Dynamic Excitation of Monopiles by Steep and Breaking Waves: Experimental and Numerical Study

An experiment with a flexible pile subjected to steep and breaking irregular waves has been conducted. The pile was constructed to represent a monopile wind turbine at scale 1:80. Two point masses were mounted on the pile to achieve the right scaled values for the first and second natural frequency....

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Bibliographic Details
Published in:Volume 8: Ocean Renewable Energy
Main Authors: Bredmose, Henrik, Slabiak, Peter, Sahlberg-Nielsen, Lasse, Schlutter, Flemming
Format: Article in Journal/Newspaper
Language:English
Published: The American Society of Mechanical Engineers (ASME) 2013
Subjects:
Arctic
Online Access:https://orbit.dtu.dk/en/publications/41838d30-15b4-4108-b5c3-71a01cdc308b
https://doi.org/10.1115/OMAE2013-10948
Description
Summary:An experiment with a flexible pile subjected to steep and breaking irregular waves has been conducted. The pile was constructed to represent a monopile wind turbine at scale 1:80. Two point masses were mounted on the pile to achieve the right scaled values for the first and second natural frequency. Emphasis is given to the observed impulsive excitation of the natural modes by steep and breaking waves. Additionally, springing and ringing-type continuous forcing of the first natural mode is seen for the moderately steep waves. The experiments were carried out at three depths and with two wave climates. The measured data for structural acceleration is analysed with respect to individual wave parameters. It is found that the largest accelerations occur for breaking waves. The measured wave field and structural response are reproduced numerically with a fully nonlinear potential flow solver for the undisturbed wave kinematics, combined with a finite element model with Morison-based forcing. A good overall reproduction of the wave field and structural response is achieved for two selected episodes. For some of the waves, however, the numerical response magnitude does not match the observed excitations. Ongoing work is therefore an investigation of breaking wave load models and their implementation into the present numerical frame work. © 2013 by ASME.

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