Abstract
As offshore wind turbines move towards deeper and more distant sites, the concept of floating foundations is a potential technically and economically attractive alternative to the traditional fixed foundations. Unlike the well-studied monopile, the geometry of a floating foundation is complex and, thereby, increases the difficulty in wave force determination due to limitations of the commonly used simplified methods. This paper deals with a physical model test of the hydrodynamic excitation force in surge on a fixed three-columned structure intended as a floating foundation for offshore wind turbines. The experiments were conducted in a wave basin at Aalborg University. The test results are compared with a Boundary Element Method code based on linear diffraction theory for different wave force regimes defined by the column diameter, wave heights and lengths. Furthermore, the study investigates the influence of incident wave direction and stabilizing heave-plates. The structure can be divided into primary, secondary and tertiary parts, defined by the columns, heave-plates and braces to determine the excitation force in surge. The test results are in good agreement with the numerical computation for the primary parts only, which leads to simplified determination of peak frequencies and corresponding dominant force regime.
Highlights
One of the most well-known and currently preferred renewable energy sources is wind power.The wind power resource is on average 50% higher offshore than onshore; the cost to install and run offshore wind power units is around double [1]
The test results are in good agreement with the numerical computation for the primary parts only, which leads to simplified determination of peak frequencies and corresponding dominant force regime
Studies have shown that the traditional fixed foundations will not be economically viable for offshore wind turbines in waters deeper than 30 m [2], which is why the concept of a floating foundation is a promising alternative
Summary
The wind power resource is on average 50% higher offshore than onshore; the cost to install and run offshore wind power units is around double [1]. This has raised the challenge of optimizing the economical perspectives of offshore wind power. Studies have shown that the traditional fixed foundations will not be economically viable for offshore wind turbines in waters deeper than 30 m [2], which is why the concept of a floating foundation is a promising alternative. Four main concept types have been developed: semi-submersible, TLP, spar buoy and barge [3]. This paper will focus on the conceptual semi-submersible prototype, see Figure 1
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