Abstract
Monopiles able to support very large offshore wind turbines are slender structures susceptible to nonlinear resonant phenomena. With the aim to better understand and model the wave-loading on these structures in very steep waves where ringing occurs and the numerical wave-loading models tend to lose validity, this study investigates the distinct influences of nonlinearities in the wave kinematics and in the hydrodynamic loading models. Six wave kinematics from linear to fully nonlinear are modelled in combination with four hydrodynamic loading models from three theories, assessing the effects of both types of nonlinearities and the wave conditions where each type has stronger influence. The main findings include that the nonlinearities in the wave kinematics have stronger influence in the intermediate water depth, while the choice of the hydrodynamic loading model has larger influence in deep water. Moreover, finite-depth FNV theory captures the loading in the widest range of wave and cylinder conditions. The areas of worst prediction by the numerical models were found to be the largest steepness and wave numbers for second harmonic, as well as the vicinity of the wave-breaking limit, especially for the third harmonic. The main cause is the non-monotonic growth of the experimental loading with increasing steepness due to flow separation, which leads to increasing numerical overpredictions since the numerical wave-loading models increase monotonically.
Highlights
Wind has become a strong player in the energy field but its main limiting factor for growth, especially for offshore technologies, remains the cost
The higher-order force components associated with ringing have been observed to be much larger in shallower water than deep [6,7], reiterating the importance of its consideration in the shallow to intermediate water depths where monopile-supported offshore wind turbines (OWTs) are placed
The applicability of this dangerous resonant phenomenon to the OWT substructures is highlighted by the fact that the structural frequency of the monopile-supported offshore wind turbines falls in the range of 3rd harmonics of typical rough sea states occurring at sites where OWTs are placed
Summary
Wind has become a strong player in the energy field but its main limiting factor for growth, especially for offshore technologies, remains the cost. The higher-order force components associated with ringing have been observed to be much larger in shallower water than deep [6,7], reiterating the importance of its consideration in the shallow to intermediate water depths where monopile-supported OWTs are placed. The applicability of this dangerous resonant phenomenon to the OWT substructures is highlighted by the fact that the structural frequency of the monopile-supported offshore wind turbines falls in the range of 3rd harmonics of typical rough sea states occurring at sites where OWTs are placed
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
