Best practice geotechnicai characterization and pipe-soil interaction analysis for HPHT pipeline design
Best practice geotechnicai characterization and pipe-soil interaction analysis for HPHT pipeline design
This paper summarizes best practice cost-effective geotechnicai design of high pressure high temperature (HPHT) pipelines, with an emphasis on HPHT lines in deep water, that are susceptible to lateral buckling and axial walking. It presents guidance on (i) tools for optimal geotechnicai characterization of shallow seabed conditions along flowline routes and (ii) techniques to assess pipe-soil interaction parameters for input to pipeline structural modeling. Recent research into pipe-soil interaction measurement tools and analysis techniques has resulted in rapid advancements that are being quickly utilized in practice. Advanced pipe-soil interaction techniques, firmly rooted in soil mechanics theory and linked to the operational sequence of the pipeline through cycles of start-up and shut-down, are presented. They are used to demonstrate benefits that can be realized on typical projects to reduce pipeline walking predictions and the associated mitigation measures such as hold-back anchors. Recommendations cover the appropriate selection of characterization tools and analysis techniques based on project-specific requirements such as seabed geotechnicai complexity, pipeline operating conditions, project timing, mitigation strategies for global stability and the desired approach to risk management and use of the observational method. The results, observations and conclusions presented in this paper represent the culmination of several years of research and development in pipe-soil interaction, as well as our experience on recent projects around the world where these techniques have been employed. The paper offers recommendations to guide both geotechnicai studies and pipeline engineering work, and unlock benefits from maintaining close integration of these two disciplines through the design and operation of a pipeline.
4235-4258
Offshore Technology Conference
White, D.J.
a986033d-d26d-4419-a3f3-20dc54efce93
Westgate, Z.J.
983a044b-1644-4a5c-895d-6b7c83501ab9
Ballard, J.C.
23ea4838-f0d1-4401-a886-5925951d4754
De Brier, C.
6054ba22-2586-4ed5-9c4e-abf6c8392140
Bransby, M.F.
89f400b2-6f20-4b5c-b163-965df69b1f02
June 2015
White, D.J.
a986033d-d26d-4419-a3f3-20dc54efce93
Westgate, Z.J.
983a044b-1644-4a5c-895d-6b7c83501ab9
Ballard, J.C.
23ea4838-f0d1-4401-a886-5925951d4754
De Brier, C.
6054ba22-2586-4ed5-9c4e-abf6c8392140
Bransby, M.F.
89f400b2-6f20-4b5c-b163-965df69b1f02
White, D.J., Westgate, Z.J., Ballard, J.C., De Brier, C. and Bransby, M.F.
(2015)
Best practice geotechnicai characterization and pipe-soil interaction analysis for HPHT pipeline design.
In Offshore Technology Conference 2015, OTC 2015.
vol. 6,
Offshore Technology Conference.
.
Record type:
Conference or Workshop Item
(Paper)
Abstract
This paper summarizes best practice cost-effective geotechnicai design of high pressure high temperature (HPHT) pipelines, with an emphasis on HPHT lines in deep water, that are susceptible to lateral buckling and axial walking. It presents guidance on (i) tools for optimal geotechnicai characterization of shallow seabed conditions along flowline routes and (ii) techniques to assess pipe-soil interaction parameters for input to pipeline structural modeling. Recent research into pipe-soil interaction measurement tools and analysis techniques has resulted in rapid advancements that are being quickly utilized in practice. Advanced pipe-soil interaction techniques, firmly rooted in soil mechanics theory and linked to the operational sequence of the pipeline through cycles of start-up and shut-down, are presented. They are used to demonstrate benefits that can be realized on typical projects to reduce pipeline walking predictions and the associated mitigation measures such as hold-back anchors. Recommendations cover the appropriate selection of characterization tools and analysis techniques based on project-specific requirements such as seabed geotechnicai complexity, pipeline operating conditions, project timing, mitigation strategies for global stability and the desired approach to risk management and use of the observational method. The results, observations and conclusions presented in this paper represent the culmination of several years of research and development in pipe-soil interaction, as well as our experience on recent projects around the world where these techniques have been employed. The paper offers recommendations to guide both geotechnicai studies and pipeline engineering work, and unlock benefits from maintaining close integration of these two disciplines through the design and operation of a pipeline.
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Published date: June 2015
Venue - Dates:
Offshore Technology Conference 2015, OTC 2015, , Houston, United States, 2015-05-04 - 2015-05-07
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Local EPrints ID: 419769
URI: http://eprints.soton.ac.uk/id/eprint/419769
PURE UUID: e2c205f6-f172-437b-a627-aa588a1a7ec1
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Date deposited: 20 Apr 2018 16:30
Last modified: 06 Mar 2024 02:56
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Contributors
Author:
Z.J. Westgate
Author:
J.C. Ballard
Author:
C. De Brier
Author:
M.F. Bransby
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