Abstract
The dynamic characteristics of an offshore wind turbine with tripod suction buckets are investigated through finite element analysis and full-scale experiments. In finite element analysis, an integrated framework is suggested to create a simple yet accurate high fidelity model. The integrated framework accounts for not only the strain dependency of the soil but also for all dynamics in the seabed, including those of the soil, suction bucket skirt, and cap. Hence, the model accurately describes the coupling effect of translational and rotational motions of the seabed. The prediction results are compared to the experimental results obtained via full-scale testing in four stages during construction and in several operational conditions. The comparison shows that the stiffness of the suction bucket cap and strain dependency of the soil play a significant role in predicting natural frequency, suggesting that these two factors should be considered in finite element analysis for the accurate prediction of dynamic responses of an offshore wind conversion system. Moreover, dynamic analysis of the strain and acceleration measured during operational conditions shows that strain is more robust than acceleration with regard to the characterization of the overall dynamics of an offshore wind conversion system because the natural frequency of an offshore wind turbine is very low. It can be inferred that the measurement of strain is a more effective way to monitor the long-term evolution of dynamic characteristics. The suggested integrated framework and measurement campaign are useful not only to avoid conservatism that may incur additional costs during load calculation and design phases but also to establish an intelligent operation and maintenance strategy with a novel sensing technique.
Highlights
Renewable and sustainable energies are attractive alternatives for mitigating issues related to the consumption of fossil fuels, including the volatility of oil prices, emission of carbon dioxide, and aggravation of air quality due to fine dust emission
In 2018, 409 new offshore wind turbines were commissioned in Europe, which provided an additional capacity of 2,649 MW, and the cumulative capacity of wind farms was 18,499 MW [10]
The farther that a wind farm is from the shore, the deeper the water depth of its candidate site. e average water depth of European offshore wind farms under construction in 2018 is 27.1 m [10]. e long distance from the shore and deep water depth hinder the economic feasibility of wind farms
Summary
Renewable and sustainable energies are attractive alternatives for mitigating issues related to the consumption of fossil fuels, including the volatility of oil prices, emission of carbon dioxide, and aggravation of air quality due to fine dust emission. Us, it is essential to bridge the gap between theory and experiments as well as that between academic research and field applications and thereby mitigate concerns regarding uncertainty and increase prediction accuracy in the development phase of commercial offshore wind farms with multipod suction buckets. To this end, this study suggests a simple yet effective design procedure and its validation method. From the civil engineering perspective, a suction bucket was designed in detail to provide sufficient bearing capacity for a selected offshore wind turbine based on an actual soil investigation, including the cone penetration test (CPT) and standard penetration test (SPT). A comparison between predicted and experimental results suggests that several important features should be accounted for to accurately predict the dynamic responses of the OWCSs, including the stiffness of the cap of the suction bucket and strain dependency of the modulus of elasticity of the soil
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
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
