Study on the mechanism of anisotropic wellbore instability in continental shale in Songliao Basin

Wellbore instability is frequently encountered in the process of shale oil drilling. Due to the anisotropic strength characteristics of shale, most conventional models are not suitable for wellbore stability analysis in layered formation. In this paper, taking the continental shale in the north of Songliao Basin as the research object, the anisotropic elasticity and strength parameters of shale are measured experimentally. Based on pore elastic mechanics, an anisotropic wellbore stability model of layered shale is established, and the variation of collapse pressure under different formation conditions is analyzed. The results show that considering the elastic and strength anisotropy, the collapse pressure is the largest, and the influence of strength anisotropy is significantly greater than that of elastic anisotropy. The stability of horizontal wells drilled along the horizontal maximum principal stress is the optimal, followed by vertical wells and small angle directional wells. The actual drilling conditions of G101 well are basically consistent with the prediction results, which confirms the accuracy of the model. According to the traditional wellbore stability model, the equivalent density of collapse pressure in horizontal well section is 1.58 similar to 1.76 g/cm(3). It is much lower than the collapse density of 1.86 g/cm(3) calculated by the anisotropic model in this study. The findings of this study can help for better understanding of the mechanism of wellbore instability in horizontal wells in shale formations. The model can be used to guide the drilling engineering design of shale oil horizontal wells and reduce the losses caused by the instability of the wellbore.

Automated summary

This study established a wellbore stability model for layered shale based on experimentally measured anisotropic elasticity and strength parameters. The results showed that considering anisotropy, the collapse pressure is the largest, and the influence of strength anisotropy is greater than that of elastic anisotropy. Horizontal wells have the best stability, and the actual drilling conditions of G101 well were consistent with the predicted results.