Litcius/Paper detail

Influence of Bending Stiffness on Snap Loads in Marine Cables: A Study Using a High-Order Discontinuous Galerkin Method

Johannes Palm, Claes Eskilsson

2020Journal of Marine Science and Engineering21 citationsDOIOpen Access PDF

Abstract

Marine cables are primarily designed to support axial loads. The effect of bending stiffness on the cable response is therefore often neglected in numerical analysis. However, in low-tension applications such as umbilical modelling of ROVs or during slack events, the bending forces may affect the slack regime dynamics of the cable. In this paper, we present the implementation of bending stiffness as a rotation-free, nested local Discontinuous Galerkin (DG) method into an existing Lax–Friedrichs-type solver for cable dynamics based on an hp-adaptive DG method. Numerical verification shows exponential convergence of order P and P+1 for odd and even polynomial orders, respectively. Validation of a swinging cable shows good comparison with experimental data, and the importance of bending stiffness is demonstrated. Snap load events in a deep water tether are compared with field-test data. The bending forces affect the low-tension response for shorter lengths of tether (200–500 m), which results in an increasing snap load magnitude for increasing bending stiffness. It is shown that the nested LDG method works well for computing bending effects in marine cables.

Topics & Concepts

Galerkin methodStiffnessBending stiffnessStructural engineeringBendingSnapOrder (exchange)Materials scienceFinite element methodMechanicsEngineeringPhysicsComputer scienceEconomicsFinanceComputer graphics (images)Mechanical stress and fatigue analysisVibration and Dynamic AnalysisNumerical methods in engineering
Influence of Bending Stiffness on Snap Loads in Marine Cables: A Study Using a High-Order Discontinuous Galerkin Method | Litcius