Your search keyword '"seepage-stress"' showing total 2 results

1. Numerical Simulation on Deflecting Hydraulic Fracture with Refracturing Using Extended Finite Element Method

Author

Jianxiong Li, Shiming Dong, Wen Hua, Yang Yang, and Xiaolong Li

Subjects

refracturing, deflecting mechanism, seepage-stress, extended finite element method (XFEM), diverting fracture, deflection angle, Technology

Abstract

Refracturing is a key technology in enhancing the conductivity of fractures from hydraulically-fractured wells. However, the deflecting mechanism of the diverting fracture is still unclear. In this paper, a fully coupled seepage-stress model based on the extended finite element method (XFEM) was developed to realize the deflection mechanism of the refracturing fractures. The modified construction of refracturing was then verified by laboratory experiments. Furthermore, two new deflection angles considering the influence area along initial fracture length were introduced to evaluate the refracturing. The numerical results demonstrated that: (1) lower stress difference, larger perforation angle and longer perforation depth can lead to a higher deflection angle, thereby a more curving propagation path of the diverting fracture; (2) increasing injection rate or fluid viscosity can significantly enhance the diverting behavior; and (3) an initial location near the root of the initial fracture results in a larger value of the deflection angle, which is preferred for far-field refracturing. The conclusions in this study can be a systematic guide for the parameter optimization in refracturing treatment.

Published

2019

2. Numerical Simulation on Deflecting Hydraulic Fracture with Refracturing Using Extended Finite Element Method.

Author

Li, Jianxiong, Dong, Shiming, Hua, Wen, Yang, Yang, and Li, Xiaolong

Subjects

*FINITE element method, *HYDRAULIC fracturing, *SEEPAGE, *COMPUTER simulation

Abstract

Refracturing is a key technology in enhancing the conductivity of fractures from hydraulically-fractured wells. However, the deflecting mechanism of the diverting fracture is still unclear. In this paper, a fully coupled seepage-stress model based on the extended finite element method (XFEM) was developed to realize the deflection mechanism of the refracturing fractures. The modified construction of refracturing was then verified by laboratory experiments. Furthermore, two new deflection angles considering the influence area along initial fracture length were introduced to evaluate the refracturing. The numerical results demonstrated that: (1) lower stress difference, larger perforation angle and longer perforation depth can lead to a higher deflection angle, thereby a more curving propagation path of the diverting fracture; (2) increasing injection rate or fluid viscosity can significantly enhance the diverting behavior; and (3) an initial location near the root of the initial fracture results in a larger value of the deflection angle, which is preferred for far-field refracturing. The conclusions in this study can be a systematic guide for the parameter optimization in refracturing treatment. [ABSTRACT FROM AUTHOR]

Published

2019