The Effect of Bottomhole Assembly Dynamics on the Trajectory of a Bit

Millheim, Keith K.; Apostal, M.C.

doi:10.2118/9222-pa

Cited by 52 publications

(22 citation statements)

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“…As concluded in [4] maximum efficiency of the drilling system is obtained when the stabilizer is closest to the drill bit while preventing drill collar from contacting the wall. Based on these facts, the drillstring system is here modeled as a simply supported axially moving rotor and contact with the wall has been neglected.…”

Section: Equations Of Motionmentioning

confidence: 90%

“…It can also cause substantial damage to the borehole wall and premature failure of bits and other drillstring components [1][2][3][4].…”

Section: Introductionmentioning

confidence: 99%

“…Theoretical investigation of the lateral drillstring vibrations was initiated with the so called Jeffcott model which was a relatively simple low-dimensional approach [4,[10][11][12][13]. Also, continuous model was employed for studying the lateral vibrations of the drillstring [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

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Nonlinear vibration analysis of an axially moving drillstring system with time dependent axial load and axial velocity in inclined well

Sahebkar

Ghazavi

Khadem

et al. 2011

Mechanism and Machine Theory

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Section: Equations Of Motionmentioning

confidence: 90%

“…It can also cause substantial damage to the borehole wall and premature failure of bits and other drillstring components [1][2][3][4].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Nonlinear vibration analysis of an axially moving drillstring system with time dependent axial load and axial velocity in inclined well

Sahebkar

Ghazavi

Khadem

et al. 2011

Mechanism and Machine Theory

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“…The implementation follows the matrix-displacement approach from structural analysis. Millheim and Apostal (1981) extend this approach to dynamic analysis and the prediction of directional tendency during drilling. Later investigations have moved forward on the full complexity of predicting BHA dynamics, vibrations, and frequency response (e.g., Apostal et al 1990;Aslaksen et al 2006;Bailey et al 2008;Bailey and Remmert 2010).…”

Section: Review Of Bending-stiffness Modelsmentioning

confidence: 99%

Advanced Casing Design With Finite-Element Model of Effective Dogleg Severity, Radial Displacements, and Bending Loads

McSpadden

Coker

Ruan³

2012

SPE Drilling &Amp; Completion

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A purpose-built finite-element model (FEM) is applied to simulate radial displacement of a casing string constrained within an outer wellbore. The FEM represents a fully stiff-string model wherein the casing is approximated by general-beam elements with six degrees of freedom at each node to account for all possible physical displacements and rotations. Results predicted include deflection of the casing centerline from the wellbore centerline, effective dogleg curvature, bending deformation, wall-contact forces, and bendingstress magnification. These results will provide for a more-accurate assessment of well integrity in terms of casing-stress safety factors and centralization before cementing, as well as more accurate prediction of running loads during the drilling phase.In critical-well-casing design, accurate assumptions regarding bending stiffness may be necessary to avoid overly conservative as well as nonconservative analysis. Challenging finite high-pressure/ high-temperature (HP/HT) and extreme-temperature wells are opportunities for increased design efficiency by avoiding overly conservative and costly designs, which can be crucial. Alternatively, design for extreme loads such as overpull loads in long deviated wells may be nonconservative if severe bending stresses are not considered.A realistic case study is presented that demonstrates the possibility to achieve cost efficiency by means of optimized casing design. A case study also is presented in which a nonconservative design may result if severe bending loads are not modeled. The purpose-built FEM code is in many ways preferable to the use of commercial finite-element-analysis (FEA) packages because of the time-consuming effort required to build up the detailed model.In typical casing and tubular-stress design, a soft-string model assumes casing strings are coincident with the wellbore centerline. The known or assumed wellbore curvature is applied directly to the casing string. Any effect of casing-string stiffness and allowable radial displacement within the outer wellbore is ignored. In many cases, this results in an overly conservative analysis. Likewise, the impact of bending-stress magnification is typically ignored, along with the effects of centralizer placement. This may also be nonconservative for critical overpull situations, such as in extended-reach-drilling (ERD) and horizontal wells.

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“…Alternatively, more sophisticated models may be used that include the influence of stabilizers and hole angle. 24 Eq. B-4 may also be used for the connections of heavy-wall drillpipe when run in compression.…”

Section: Appendix B-inspection Interval Equationsmentioning

confidence: 99%

Inspection Interval Guidelines To Reduce Drillstring Failures

Dale

1989

SPE Drilling Engineering

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Inspection interval guidelines were developed to reduce the occurrence of costly drill string fatigue failures. The guidelines are based on a state-of-the-art fracture mechanics model and incorporate reliability data of commercial inspection services using conventional nondestructive testing techniques. On the basis of extensive full-scale testing, the model was found to predict fatigue-crack-growth behavior reliably. By establishing inspection intervals on the basis of fatigue-crack growth, inspection services are systematically and cost-effectively specified to achieve acceptable reliability (or risk). Simple equations and charts are presented in terms of practical drilling parameters to reduce typical downhole fatigue failures. IntroductionFatigue and corrosion fatigue are recognized as a major cause of downhole driIIstring failures. 1 In practice, the oil industry attempts to guard against the likelihood of these costly failures by performing periodic nondestructive inspectiops to remove damaged tubulars from service. 2 Drillstring inspections are usually conducted by service companies that perform a variety of visual, dimensional, and nondestructive inspection procedures to locate cracks and to classify the pipe for future drilling service. 3 These procedures generally consist of both automated and manual techniques to assess the condition of the connections and pipe body. Classification is normally completed in accordance with API specifications,2.4 but detailed user specifications are also frequently used to ensure the quality of inspection work performed. 5 Conventional nondestructive testing techniques are capable only of detecting fatigue damage that results in the formation of macroscopic cracks. Thus, inspection intervals are "effectively" limited by the time for undetected cracks to grow until failure. Inspections are typically performed before the start of a well but may be performed several times throughout the drilling of deep, deviated wellbores or "hard-rock" formations. Inspection intervals traditionally have been selected on the basis of experience in a given regional area, but costly failures often occur during this learning process.This paper describes the development and application of a fracture mechanics model, verified by extensive full-scale testing, to predict fatigue-crack-growth behavior in the pipe body and connections. After reliability data of commercial inspection services are discussed, simple equations and charts are presented in terms of practical drilling parameters to reduce typical downhole fatigue failures.

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The Effect of Bottomhole Assembly Dynamics on the Trajectory of a Bit

Cited by 52 publications

References 0 publications

Nonlinear vibration analysis of an axially moving drillstring system with time dependent axial load and axial velocity in inclined well

Nonlinear vibration analysis of an axially moving drillstring system with time dependent axial load and axial velocity in inclined well

Advanced Casing Design With Finite-Element Model of Effective Dogleg Severity, Radial Displacements, and Bending Loads

Inspection Interval Guidelines To Reduce Drillstring Failures

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