geomechanical Responses in Marine Methane Hydrate-Bearing Sediments Exploited by Depressurization through Hydraulic Fractures

Guo, Xuyang; Jin, Yan; Zi, Jingyu; Lin, Bor-Luh

doi:10.1021/acs.energyfuels.1c02569

Cited by 19 publications

(10 citation statements)

References 45 publications

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“…If necessary, only a small amount of inorganic salt should be added, and the drilling fluid density should be strictly controlled. Guo et al 43 studied the geomechanical response of hydraulic fracturing combined with depressurization and compared the effects of hydraulic fracturing in reservoirs with different permeabilities. Hydraulic fracturing has a more optimized effect and is less likely to cause shear failure in hydrate-bearing sediments with a low permeability.…”

Section: Mechanical Stability Of Nghrsmentioning

confidence: 99%

Reservoir Stimulation Technologies for Natural Gas Hydrate: Research Progress, Challenges, and Perspectives

Liang

2023

Energy Fuels

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The energy crisis has intensified in recent years. The current global economic environment and increasing cost of mining necessitate additional energy access channels. Previous studies have shown that natural gas hydrate reservoirs (NGHRs) contain a large number of natural gas resources. However, several problems are associated with the safe and efficient exploitation of the NGHRs. Reservoir stimulation technology is expected to address these issues. This study introduces the properties and mining difficulties of NGHRs and reviews their stimulation scheme and related research progress based on three perspectives: hydraulic fracturing, burden sealing, and near-well reconstruction. The principles, advantages, and limitations of the three schemes are compared. In addition to the stimulation effects of the three aforementioned methods, this study focused on the fracability of NGHRs, the factors influencing fracture initiation and development, and the fracturing fluid, proppant, completion fluid, and slurry suitable for NGHR stimulation. In addition, the principles, current challenges, and future research prospects for reservoir stimulation are summarized to provide a reference for the commercial exploitation of natural gas hydrates in the future.

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Section: Mechanical Stability Of Nghrsmentioning

confidence: 99%

Reservoir Stimulation Technologies for Natural Gas Hydrate: Research Progress, Challenges, and Perspectives

Liang

2023

Energy Fuels

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“…They enable a comprehensive assessment of reservoir behavior. As an example, in a series of studies, Sangnimnuan et al (2018), Guo et al (2021) and Guo et al (2023) proposed a coupling strategy for the quantification of temporal and spatial evolution of pressure, stress, and temperature in hydrocarbon-bearing formation, where stress-dependent reservoir rock behaviors are comprehensively analyzed. The characterization of rock deformation and failure requires the use of accurate modeling techniques.…”

Section: Introductionmentioning

confidence: 99%

The experimental and numerical analysis of elastic rock mechanical properties in tight conglomerate rock samples: a case study in Junggar Basin

Qi,

Li,

Zhao

et al. 2024

Front. Energy Res.

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Tight conglomerate rocks consist of gravels and rock matrices. The existence of these stiff gravels leads to heterogeneity in conglomerates and makes it difficult to characterize rock mechanical properties, which then affects drilling and hydraulic fracturing operations in tight conglomerate hydrocarbon-bearing reservoirs. This case study introduces a series of experimental and numerical analyses for the better understanding of rock deformation and elastic wave propagation patterns in a tight conglomerate reservoir in Junggar Basin, China. Tri-axial compression tests, acoustic test, and finite element modeling of rock deformation and elastic wave propagation in conglomerate rocks are presented. Experimentally tested samples exhibit good brittleness and shearing failure patterns, while well correlated static-dynamic elastic moduli and P-S wave velocities are captured. Numerical results show that the existence of stiff gravels leads to strong direction-dependent stress and strain anisotropies. Stress concentrations are also induced by gravels radially and axially. In the elastic wave domain, stiff gravels facilitate the propagation of elastic waves. The gravel close to the wave source also induces stronger compressive/tensile states in the wave domain, indicating that the existence of gravels in conglomerates can alter waveforms. This integrated approach improves the quantitative understanding of stress, strain, and elastic wave responses in heterogeneous tight conglomerates. This case study also serves as a reference for the brittleness evaluation and geomechanical evaluation in the study area. The contribution of this work is primarily about the integrated experimental study, solid deformation modeling, and elastic wave modeling of tight conglomerate rocks.

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“…Wang Xudong etc. [8][9][10]. In order to determine the size of the moving area of sand layer and the permeability distribution of the near well area, a simulation model of macroscopic radial flow in microporous medium is proposed.…”

Section: Introductionmentioning

confidence: 99%

Study on Sand Production Evolution Mechanism of High Muddy Silt and Fine Sand Hydrate Reservoir Exploitation in Sea Area

Feng

et al. 2022

Advances in Transdisciplinary Engineering

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According to the grading curve and Water content allocation of the hydrate reservoir, the particle size distribution and water condition of the formation sand are simulated, and the gas drive pressure difference condition is set. Under the condition of gravel packing and sand control, the one-dimensional unidirectional flow of high argillaceous and fine sand under gas drive is analyzed, and the parameters such as displacement pressure difference, flow rate, sand proportion and permeability are measured. The three phase percolation law of gas, water and solid particles from the initial stage to the end of the test was systematically analyzed. The results show that the evolution process of sand production is divided into four stages: initial particle-free migration, slow particle migration, rapid particle migration and particle structure stability. The time of specific process is controlled by pressure difference and gas-water flow conditions. Because of the high mud content, the slow migration phase of the particles will migrate and consolidate on the outer wall of the sand retention structure to form a mud layer (permeability is 0.1–5 Milli Darcy). The mud layer has a certain stable structure and strength, which has a significant influence on the water flow conditions and has no obvious influence on the gas percolation. The test results reveal three mechanisms for the exploitation of natural gas hydrate reservoirs, namely the sanding evolution process, the gravel filling sand blocking and the mud layer sand resistance with certain permeability and strength.

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Numerical Investigation of the Gas Production Efficiency and Induced Geomechanical Responses in Marine Methane Hydrate-Bearing Sediments Exploited by Depressurization through Hydraulic Fractures

Cited by 19 publications

References 45 publications

Reservoir Stimulation Technologies for Natural Gas Hydrate: Research Progress, Challenges, and Perspectives

Reservoir Stimulation Technologies for Natural Gas Hydrate: Research Progress, Challenges, and Perspectives

The experimental and numerical analysis of elastic rock mechanical properties in tight conglomerate rock samples: a case study in Junggar Basin

Study on Sand Production Evolution Mechanism of High Muddy Silt and Fine Sand Hydrate Reservoir Exploitation in Sea Area

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