Volume 2: Safety and Reliability; Pipeline Technology 2003
DOI: 10.1115/omae2003-37219
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Minimum Wall Thickness Requirements for Ultra Deep-Water Pipelines

Abstract: The offshore pipeline industry is planning new gas trunklines at water depth ever reached before (up to 3500 m). In such conditions, external hydrostatic pressure becomes the dominating loading condition for the pipeline design. In particular, pipe geometric imperfections as the cross section ovality, combined load effects as axial and bending loads superimposed to the external pressure, material properties as compressive yield strength in the circumferential direction and across the wall thickness etc., signi… Show more

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Cited by 4 publications
(2 citation statements)
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“…An increase of wall thickness and sometimes yield strength is the obvious approach to improve the collapse capacity. Torselletti et al 4 state that collapse becomes the most critical design aspect in ultra-deep waters as there are limitations on how thick line pipes can be manufactured by the mills. Depending on the pipe diameters, there are also limitations on the tension capacity associated with different installation vessels in order to hold the weight of the submerged pipe string in the catenary.…”
Section: Challengesmentioning
confidence: 99%
“…An increase of wall thickness and sometimes yield strength is the obvious approach to improve the collapse capacity. Torselletti et al 4 state that collapse becomes the most critical design aspect in ultra-deep waters as there are limitations on how thick line pipes can be manufactured by the mills. Depending on the pipe diameters, there are also limitations on the tension capacity associated with different installation vessels in order to hold the weight of the submerged pipe string in the catenary.…”
Section: Challengesmentioning
confidence: 99%
“…The propagation buckling pressure was determined in the context of the tests performed on one pipe in each of the "as-received" and thermally treated states. The following equation can be found in DNV Offshore Standard OS-F101 [5], taking no account of additional safety margins: The fabrication factor α fab allows for the reduction in compressive yield strength frequently observed in the past in circumferential direction of pipes produced using UOE process [6], [7], [8]. Figure 14 shows a comparative assessment of calculated propagation buckling pressures and data obtained experimentally.…”
Section: Propagation Bucklingmentioning
confidence: 99%