Journal
GEOTECHNIQUE
Volume 71, Issue 3, Pages 189-204Publisher
ICE PUBLISHING
DOI: 10.1680/jgeot.18.P.133
Keywords
bearing capacity; discrete-element modelling; pipes & pipelines; soil/structure interaction
Categories
Funding
- Engineering and Physical Sciences Research Council (EPSRC)
- EU H2020 RISE Hercules grant [778360]
- BP
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Realistic modelling of transverse pipe-soil interaction is crucial for predicting the behavior of untrenched offshore pipelines. This paper uses the DEM method to study the behavior of a partially embedded pipe segment in sand, providing quantitative predictions of vertical and horizontal forces, displacement trajectory, and qualitative insights into soil failure mechanisms.
Realistic modelling of transverse (i.e. vertical and lateral) pipe-soil interaction plays an important role in predicting the behaviour of untrenched offshore pipelines that are designed to undergo controlled lateral buckling. The large plastic soil deformations and surface geometry changes that occur during this process mean that numerical analyses using the continuum-based finite-element method are difficult and computationally expensive. Furthermore, most previous research in this area has focused on undrained deformation of soft clay seabed soils. This paper uses the three-dimensional distinct-element method (DEM) to investigate the behaviour of a pipe segment that is partially embedded in sand. The simulation approach is validated against experimental results for a monotonic vertical penetration test, a monotonic sideswipe test, and a cyclic lateral loading test performed under constant vertical load. Other DEM analyses are performed to illustrate the growth, deposition and collection of soil berms, and to investigate the effect of varying the initial vertical overloading ratio and the pipe weight. The DEM simulations provide quantitative predictions of the vertical and horizontal forces acting on the pipe segment, and of the pipe displacement trajectory. Valuable qualitative insights into soil failure mechanisms occurring at a grain level are also obtained.
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