Lateral Response of Large-Diameter Monopiles for Offshore Wind Turbines from Centrifuge Model Tests

With the development of offshore wind energy in China, more and more offshore wind turbines are being constructed in rock-based sea areas. However, the large diameter and thin-walled steel rock-socketed monopiles are very scarce at present, and both the construction and design are very difficult. For the design, the dynamic safety during the whole lifetime of the wind turbine is difficult to guarantee. Dynamic safety of a turbine is mostly controlled by the dynamic impedances of the rock-socketed monopile, which are still not well understood. How to choose the appropriate impedances of the socketed monopiles so that the wind turbines will neither resonant nor be too conservative is the main problem. Based on a numerical model in this study, the accurate impedances are obtained for different frequencies of excitation, different soil and rock parameters, and different rock-socketed lengths. The dynamic stiffness of monopile increases, while the radiative damping decreases as rock-socketed depth increases. When the weathering degree of rock increases, the dynamic stiffness of the monopile decreases, while the radiative damping increases.

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Deformation Analysis of Large Diameter Monopiles of Offshore Wind Turbines under Scour

Applied Sciences ◽

10.3390/app10217579 ◽

2020 ◽

Vol 10 (21) ◽

pp. 7579

Author(s):

Zhaoyao Wang ◽

Ruigeng Hu ◽

Hao Leng ◽

Hongjun Liu ◽

Yifan Bai ◽

...

Keyword(s):

Wind Turbines ◽

Wind Farm ◽

Large Diameter ◽

Horizontal Displacement ◽

Local Scour ◽

Offshore Wind ◽

Deformation Analysis ◽

Pile Head ◽

Offshore Wind Turbines ◽

Test Conditions

The displacement of monopile supporting offshore wind turbines needs to be strictly controlled, and the influence of local scour can not be ignored. Using p–y curves to simulate the pile–soil interaction and the finite difference method to calculate iteratively, a numerical frame for analysis of lateral loaded pile was discussed and then verified. On the basis of the field data from Dafeng Offshore Wind Farm in Jiangsu Province, the local scour characteristics of large diameter monopile were concluded, and a new method of considering scour effect applicable to large diameter monopile was put forward. The results show that, for scour of large diameter monopiles, there was no obvious scour pit, but local erosion and deposition. Under the test conditions, the displacement errors between the proposed and traditional method were 46.4%. By the proposed method, the p–y curves of monopile considering the scour effect were obtained through ABAQUS, and the deformation of large diameter monopile under scour was analyzed by the proposed frame. The results show that, with the increase of scour depth, the horizontal displacement of the pile head increases nonlinearly, the depth of rotation point moves downward, and both of the changes are related to the load level. Under the test conditions, the horizontal displacement of the pile head after scour could reach 1.4~3.6 times of that before scour. Finally, for different pile parameters, the pile head displacement was compared, and further, the susceptibility to scour was quantified by a proposed concept of scour sensitivity. The analysis indicates that increasing pile length is a more reasonable way than pile diameter and wall thickness to limit the scour effect on the displacement of large diameter pile.

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Insight into Failure Mechanism of Large-Diameter Monopile for Offshore Wind Turbines Subjected to Wave-Induced Loading

Journal of Coastal Research ◽

10.2112/si73-096.1 ◽

2015 ◽

Vol 73 ◽

pp. 554-558 ◽

Cited By ~ 1

Author(s):

Ke Wu ◽

Qinglai Fan ◽

Jing Zheng

Keyword(s):

Failure Mechanism ◽

Wind Turbines ◽

Large Diameter ◽

Offshore Wind ◽

Offshore Wind Turbines ◽

Wave Induced ◽

Insight Into

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Model Tests on the Long-Term Dynamic Performance of Offshore Wind Turbines Founded on Monopiles in Sand

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.4030682 ◽

2015 ◽

Vol 137 (4) ◽

Cited By ~ 18

Author(s):

Zhen Guo ◽

Luqing Yu ◽

Lizhong Wang ◽

S. Bhattacharya ◽

G. Nikitas ◽

...

Keyword(s):

Dynamic Response ◽

Wind Turbines ◽

Model Tests ◽

Offshore Wind ◽

Frequency Change ◽

Test Results ◽

Scaled Model ◽

Structural Dynamic ◽

Offshore Wind Turbines

The dynamic response of the supporting structure is critical for the in-service stability and safety of offshore wind turbines (OWTs). The aim of this paper is to first illustrate the complexity of environmental loads acting on an OWT and reveal the significance of its structural dynamic response for the OWT safety. Second, it is aimed to investigate the long-term performance of the OWT founded on a monopile in dense sand. Therefore, a series of well-scaled model tests have been carried out, in which an innovative balance gear system was proposed and used to apply different types of dynamic loadings on a model OWT. Test results indicated that the natural frequency of the OWT in sand would increase as the number of applied cyclic loading went up, but the increasing rate of the frequency gradually decreases with the strain accumulation of soil around the monopile. This kind of the frequency change of OWT is thought to be dependent on the way how the OWT is cyclically loaded and the shear strain level of soil in the area adjacent to the pile foundation. In this paper, all test results were plotted in a nondimensional manner in order to be scaled up to predict the consequences for prototype OWT in sandy seabed.

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Hybrid Model Tests for Floating Offshore Wind Turbines

ASME 2019 2nd International Offshore Wind Technical Conference ◽

10.1115/iowtc2019-7575 ◽

2019 ◽

Author(s):

Maxime Thys ◽

Alessandro Fontanella ◽

Federico Taruffi ◽

Marco Belloli ◽

Petter Andreas Berthelsen

Keyword(s):

Wind Tunnel ◽

Real Time ◽

Hybrid Model ◽

Wind Turbines ◽

Ocean Basin ◽

Model Testing ◽

Model Tests ◽

Offshore Wind ◽

Offshore Wind Turbines ◽

Floating Offshore Wind Turbines

Abstract Model testing of offshore structures has been standard practice over the years and is often recommended in guidelines and required in certification rules. The standard objectives for model testing are final concept verification, where it is recommended to model the system as closely as possible, and numerical code calibration. Model testing of floating offshore wind turbines is complex due to the response depending on the aero-hydro-servo-elastic system, but also due to difficulties to perform model tests in a hydrodynamic facility with correctly scaled hydrodynamic, aerodynamic and inertial loads. The main limitations are due to the Froude-Reynolds scaling incompatibility, and the wind generation. An approach to solve these issues is by use of hybrid testing where the system is divided in a numerical and a physical substructure, interacting in real-time with each other. Depending on the objectives of the model tests, parts of a physical model of a FOWT can then be placed in a wind tunnel or an ocean basin, where the rest of the system is simulated. In the EU H2020 LIFES50+ project, hybrid model tests were performed in the wind tunnel at Politecnico di Milano, as well as in the ocean basin at SINTEF Ocean. The model tests in the wind tunnel were performed with a physical wind turbine positioned on top of a 6DOF position-controlled actuator, while the hydrodynamic loads and the motions of the support structure were simulated in real-time. For the tests in the ocean basin, a physical floater with tower subject to waves and current was used, while the simulated rotor loads were applied on the model by use of a force actuation system. The tests in both facilities are compared and recommendations on how to combine testing methodologies in an optimal way are discussed.

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