Abstract
The formation of complex fracture networks through the fracturing technology is a crucial operation used to improve the production capacity of tight gas/oil. In this study, physical simulation experiments of hydraulic fracturing were conducted with a true triaxial test system on cubic shale oil samples from the Yanchang Formation, China. The fractures were scanned by CT both before and after the experiments and then reconstructed in 3D. The complexity of fracture networks was investigated quantitatively by the fractal theory with topology. Finally, the effect of the horizontal stress ratio, fluid viscosity, and natural fractures on the complexity of the fracture networks was discussed. The results indicate that the method based on fractal theory and topology can effectively characterize the complexity of the fracture network. The change rates of the fractal dimension (K) are 0.45–3.64%, and the fractal dimensions (DNH) of the 3D fracture network after fracturing are 1.9522–2.1837, the number of connections per branch after fracturing (CB) are 1.57–2.0. The change rate of the fractal dimension and the horizontal stress ratio are negatively correlated. However, the change rate of the fractal dimension first increases and then decreases under increasing fluid viscosities, and a transition occurs at a fluid viscosity of 5.0 mPa·s. Whether under different horizontal stress ratios or fluid viscosities, the complexity of the fracture networks after fracturing can be divided into four levels according to DNH and CB. Complex fracture networks are more easily formed under a lower horizontal stress ratio and a relatively low fluid viscosity. A fracturing fluid viscosity that is too low or too high limits the formation of a fracture network.
Highlights
Shale oil is an unconventional petroleum resource and has great potential for exploration and development [1,2]
We focused on discussing the fractal dimension change rate (K) and the number of connections per fracture branch (CB) before and after fracturing under different horizontal stress ratios and fluid viscosities. 3 of 17
The results show that it is more conducive to the formation of complex fracture networks at a low horizontal stress ratio
Summary
Shale oil is an unconventional petroleum resource and has great potential for exploration and development [1,2]. The quantitative characterization of the complexity of fracture networks after fracturing can be used to obtain an index of reservoir reconstruction efficiency. Jiang et al [32] and Liu et al [33] investigated the effects of in situ stress and fracturing fluid on the propagation and distribution characteristics of hydraulic fractures based on the 3D reconstruction technology. Based on CT scanning, some scholars [50,51,52] characterized the fracture networks of coal rocks by the fractal theory and discussed the effect of loading on its evolution. It is necessary to consider both fractal dimension and Energies 2021, 14, 1123 the effect of the horizontal stress ratio, fluid viscosity, and natural fractures on the complexity of fracture networks in oil shale, hydraulic fracturing physical simulation experiments and 3D fracture reconstruction were carried out. We focused on discussing the fractal dimension change rate (K) and the number of connections per fracture branch (CB) before and after fracturing under different horizontal stress ratios and fluid viscosities. 3 of 17
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