Abstract
The majority of wind turbine foundations consist of hollow monopiles inserted in the soil, requiring high computational effort to be numerically simulated. Alternative simplified models are very often employed instead. Three-dimensional solid models, in which the hollow structure and pile are substituted by solid cylinders with equivalent properties, are the most extended simplifications. Very few 2D models can be found in the literature due to the challenge of finding suitable equivalent properties and loads to fully represent the 3D nature of the problem. So far, very limited attention has been devoted to the accuracy of both 3D and 2D simplified models under dynamic and even static actions. Thus, in this paper, simplified 3D and 2D solid models are proposed and justified. An elasto-plastic constitutive model with accumulative degradation is used to simulate the soil behaviour, and frictional contact elements are implemented between the soil and pile to model their interaction. These simplified approaches are compared with the full 3D hollow model, under static and cyclic loads. The results demonstrate that the proposed simplified approaches are a reasonable alternative to the 3D hollow model, which allows researchers and designers to drastically reduce the computational effort in the simulations under long term conditions.
Highlights
Due to the depletion of fossil-fuel-based energy resources and the need to minimise climate change, renewable energies are rapidly developing nowadays, as a feasible and sustainable alternative to provide energy for the world
This paper presents the derivation of two simplified numerical models, aiming at accurately replicating the response of a hollow wind turbine foundation to reduce the computational efforts for long term simulations
The first simplified model consists of a 3D solid structure and pile, while the second one is a 2D model which represents the central vertical section of the geometry
Summary
Due to the depletion of fossil-fuel-based energy resources and the need to minimise climate change, renewable energies are rapidly developing nowadays, as a feasible and sustainable alternative to provide energy for the world. The dynamic behaviour of offshore wind turbines is more complicated than in onshore wind farms and more than in offshore oil and gas industry platforms This is due to the combination of constant movement of the turbine blades, the persistent winds and the action of sea waves, which can reach several meters high under extreme storm conditions. These forces pose new challenges for turbine foundation design due to the high ratio between lateral and vertical loads. The first modal frequencies of these infrastructures are often very close to those of the excitation loads, and long-term changes in soil stiffness can significantly contribute to increasing the risk of resonance [3]
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