Seismic soil-monopile-structure interaction for offshore wind turbines
from 3D to 1D modelling
D. Delavinia (GR8 GEO)
Evangelos Kementzetzidis (TU Delft - Offshore Engineering)
S. Panagoulias (Siemens Gamesa Renewable Energy, TU Delft - Offshore Engineering)
A. Tsouvalas (TU Delft - Dynamics of Structures, TU Delft - Offshore Engineering)
Federico Pisano (TU Delft - Geo-engineering)
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Abstract
To accommodate the foreseen expansion of the offshore wind sector, monopile-supported Offshore Wind Turbines (OWTs) are currently being designed for harvesting offshore wind energy in seismically active regions. Three-dimensional (3D) Finite Element (FE) analyses have proven a reliable, though computationally expensive, tool for modelling laterally loaded monopiles. A more efficient modelling approach is the one-dimensional (1D) Beam-on-Winkler-Foundation (BWF) method, where the monopile is modelled via a series of beam elements, laterally supported by uncoupled, lateral soil springs. Under the simplifying assumption of linear elastic soil behaviour, this study explores the suitability of the BWF method for the simulation of the seismic soil-structure interaction by comparing the response obtained through 1D modelling to the outcome of 3D FE calculations. To this end, different monopile geometries are examined, for which the contributions of multiple soil resisting mechanisms (determined by normal and tangential stresses along the pile shaft and base) to the global monopile response are also assessed.