Title
Multi-x-objective Optimization of Drilling Trajectory Considering Buckling Risk
Authors
Jiho Jeong, Chaeog Lim, Byeong-Cheol Park, Jeonghoon Bae, Sung-chul Shin
Abstract
Directional drilling involves three sections―vertical, curved, and horizontal―and is used for drilling offshore wells and mining unconventional resources. The initial design of a well trajectory is important because the total length of the well trajectory is associated with the drilling cost; furthermore, the drag force and torque may cause buckling and damage the drill pipe. The well trajectory should be optimized considering the length and load of drill pipes. In this study, a new method of optimizing directional well trajectory is used to formulate the x-objective function considering the length, drag, and torque. To verify the applicability of this method, we applied it to an actual oil well and a theoretical oil well. The results obtained show that the use of the proposed method in the initial design of drilling trajectory can reduce the torque by up to 15%, drag by 2.6%, and length by 8.5% for the two models used in this study. This method is safer as it reduces the risk of buckling compared to the design that relies on the previous designer’s experience, and it reduces the trajectory length; thus, it can save time and costs of drilling.
Appl. Sci. 2022, 12, 1829.