A hybrid multi objective cellular spotted hyena optimizer for wellbore trajectory optimization.

Kallol Biswas,Amril Nazir,Md Ashikur Rahman,Jahedul Islam,Abubakr M Idris,Mayeen Uddin Khandaker,Abdul-Halim M Jallad,Md Tauhidur Rahman,Mohd Nadhir Ab Wahab

doi:10.1371/journal.pone.0261427

Abstract

Cost and safety are critical factors in the oil and gas industry for optimizing wellbore trajectory, which is a constrained and nonlinear optimization problem. In this work, the wellbore trajectory is optimized using the true measured depth, well profile energy, and torque. Numerous metaheuristic algorithms were employed to optimize these objectives by tuning 17 constrained variables, with notable drawbacks including decreased exploitation/exploration capability, local optima trapping, non-uniform distribution of non-dominated solutions, and inability to track isolated minima. The purpose of this work is to propose a modified multi-objective cellular spotted hyena algorithm (MOCSHOPSO) for optimizing true measured depth, well profile energy, and torque. To overcome the aforementioned difficulties, the modification incorporates cellular automata (CA) and particle swarm optimization (PSO). By adding CA, the SHO’s exploration phase is enhanced, and the SHO’s hunting mechanisms are modified with PSO’s velocity update property. Several geophysical and operational constraints have been utilized during trajectory optimization and data has been collected from the Gulf of Suez oil field. The proposed algorithm was compared with the standard methods (MOCPSO, MOSHO, MOCGWO) and observed significant improvements in terms of better distribution of non-dominated solutions, better-searching capability, a minimum number of isolated minima, and better Pareto optimal front. These significant improvements were validated by analysing the algorithms in terms of some statistical analysis, such as IGD, MS, SP, and ER. The proposed algorithm has obtained the lowest values in IGD, SP and ER, on the other side highest values in MS. Finally, an adaptive neighbourhood mechanism has been proposed which showed better performance than the fixed neighbourhood topology such as L5, L9, C9, C13, C21, and C25. Hopefully, this newly proposed modified algorithm will pave the way for better wellbore trajectory optimization.

Highlights

The increasing demand for energy consumption around the world has promoted the depletion of conventional energy sources
Several statistical analyses are discussed to investigate the performance of the proposed algorithm qualitatively and quantitively for wellbore trajectory optimization
The hybridization is done with the incorporation of cellular automata (CA) and particle swarm optimization (PSO)

Summary

Introduction

The increasing demand for energy consumption around the world has promoted the depletion of conventional energy sources. The high energy demand has drawn attention to producing energy from unconventional sources. Producing oil/gas from unconventional sources is not easier with conventional production methods. One of the major challenges in directional / horizontal drilling is wellbore trajectory design, which is associated with cost and safety [2]. Directional/horizontal drilling needs high expenditure, which tends to increase the oil and gas price at the consumer level. To minimize the oil/gas price, it is crucial to minimize the operational expenditure. In directional/horizontal drilling, one of the key ways to reducing operational expenditure is optimizing the wellbore trajectory [3]

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Results

Conclusion