Abstract
Multistage fracturing of horizontal wells to form a complex fracture network is an essential technology in the exploitation of shale gas. Different from the conventional reservoirs, the mechanical characteristics of shale rock have significant heterogeneity due to the existence of beddings, which makes it difficult to predict the fracture geometry in the shale reservoir. Based on the laboratory experiments, the factors that affect fracture propagation were analyzed. The experimental results revealed that the hydraulic fracture would cross the beddings under the high vertical stress difference, while it would propagate along with the bedding under the low vertical stress difference; besides, the low injection rate and viscosity of the fracturing fluid were beneficial to generate a complex fracture network. Under the high injection rate and viscosity, a planar fracture was created, while a nonplanar fracture was observed under the low injection rate and viscosity, and branch fracture was created. According to the acoustic emission events, the shear events were the main events that occurred during the hydraulic fracturing process, and the acoustic emission events could be adopted to describe the fracture network. Lastly, the supercritical carbon dioxide fracturing was more effective compared with the hydraulic fracturing because the fracture network was more complex.
Highlights
Hydraulic fracturing has become an essential technology inRthe exploration of shale reservoir
Under the vertical stress difference of 6 MPa, the fracturing fluid with low viscosity and low injection rate could leak into the beddings, which could enhance the possibility for interaction between propagators
The flow rate and viscosity were the controllable factors in the hydraulic fracturing field
Summary
It it is of great importance to understand the fracture initiation was found that different types of interactions between and propagation mechanism in the vertical plane for estimat- hydraulic fractures and natural fractures were observed ing the stimulated reservoir volume. They found that the hydraulic fracture crossed [9,10,11,12,13] have studied the factors which affected the vertical the preexisting fracture under high horizontal differential propagation of the hydraulic fracture, which included the stress. Based on the finite element method, Guo et al [15] investigated the relationship between horizontal differential stress and fracture propagation path based on numerical simulation They found that a large approaching angle was a comparatively.
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