| 英文摘要 | The Unconventional oil and gas resources are playing an increasingly important role in global energy. Tight sandstone reservoirs, as typical representatives of unconventional reservoirs, have been a focal point of the energy industry in achieving large-scale economically viable exploitation. However, tight sandstone formations typically exhibit low porosity and permeability, necessitating the construction of an artificial fracture network within the reservoir to enhance the migration of hydrocarbons from the pores to the wellbore. Therefore, studying the mechanical mechanisms of microfracture network formation in tight sandstone is crucial. This paper focuses on tight sandstone dominated by brittle minerals and presents a numerical simulation model based on a two-dimensional discrete element method. The model takes into account the influence of multi-component mineral characteristics and rock microstructure, enabling simulation of fracture network growth under various loading conditions. Furthermore, to address the current challenge of in situ high-resolution observation of hydraulic fracture networks, a hydraulic fracturing online scanning platform (HFCP) is established, accompanied by corresponding experimental procedures and analysis methods, to investigate the general patterns of in situ hydraulic fracturing in tight sandstone. The specific research contributions are as follows:
Investigating the mechanisms of fracture network generation and propagation under tensile stress. The Brazilian splitting loading method is employed to study the formation patterns of microfracture networks at the center of the rock model. The experimental results validate the mechanical performance of the model and the accuracy of fracture network growth calculations. Furthermore, a local tensile model is utilized to demonstrate that primary microfractures exhibit a more pronounced preferential orientation effect compared to micropores. Subsequently, the influence of primary microfractures and micropores on macroscopic rock failure and stress-strain curves is further discussed. Computational results reveal that an increase in pore density leads to the development of twisting tensile fractures within the rock core, while an increase in fracture density does not exhibit such behavior. Under the same central tensile stress, primary microfractures affected by the preferential orientation effect are more likely to induce the formation of rock microfractures compared to micropores. When the fracture density exceeds 0.324 or the pore density exceeds 0.041 , the number of growing microfractures is primarily controlled by microdefect density, and the influence of the stiffness ratio of springs can be neglected.
An in situ hydraulic fracturing experiment and corresponding result analysis method are proposed. To address the challenges encountered in observing hydraulic fracture networks using micro-CT, new fracturing components are designed, along with compatible installation methods and power adjustment schemes. The Hydraulic Fracturing Online Scanning Platform (HFCP) is ultimately constructed to conduct in situ hydraulic fracturing experiments, accompanied by a designed experimental procedure. Utilizing the HFCP, hydraulic fracturing experiments on tight sandstone are conducted, enabling real-time monitoring of injected fluid pressure and post-processing of fracture network images. Subsequently, based on the experimental results, the influence of injection rate and confining pressure on the fluid pressure curve is discussed. The experimental results demonstrate that, under different confining pressures, an increase in injection rate leads to higher fluid breakdown pressure and average fracture aperture, but the variation of branch fracture volume fraction exhibits diverse characteristics.
The mechanisms of hydraulic fracturing impact on fracture network generation and propagation are clarified. A numerical model for hydraulic fracturing is constructed based on the physical properties of actual rock, with loading conditions consistent with the laboratory HFCP fracturing experiments. Building upon the theoretical solutions and experimental verification, the optimal strategies for injection rate and confining pressure variations during fracture network growth are discussed. Subsequently, primary microfractures and micropores are introduced into the rock model, and the impact of these two types of microdefects on the fluid pressure curve, particle cloud images, and fracture network distribution is compared. The computational results demonstrate that as the confining pressure increases, the breakdown pressure linearly increases while the average fracture width monotonically decreases exponentially. The highest fraction of branch fracture area in the fracturing network occurs when the stress coefficient is within the range of 0.532-0.572. Compared to different minerals and microfractures, micropores cause more significant fluctuations in the fluid pressure curve within the model, as well as notable changes in particle displacement and stress distribution. Additionally, the presence of isotropic stresses alters the direction of fracture growth and affects the distribution of the fracture network.
The research findings of this study contribute to further controlling the growth of artificial fracture networks in hydraulic fracturing operations, while providing a theoretical foundation for enhancing the oil and gas recovery efficiency in tight sandstone reservoirs. |
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