Theoretical framework for predicting the response of tolerably mobile subsea installations
Theoretical framework for predicting the response of tolerably mobile subsea installations
Tolerable mobility of subsea foundations and pipelines supporting offshore oil and gas developments has recently become an accepted design concept. It enables a smaller foundation footprint and so is a potential cost-saving alternative to conventionally engineered ‘fixed’ seabed foundations. Dominant sources of loading on subsea infrastructure arise from connection misalignment or thermal and pressure-induced expansion, and these are reduced if the structure is permitted to displace while ensuring that additional loading is not induced by excessive settlements. A sound prediction of the resulting sliding response will provide a robust design basis for mobile subsea infrastructure. This paper presents a theoretical model based on critical state soil mechanics to predict the performance of a subsea installation that is founded on soft, normally consolidated or lightly overconsolidated soil, and subjected to intermittent horizontal sliding movements. The framework is validated against centrifuge test results and is shown to capture the essential elements of the soil–structure interaction, which include: (a) the changing soil strength from cycles of sliding and pore pressure generation; (b) the regain in strength due to dissipation of excess pore pressure (consolidation); and (c) the soil contraction and consequent settlement of the foundation caused by the consolidation process.
consolidation, footings/foundations, offshore engineering, theoretical analysis
608-620
Cocjin, M.L.
42ee9efc-8d8a-4330-ae75-00665def8fd3
Gourvenec, S.M.
6ff91ad8-1a91-42fe-a3f4-1b5d6f5ce0b8
White, D.J.
a986033d-d26d-4419-a3f3-20dc54efce93
Randolph, M.F.
75caa33a-e630-4ae8-84cd-758797bf9633
1 July 2017
Cocjin, M.L.
42ee9efc-8d8a-4330-ae75-00665def8fd3
Gourvenec, S.M.
6ff91ad8-1a91-42fe-a3f4-1b5d6f5ce0b8
White, D.J.
a986033d-d26d-4419-a3f3-20dc54efce93
Randolph, M.F.
75caa33a-e630-4ae8-84cd-758797bf9633
Cocjin, M.L., Gourvenec, S.M., White, D.J. and Randolph, M.F.
(2017)
Theoretical framework for predicting the response of tolerably mobile subsea installations.
Geotechnique, 67 (7), .
(doi:10.1680/jgeot.16.P.137).
Abstract
Tolerable mobility of subsea foundations and pipelines supporting offshore oil and gas developments has recently become an accepted design concept. It enables a smaller foundation footprint and so is a potential cost-saving alternative to conventionally engineered ‘fixed’ seabed foundations. Dominant sources of loading on subsea infrastructure arise from connection misalignment or thermal and pressure-induced expansion, and these are reduced if the structure is permitted to displace while ensuring that additional loading is not induced by excessive settlements. A sound prediction of the resulting sliding response will provide a robust design basis for mobile subsea infrastructure. This paper presents a theoretical model based on critical state soil mechanics to predict the performance of a subsea installation that is founded on soft, normally consolidated or lightly overconsolidated soil, and subjected to intermittent horizontal sliding movements. The framework is validated against centrifuge test results and is shown to capture the essential elements of the soil–structure interaction, which include: (a) the changing soil strength from cycles of sliding and pore pressure generation; (b) the regain in strength due to dissipation of excess pore pressure (consolidation); and (c) the soil contraction and consequent settlement of the foundation caused by the consolidation process.
Text
2017 Geotechnique 67_7_608-620 Cocjin et al.
- Accepted Manuscript
More information
Accepted/In Press date: 8 December 2016
e-pub ahead of print date: 14 June 2017
Published date: 1 July 2017
Keywords:
consolidation, footings/foundations, offshore engineering, theoretical analysis
Identifiers
Local EPrints ID: 414829
URI: http://eprints.soton.ac.uk/id/eprint/414829
ISSN: 0016-8505
PURE UUID: a384ddee-74cb-4225-8b2b-80b0d77517e6
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Date deposited: 11 Oct 2017 16:31
Last modified: 16 Mar 2024 04:31
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Author:
M.L. Cocjin
Author:
M.F. Randolph
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