Next Generation Drill Pipe for Extended Reach, Deepwater and Ultra-deep Drilling

Jellison, Michael J.; Payne, M.L.; Shepard, Jeff; Chandler, R. Brett

doi:10.4043/15327-ms

Cited by 10 publications

(3 citation statements)

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“…drill pipe that has significantly improved drilling performance for extended reach drilling, deep water and other deep well applications. (5),(6), (7), (8) The technology also resulted in ultrahigh performance 4 in. drill pipe with streamline connections capable of replacing conventional 3-1/2 in.…”

Section: Evolution Of Double-shoulder Connectionsmentioning

confidence: 99%

Drill Faster, Deeper, and Further With Ultrahigh-Torque, Third-Generation Double-Shoulder Connections

Chandler¹,

Muradov²,

Jellison³

et al. 2007

Proceedings of SPE/IADC Drilling Conference

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TX 75083-3836 U.S.A., fax 1.972.952.9435. AbstractNew developments in drilling tubulars are rapidly evolving and represent enabling technologies for the industry's continued advancement of drilling deeper, further and more cost-effective wells. Much focus has been made toward the advancement of drill pipe connection technology to permit high torque drilling of extended reach, directional and horizontal wells. First and second generation high torque connections have been available to the industry for several years.In today's rig market; deepwater, extended reach and ultradeep wells dictate large spread rates that can benefit significantly from reduced tripping times. These same wells often have mechanical and hydraulic load requirements for which today's high torque connections may not be specifically optimized.In response to this need, the development of third generation, ultra-high torque connections is now complete. This paper will present the results of a 2-1/2 year comprehensive effort to design, test, manufacture and field trial a family of connections that were engineered to meet the specific needs of each drill pipe size. Results from extensive laboratory tests and two field trial programs designed to produce harsh, aggressive dynamic loads to the connections are presented.The thread form is a double-start thread that reduces the number of revolutions to assemble the connection by 50%. The thread form also provides a unique dual-radius thread root that offers a step change improvement in fatigue resistance. Conservative estimates suggest that the new connections will save approximately 7-1/2 hours in planned trip time per 20,000 ft well. The new connections provide increased mechanical and hydraulic performance compared to second generation high torque connections while also providing fatigue performance greater than standard API connections.These connections can facilitate more challenging wells, provide increased cost savings and reduce risk during the well construction process.

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Section: Evolution Of Double-shoulder Connectionsmentioning

confidence: 99%

Drill Faster, Deeper, and Further With Ultrahigh-Torque, Third-Generation Double-Shoulder Connections

Chandler¹,

Muradov²,

Jellison³

et al. 2007

Proceedings of SPE/IADC Drilling Conference

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show abstract

“…In the hand-tight position the primary external shoulder makes contact. 5 As the connection is made-up from the hand-tight to power-tight position the secondary torque stop engages. The secondary torque shoulder provides the increased torsional capacity compared to a standard API rotary shoulder connection.…”

Section: Tool Jointsmentioning

confidence: 99%

High Performance, Slim-hole Drilling with 4 in. Drill Pipe and a Streamline Connection

Plessis¹,

Andre²,

Pasnak³

et al. 2004

Proceedings of IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

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fax 01-972-952-9435. AbstractBoth Saudi Aramco and Total Indonesia found benefits in selecting 4 in. drill pipe with streamlined double shoulder connections for the drilling of wells, for which the 3 ½ in. drill pipe was unsuitable. Although dealing with different environments and applications, these benefits can be summarized in "successfully drilling longer slim holes with a drill string having enhanced torsional, tensile and hydraulic characteristics at a lower overall cost". design provides 22,000 ft-lb working torque, an outside diameter of 4-7/8 in. and an oversized internal bore that promotes hydraulic efficiency.Other important improvements include considerable gain in pipe resistance under buckling loads, increased available pressure at the bit, better telemetry for the MWD and LWD tools and improved hole cleaning and rate of penetration.

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“…An approach to the design of deepwater riserless landing strings was proposed by Adams [23], which focuses on the selection of pipe joints and tool joints. e design, manufacture, testing, and operation of landing strings have also been discussed by Breihan et al [24], Jellison et al [25], and Cantrell et al [26]. However, in these studies, dynamic analysis did not get enough attention.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear Dynamic Characteristic Analysis of a Landing String in Deepwater Riserless Drilling

Zhao

Yang

et al. 2018

Shock and Vibration

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The landing string is an important component of deepwater riserless drilling systems. Determination of the dynamic characteristics of the landing string plays an essential role in its design for ensuring its safe operation. In this paper, a dynamic model is developed to investigate the dynamic response characteristics of a landing string, where a landing string in a marine environment is modeled as a flexible slender tube undergoing coupled transverse and axial motions. The heaving motion of the drilling platform is taken as the upper boundary condition and the motion of the drilling bit caused by the interaction between the rock and the bit as the lower boundary condition. A semiempirical Morison equation is used to simulate the effect of the load imposed by the marine environment. The dynamic model, which is nonlinearly coupled and multibody, is discretized by a finite element method and solved by the Newmark technique. Using the proposed model, the dynamic responses of the displacement, axial force, and moment in the landing string are investigated in detail to find out the influences of driving depth of surface catheter, platform motion, bit movement, and marine environment on the dynamical characteristics of the landing string.

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Next Generation Drill Pipe for Extended Reach, Deepwater and Ultra-deep Drilling

Cited by 10 publications

References 0 publications

Drill Faster, Deeper, and Further With Ultrahigh-Torque, Third-Generation Double-Shoulder Connections

Drill Faster, Deeper, and Further With Ultrahigh-Torque, Third-Generation Double-Shoulder Connections

High Performance, Slim-hole Drilling with 4 in. Drill Pipe and a Streamline Connection

Nonlinear Dynamic Characteristic Analysis of a Landing String in Deepwater Riserless Drilling

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