Gas Production Enhancement by Horizontal Wells with Hydraulic Fractures in a Natural Gas Hydrate Reservoir: A Thermo-Hydro-Chemical Study

Wang, Feifei; Wang, Zizhen; Zhang, Di; Wang, Zhenqing

doi:10.1021/acs.energyfuels.3c00966

Cited by 8 publications

(2 citation statements)

References 57 publications

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“…Numerical simulation of hydraulic fracturing in HBS is one of the important topics in the study of geological environments, and the fracturing behavior involves multiple scales, ranging from interactions between microscopic particles to fracture extensions at the macroscopic rock level. ,, It is an important means to study reservoir stability and fracturing efficiency transformation . HBS fracturing simulation uses a variety of methods, which mainly include the finite element method (FEM), discrete element method (DEM), extending the finite element method (XFEM), etc., to simulate the pressure response and mechanical behavior of HBS based on the consideration of the microstructure and interactions of hydrates. ,− …”

Section: Experimental and Simulation Methodsmentioning

confidence: 99%

Review and Outlook on Fracturing Technology and Mechanism of Hydrate-Bearing Sediments

Song,

Wang,

Dong

et al. 2024

Energy Fuels

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Natural gas hydrates (NGHs) are widely distributed in marine and permafrost regions with huge reserves, which are considered one of the important potential sources for future clean energy. At present, China, Japan, the United States, Canada, etc. have conducted several trials; however, they all face varying degrees of challenges, such as low gas production efficiency and discontinuous production periods. In the oil and gas industry, hydraulic fracturing is a mature and highly efficient method for enhancing production through pressurization. Therefore, the successful application of fracturing technology to the NGH reservior is an urgently needed solution and could be a potentially revolutionary technology. This study summarizes the main recent fracturing advances in the hydrate field; it outlines the existing fracturing equipment for the NGH reservoir that differs from traditional oil and gas reservoir development, discussing the more efficient numerical simulation methods from the unit cell, experimental scale, to field scale. Additionally, it investigates the main controlling factors of fracturing behavior, such as the effects of fracturing fluid (viscosity and injection rate) and sample conditions (saturation, stress anisotropy, matrix, and natural fractures). The relationships and mechanisms proposed herein can provide new insights for understanding the fracturing behavior during hydrate exploration and constructing safe fracturing and extraction technologies.

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Section: Experimental and Simulation Methodsmentioning

confidence: 99%

Review and Outlook on Fracturing Technology and Mechanism of Hydrate-Bearing Sediments

Song,

Wang,

Dong

et al. 2024

Energy Fuels

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“…Some authors have evaluated hydrate production after reservoir fracturing. Wang et al 26 and Han et al 27 investigated the multifractured well method in developing the gas hydrate reservoir, and they found it had great potential for improving the gas production. Ma et al 28 established a hydraulic fracturing numerical model based on the clayey silt hydrate reservoir property and analyzed the fracture morphology and stress interference during the multicluster fracturing process.…”

Section: Introductionmentioning

confidence: 99%

Class-III Hydrate Reservoir Depressurization Production Enhancement by Volume Fracturing and Cyclic N₂ Stimulation Combination

Xia,

Wang,

Ren

2023

ACS Omega

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The depressurization effect is limited to class III hydrate reservoir recovery. To improve the depressurization effect, a new method of volume-fracturing and cyclic N 2 stimulation combination (VFCS) was proposed. The production performance of this method was investigated by using numerical models based on reservoir parameters of the SH7 hydrate site in the South China Sea. The results show that (1) VFCS can greatly enhance the production performance with the average CH 4 production rate being approximately 2.85 times higher than that of pure depressurization. This method combines the effects of volume fracturing and cyclic N 2 stimulation by improving the seepage environment and further reducing the CH 4 partial pressure in the gas phase. (2) High reservoir permeability, medium hydrate saturation, large volume-fracturing scale, low bottom-hole pressure, and high N 2 injection amount can increase CH 4 production by VFCS. (3) Although VFCS has the largest CH 4 production volume and the highest hydrate dissociation degree among the studied production strategies, the reservoir temperature drop is significant by VFCS and future studies can be focused on the external heat supply to the reservoir to further improve the production.

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Prediction of Gas Production Dynamic of Natural Gas Hydrate Reservoirs Based on Neural Network

Yu,

2024

Lecture Notes in Civil Engineering

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Gas Production Enhancement by Horizontal Wells with Hydraulic Fractures in a Natural Gas Hydrate Reservoir: A Thermo-Hydro-Chemical Study

Cited by 8 publications

References 57 publications

Review and Outlook on Fracturing Technology and Mechanism of Hydrate-Bearing Sediments

Review and Outlook on Fracturing Technology and Mechanism of Hydrate-Bearing Sediments

Class-III Hydrate Reservoir Depressurization Production Enhancement by Volume Fracturing and Cyclic N₂ Stimulation Combination

Prediction of Gas Production Dynamic of Natural Gas Hydrate Reservoirs Based on Neural Network

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Gas Production Enhancement by Horizontal Wells with Hydraulic Fractures in a Natural Gas Hydrate Reservoir: A Thermo-Hydro-Chemical Study

Cited by 8 publications

References 57 publications

Review and Outlook on Fracturing Technology and Mechanism of Hydrate-Bearing Sediments

Review and Outlook on Fracturing Technology and Mechanism of Hydrate-Bearing Sediments

Class-III Hydrate Reservoir Depressurization Production Enhancement by Volume Fracturing and Cyclic N2 Stimulation Combination

Prediction of Gas Production Dynamic of Natural Gas Hydrate Reservoirs Based on Neural Network

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Class-III Hydrate Reservoir Depressurization Production Enhancement by Volume Fracturing and Cyclic N₂ Stimulation Combination