Experimental study of hydraulic fracture propagation with multi-cluster in-plane perforations in a horizontal well

IF 6 1区 工程技术 Q2 ENERGY & FUELS
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Abstract

Tri-axial fracturing studies were carried out to understand the impact of lateral mechanical parameters on fracture propagation from multiple in-plane perforations in horizontal wells. Additionally, the discussion covered the effects of geology, treatment, and perforation characteristics on the non-planar propagation behavior. According to experimental findings, two parallel transverse fractures can be successfully initiated from in-plane perforation clusters in the horizontal well because of the in-plane perforation, the guide nonuniform fishbone structure fracture propagation still can be exhibited. The emergence of transverse fractures and axial fractures combined as complex fractures under low horizontal principal stress difference and large pump rate conditions. The injection pressure was also investigated, and the largest breakdown pressure can be also found for samples under these conditions. The increase in perforation number or decrease in the cluster spacing could provide more chances to increase the complexity of the target stimulated zone, thus affecting the pressure fluctuation. In a contrast, the increase in fracturing fluid viscosity can reduce the multiple fracture complexity. The fracture propagation is significantly affected by the change in the rock mechanical properties. The fracture geometry in the high brittle zone seems to be complicated and tends to induce fracture reorientation from the weak-brittle zone. The stress shadow effect can be used to explain the fracture attraction, branch, connection, and repulsion in the multiple perforation clusters for the horizontal well. The increase in the rock heterogeneity can enhance the stress shadow effect, resulting in more complex fracture geometry. In addition, the variable density perforation and temporary plugging fracturing were also conducted, demonstrating higher likelihood for non-uniform multiple fracture propagation. Thus, to increase the perforation efficiency along the horizontal well, it is necessary to consider the lateral fracability of the horizontal well on target formation.
水平井多簇平面射孔水力压裂传播实验研究
进行了三轴压裂研究,以了解横向机械参数对水平井多平面射孔压裂传播的影响。此外,还讨论了地质、处理和射孔特性对非平面传播行为的影响。实验结果表明,在水平井中,由于采用了平面射孔,两个平行的横向裂缝可以从平面射孔簇中成功启动,但仍然可以表现出导向不均匀的鱼骨状结构裂缝扩展。在低水平主应力差和大泵率条件下,横向裂缝和轴向裂缝结合为复合裂缝。此外,还对注入压力进行了研究,发现在这些条件下样品的击穿压力最大。射孔数量的增加或簇间距的减小可以提供更多的机会来增加目标激发区的复杂性,从而影响压力波动。相反,压裂液粘度的增加则会降低多重裂缝的复杂性。岩石力学性质的变化对裂缝扩展有很大影响。高脆性区的裂缝几何形状似乎很复杂,往往会引起裂缝从弱脆性区重新定向。应力阴影效应可用于解释水平井多射孔群中的裂缝吸引、分支、连接和排斥。岩石异质性的增加会增强应力阴影效应,导致裂缝几何形状更加复杂。此外,还进行了变密度射孔和临时堵塞压裂,结果表明非均匀多裂缝传播的可能性更大。因此,要提高水平井的射孔效率,必须考虑水平井对目标地层的横向可压裂性。
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来源期刊
Petroleum Science
Petroleum Science 地学-地球化学与地球物理
CiteScore
7.70
自引率
16.10%
发文量
311
审稿时长
63 days
期刊介绍: Petroleum Science is the only English journal in China on petroleum science and technology that is intended for professionals engaged in petroleum science research and technical applications all over the world, as well as the managerial personnel of oil companies. It covers petroleum geology, petroleum geophysics, petroleum engineering, petrochemistry & chemical engineering, petroleum mechanics, and economic management. It aims to introduce the latest results in oil industry research in China, promote cooperation in petroleum science research between China and the rest of the world, and build a bridge for scientific communication between China and the world.
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