Numerical Simulation of Motion of Rotating Drill Pipe due to Magnus Effect in Riserless Drilling

Inoue, Tomoya; Suzuki, Hiroki; Tar, Thaw; Senga, Hidetaka; Wada, Kazuyasu; Matsuo, Miki

doi:10.1115/omae2017-62327

Cited by 3 publications

(1 citation statement)

References 0 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Combined with the simulation results of computational fluid dynamics (CFD), they studied the lift force and drag force of drill pipe under different rotating speeds and ocean velocity, and find that lift force increases with ocean velocity and drill pipe rotation speed. This force is quite large and can cause drill pipe to move, resulting in a large bending moment [5]. The present writer simulated the landing string in the marine environment as a flexible tube with lateral and axial coupling motion, and established a dynamic model to study its dynamic response characteristics.…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional nonlinear coupling vibration of drill string in deepwater riserless drilling and its influence on wellbore pressure field

Chen

Liu

Cai

2023

Preprint

View full text Add to dashboard Cite

In deepwater riserless drilling operations, the vibration behavior of drill string may have a significant impact on wellbore pressure, which leads to serious risks of drilling accidents such as well leakage and well collapse in shallow risk areas. In order to solve this problem, based on Hamilton's principle, a three-dimensional nonlinear coupling dynamics model of drill string in deepwater riserless drilling is established to simulate the dynamic behavior of drill string under offshore drilling conditions, considering the influence of heave and offset motion of offshore platform, ocean current load, drillstring-borehole contact and bit-rock interaction. The Newmark-β method is used to solve the nonlinear discrete equations of the system, and the effectiveness of the model and calculation program is verified by the field test data. Meanwhile, a wellbore pressure field model under axial, lateral and torsional motion modes of drill string in deepwater riserless drilling is established. The three-dimensional nonlinear coupling vibration characteristic of drill string and its influence on wellbore pressure fluctuation are investigated. The results indicate that: excitation and natural frequency play a leading role in axial vibration response; the collision between the drill string and the borehole wall mostly occurs in the middle part of the formation section, and the lateral vibration at the bit is the most intense; and the closer to the upper platform, the more high-frequency components of torsional vibration response and the stronger the chaos. The larger the axial vibration amplitude of drill string is, the greater the influence on wellbore pressure field is; for the lateral vibration, the middle and bit position have great influence on the wellbore pressure field; for the torsional vibration, the bottom position has the greatest influence on wellbore pressure field. Compared with the axial and torsional vibration, the lateral vibration of drill string has the greatest influence on the wellbore pressure field.

show abstract

Section: Introductionmentioning

confidence: 99%

Three-dimensional nonlinear coupling vibration of drill string in deepwater riserless drilling and its influence on wellbore pressure field

Chen

Liu

Cai

2023

Preprint

View full text Add to dashboard Cite

show abstract

Three-dimensional nonlinear coupling vibration of drill string in deepwater riserless drilling and its influence on wellbore pressure field

2023

View full text Add to dashboard Cite

Technical Investigation on Drill Pipe Failure

Inoue¹,

Wada²,

Osawa³

et al. 2017

J.JASNAOE

View full text Add to dashboard Cite

SummaryScientific drilling vessel Chikyu faced drill pipe failure during offshore commissioning of drilling control and instrumentation system upgrade work. The failure occurred with cyclic bending stress which was enough low to prevent fatigue failure according to S-N curve obtained from full-scale fatigue tests. Material tests and observation of a remaining part of the failed drill pipe, investigation of onboard data observed and measured during the operation, and fatigue analysis based on the material tests data and stress amplitude determined by both the onboard observation and the simulation of drill pipe motion are examined to investigate the cause of the failure. All three examinations provide that the number of cycles of bending stress to fail is in the order of 10 4 . The examinations also provide an evidence of cause of initiating cracks. This study presents the results of examinations and discusses the cause of drill pipe failure by verifying and complementing the results. It finally concludes that micro cracks were initiated owing to heat and stress, then cracks grew with cyclic stress, and it consequently reached to failure owing to the drill pipe motion including Magnus effect.

show abstract

Numerical Simulation of Motion of Rotating Drill Pipe due to Magnus Effect in Riserless Drilling

Cited by 3 publications

References 0 publications

Three-dimensional nonlinear coupling vibration of drill string in deepwater riserless drilling and its influence on wellbore pressure field

Three-dimensional nonlinear coupling vibration of drill string in deepwater riserless drilling and its influence on wellbore pressure field

Three-dimensional nonlinear coupling vibration of drill string in deepwater riserless drilling and its influence on wellbore pressure field

Technical Investigation on Drill Pipe Failure

Contact Info

Product

Resources

About