Lateral Global Buckling of Submarine Pipelines Based on the Model of Nonlinear Pipe–Soil Interaction

With the increasing development and utilization of offshore oil and gas resources, global buckling failures of pipelines subjected to high temperature and high pressure are becoming increasingly important. For unburied or semi-buried submarine pipelines, lateral global buckling represents the main f...

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Bibliographic Details
Published in:China ocean engineering 2018-06, Vol.32 (3), p.312-322
Main Authors: Liu, Run, Wang, Xiu-yan
Format: Article
Language:English
Subjects:
Arches
Buckling
Buried pipes
Coastal Sciences
Computer simulation
Deformation
Engineering
Failures
Fluid- and Aerodynamics
Gas pipelines
High pressure
High temperature
Interaction models
Interactions
Marine & Freshwater Sciences
Mathematical models
Natural gas
Numerical and Computational Physics
Oceanography
Offshore
Offshore drilling rigs
Offshore Engineering
Petroleum pipelines
Photosystem I
Pipelines
Simulation
Soil
Soil resistance
Soil-structure interaction
Soils
Stress analysis
Stress concentration
Stress distribution
Submarine pipelines
Temperature differences
Temperature gradients
Underwater pipelines
Underwater structures
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Summary:With the increasing development and utilization of offshore oil and gas resources, global buckling failures of pipelines subjected to high temperature and high pressure are becoming increasingly important. For unburied or semi-buried submarine pipelines, lateral global buckling represents the main form of global buckling. The pipe–soil interaction determines the deformation and stress distribution of buckling pipelines. In this paper, the nonlinear pipe–soil interaction model is introduced into the analysis of pipeline lateral global buckling, a coupling method of PSI elements and the modified RIKS algorithm is proposed to study the lateral global buckling of a pipeline, and the buckling characteristics of submarine pipeline with a single arch symmetric initial imperfection under different pipe–soil interaction models are studied. Research shows that, compared with the ideal elastic–plastic pipe–soil interaction model, when the DNV-RP-F109 model is adopted to simulate the lateral pipe–soil interactions in the lateral global buckling of a pipeline, the buckling amplitude increases, however, the critical buckling force and the initial buckling temperature difference decreases. In the DNV-RP-F109 pipe–soil interaction model, the maximum soil resistance, the residual soil resistance, and the displacement to reach the maximum soil resistance have significant effects on the analysis results of pipeline global buckling.
ISSN:0890-5487
2191-8945
DOI:10.1007/s13344-018-0032-y