Numerical Simulation on Borehole Instability Based on Disturbance State Concept

This paper carries out a study on the numerical simulation of borehole instability based on the disturbance state concept. By introducing the disturbance damage factor into the classical Mohr–Coulomb yield criterio, we establish a finite element hydro-mechanical coupling model of borehole instabilit...

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Bibliographic Details
Published in:Energies (Basel) 2022-09, Vol.15 (17), p.6295
Main Authors: Wang, Daobing, Qu, Zhan, Ren, Zongxiao, Shan, Qinglin, Yu, Bo, Zhang, Yanjun, Zhang, Wei
Format: Article
Language:English
Subjects:
Analysis
Anisotropy
borehole stability
Boreholes
Computer simulation
Deformation
Disturbance
disturbance state concept
Drilling
Drilling and boring
Drilling fluids
Elastic deformation
elastic–plastic deformation
Equilibrium
finite element method
Friction
Instability
Internal friction
Kelvin-Helmholtz instability
Mathematical models
Mechanical properties
Mechanics
Methods
Mohr-Coulomb theory
Numerical analysis
numerical simulation
Oil sands
Permeability
Plastic deformation
Plastics
Porosity
Rocks
Shear strength
Simulation
Simulation methods
Strain
Stress
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Summary:This paper carries out a study on the numerical simulation of borehole instability based on the disturbance state concept. By introducing the disturbance damage factor into the classical Mohr–Coulomb yield criterio, we establish a finite element hydro-mechanical coupling model of borehole instability and program the relevant field variable by considering elastic–plastic deformation in borehole instability, the distribution of the damage disturbance area, the variation of porosity and permeability with the disturbance damage factor, etc. Numerical simulation shows that the borehole stability is related to the action time of drilling fluid on the wellbore, stress anisotropy, the internal friction angle of rock, and borehole pressure. A higher horizontal stress difference helps suppress shear instability, and a higher rock internal friction angle enhances shear failure around the borehole along the maximum horizontal principal stress. When considering the effect of the internal friction angle of rock, the rock permeability, disturbance damage factor, and equivalent plastic strain show fluctuation characteristics. Under the high internal friction angle of rock, a strong equivalent plastic strain area and disturbance damage area occur in the direction of the maximum horizontal principal stress. Their cloud picture shows the mantis shape, where the bifurcation corresponds to the whiskers of the shear failure area in borehole instability. This study provides a theoretical basis for solving the problem of borehole instability during drilling engineering.
ISSN:1996-1073
1996-1073
DOI:10.3390/en15176295