| Citation: |
QIAN Qin, LU Mingjing, ZHONG Anhai. Study on fracture morphology of CO2 energized fracturing of continental shale oil in Dongying Sag [J]. Petroleum Drilling Techniques,2023, 51(5):42-48. DOI: 10.11911/syztjs.2023082
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In the process of CO2 energized fracturing, the evaluation of fracturing stimulation effect and production effect is affected by fracture distribution. In order to clarify the fracture mechanism of CO2 fracturing of continental shale oil in Dongying Sag, the changes in rock mass fracture pressure, natural fracture shear/opening stress, and in-situ stress with time under CO2 immersion were determined by experiments. On this basis, by considering the rock stress parameters under CO2 immersion, the Pen-Robinson equation was used to describe the change of CO2 physical property parameters. In addition, combined with experimental and numerical methods, a simulation method for fracture propagation by CO2 energized fracturing based on node connection method was developed, and an example analysis of an oil well in Dongying Sag was carried out. The results show that the CO2 ratio has a great influence on the induced fracture density. When the CO2 ratio increased from 0.1 to 0.3, the induced fracture density increased by 117%. The stress difference mainly affects the fracture length and induced fracture density. When the horizontal stress difference increased from 5 MPa to 30 MPa, the fracture network length increased by 52%, and the induced fracture density decreased by 13.85%. The simulation results of fracture morphology are in good agreement with the actual monitoring. This study can provide a theoretical reference for the formulation of continental shale oil fracturing schemes.
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