Numerical Study of Mobilized Friction along Embedded Catenary Mooring Chains

Numerical Study of Mobilized Friction along Embedded Catenary Mooring Chains

AbstractUnderstanding the soil resistance along an embedded anchor chain is imperative for efficient and economic design of an overall mooring system as it determines the magnitude and direction of the load at the padeye of the anchor. The tensioning process of an embedded chain for catenary mooring...

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Bibliographic Details
Published in:Journal of geotechnical and geoenvironmental engineering Vol. 145; no. 10
Main Authors: Sun, C, Feng, X, Neubecker, S. R, Randolph, M. F, Bransby, M. F, Gourvenec, S
Format: Journal Article
Language:English
Published: New York American Society of Civil Engineers 01-10-2019
Subjects:
Anchors
Catenary
Chains
Coefficient of friction
Computer simulation
Deformation
Economics
Finite element method
Friction
Friction resistance
Mathematical analysis
Mathematical models
Mooring
Mooring systems
Normality
Ocean floor
Soil
Soil resistance
Soils
Technical Papers
Tension
Tensioning
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Summary:AbstractUnderstanding the soil resistance along an embedded anchor chain is imperative for efficient and economic design of an overall mooring system as it determines the magnitude and direction of the load at the padeye of the anchor. The tensioning process of an embedded chain for catenary moorings was modeled using a coupled Eulerian–Lagrangian (CEL) finite-element approach simulating the large deformations of the chain as it cuts through the soil to form an inverse catenary. The analyses reveal that the configuration of the embedded chain and the relationship between tension and chain angle at the padeye show excellent agreement with previously published analytical predictions. However, the ratio of the tension at the padeye to that at the mudline obtained from CEL is significantly higher than the theoretical values, mainly due to partial mobilization of the frictional soil resistance along the length of the chain. The CEL results indicate that the partial mobilization is a result of the combined-loading effect during failure of the soil around the embedded chain as it cuts through the seabed, in contrast with the conventional assumption that the ultimate frictional and normal soil resistances are mobilized simultaneously. A new design approach is proposed for calculating the local equivalent coefficient of friction based on the yield locus for a deeply embedded chain and the normality rule.
ISSN:1090-0241
1943-5606
DOI:10.1061/(ASCE)GT.1943-5606.0002154