Tahiti Flowline Expansion Control System

Thompson, Hugh; Reiners, Jim; Brunner, Mark; DeLack, Kristen; Qui, Xinhai; Noel, Clyde

doi:10.4043/19858-ms

“…A few projects have now installed pipeline anchors, for example the Tahiti Development [9] where the vertical stab and hinge-over method was employed to connect PLETS to suction anchor piles with capacities of up to 180 tonnes. Another example is the Greater Plutonio Development [6] where all three Southern Production flowlines were anchored at one end to prevent walking using suction anchors with capacities of up to 100 tonnes.…”

Section: Walking Mitigationmentioning

confidence: 99%

Lessons Learned From Observing Walking of Pipelines with Lateral Buckles, Including New Driving Mechanisms and Updated Analysis Models

Bruton

¹

,

Carr

²

,

Sinclair

³

et al. 2010

View full text Add to dashboard Cite

This paper was selected for presentation by an OTC program committee following revi ew of information contained in an abstract submitted by the author(s). Contents of the paper have not been reviewed by the Offshore Technology Conference and are subject to correction by the author(s). The material does not necessar ily reflect any position of the Offshore Technology Conference, its officers, or members. Electronic reproduction, distribution, or storage of any part of this paper without the written consent of the Offshore Technology Conference is prohibited. Permission to reproduce in print is restricted to an abstract of not more than 300 words; illustrations may not be copied. The abstract must contain conspicuo us acknowledgment of OTC copyright. AbstractPipeline walking is a phenomenon that causes global axial movement of a whole pipeline. Pipeline walking has been observed on a number of pipelines to date and if left uncontrolled can lead to potential failures at connections or risers.Designing to control or mitigate pipeline walking can result in significant changes to field layouts and high installation costs associated with pipeline anchors, which have been installed on a number of recent developments. It is therefore essential to be able to assess whether walking is a potential issue early in the design process.Walking is a stepwise ratcheting mechanism that occurs during changes in operating conditions, particularly during shutdown and restart operations. A number of contributory mechanisms are known to cause pipeline walking:  Sustained tension, applied to the end of a pipeline by a steel catenary riser (SCR);  Seabed slopes, along the pipe length, defined by route bathymetry;  Thermal transients, defined by changes in fluid temperature and thermal loading during shutdown and restart operations;  Multiphase flow behavior during shutdown and restart operations.This last multiphase flow mechanism has only recently been identified from observation and measurement of operating systems and is not addressed by previously published analytic pipeline walking models developed by the SAFEBUCK JIP, published at OTC in 2006 [1] . This fourth mechanism is described along with a discussion on the impact of multiphase flow on pipeline walking, axial friction response, anchor loading and route curve stability. A new analytic model i is presented to assess pipeline-walking rates due to this behavior. This paper also illustrates pipeline-anchoring solutions that have been employed to control pipeline walking on a number of deepwater developments and discusses the issues with these control methods, including the increased potential for route-curve pullout. The paper also investigates the complex interaction between pipeline walking and lateral buckling. It is known that lateral buckles along a pipeline can significantly influence both pipeline walking and end expansion predictions. The complex cyclic interaction is explained and methods for predicting the cyclic response either analytically, or using FEA techniques, a...

show abstract

“…More detailed information about the field and the riser systems can be found in References [1], and [2], respectively. Steel Catenary Risers (SCRs) have a proven track record and have been successfully installed in water depth of up to 8,000 feet.…”

Section: Introductionmentioning

confidence: 99%

“…For flowlines below a critical length, the expansion can lead to buckling and possible failure. To accommodate sizeable expansions and contractions of high temperature high pressure flowlines during start up and shut down, buckling is initiated at controlled locations[2]. On Tahiti flowlines this controlled buckling zone is introduced through installation of the buoyancy modules at two locations along the flowline.…”

mentioning

confidence: 99%

Tahiti Online Monitoring System for Steel Catenary Risers and Flowlines

Karayaka

¹

,

Chen

²

,

Blankenshipp

³

et al. 2009

Proceedings of Offshore Technology Conference

0

View full text Add to dashboard Cite

The Riser and Flowline Monitoring (RFM) project deployed one of the most comprehensive subsea structural monitoring systems to date on a Tahiti infield (production) Steel Catenary Riser (SCR) and associated flowline. State-of-the-art motion and strain measurement devices are optimally placed along the SCR to continuously measure and store real-time full scale riser response. In addition, RFM project is the first to implement monitoring devices on a flowline to measure the flowline buckling, a phenomenon that is predicted during repeated start up/shut down. The project goals are two-fold:1. Understand fundamental hydrodynamic behavior of SCRs and flowlines, specifically, floater motion induced response of catenary risers, Vortex Induced Vibration of catenary risers, riser behavior at the pull tube exit region, riser-soil interaction at the touchdown region, flowline buckling, flowline axial walking, and flow assurance characteristics of infield flowlines. The information generated will be used in future riser designs.2. The information will be used to validate Tahiti riser and flowline system robustness and conduct "health checks" on the fatigue critical risers and flowlines, particularly after significant environmental or operational events. This paper describes the monitoring system configuration, the technology deployed, and the installation methods.

show abstract

“…More detailed information about the field and the riser systems can be found in References [1], and [2], respectively. More detailed information about the field and the riser systems can be found in References [1], and [2], respectively.…”

Section: Introductionmentioning

confidence: 99%

“…To accommodate sizeable expansions and contractions of high temperature high pressure flowlines during start up and shut down, buckling is initiated at controlled locations[2]. For flowlines below a critical length, the expansion can lead to buckling and possible failure.…”

mentioning

confidence: 99%

SS: Tahiti On-Line Monitoring System for Steel Catenary Risers and Flowlines

Karayaka

¹

,

Chen

²

,

Blankenshipp

³

et al. 2009

View full text Add to dashboard Cite

The Riser and Flowline Monitoring (RFM) project deployed one of the most comprehensive subsea structural monitoring systems to date on a Tahiti infield (production) Steel Catenary Riser (SCR) and associated flowline. State-of-the-art motion and strain measurement devices are optimally placed along the SCR to continuously measure and store real-time full scale riser response. In addition, RFM project is the first to implement monitoring devices on a flowline to measure the flowline buckling, a phenomenon that is predicted during repeated start up/shut down. The project goals are two-fold:1. Understand fundamental hydrodynamic behavior of SCRs and flowlines, specifically, floater motion induced response of catenary risers, Vortex Induced Vibration of catenary risers, riser behavior at the pull tube exit region, riser-soil interaction at the touchdown region, flowline buckling, flowline axial walking, and flow assurance characteristics of infield flowlines. The information generated will be used in future riser designs.2. The information will be used to validate Tahiti riser and flowline system robustness and conduct "health checks" on the fatigue critical risers and flowlines, particularly after significant environmental or operational events. This paper describes the monitoring system configuration, the technology deployed, and the installation methods.

show abstract

Tahiti Flowline Expansion Control System

Cited by 8 publications

References 0 publications

Lessons Learned From Observing Walking of Pipelines with Lateral Buckles, Including New Driving Mechanisms and Updated Analysis Models

Lessons Learned From Observing Walking of Pipelines with Lateral Buckles, Including New Driving Mechanisms and Updated Analysis Models

Tahiti Online Monitoring System for Steel Catenary Risers and Flowlines

SS: Tahiti On-Line Monitoring System for Steel Catenary Risers and Flowlines

Contact Info

Product

Resources

About