Dynamic Response of Offshore Wind Turbine on 3×3 Barge Array Floating Platform under Extreme Sea Conditions

• Published in: China ocean engineering Vol. 35; no. 2; pp. 186 - 200
• Main Authors: Liu, Qing-song, Miao, Wei-pao, Yue, Min-nan, Li, Chun, Wang, Bo, Ding, Qingwei
• Format: Journal Article
• Language: English
• Published: Nanjing Chinese Ocean Engineering Society 01.04.2021; Springer Nature B.V
• Subjects: Aerodynamic loads; Algorithms; Arrays; Barges; Center of gravity; Coastal Sciences; Deep water; Degrees of freedom; Dynamic response; Engineering; Floating platforms; Fluid- and Aerodynamics; Gravity; Marine & Freshwater Sciences; Momentum; Mooring; Mooring systems; Numerical and Computational Physics; Oceanography; Offshore construction; Offshore energy sources; Offshore Engineering; Programming languages; Simulation; Turbine engines; Unsteady aerodynamics; Wind effects; Wind farms; Wind power; Wind power generation; Wind turbines; Work platforms; floating platform; dynamic response; Barge; extreme sea conditions; stability
• ISSN: 0890-5487; 2191-8945
• DOI: 10.1007/s13344-021-0017-0

Offshore wind farm construction is nowadays state of the art in the wind power generation technology. However, deep water areas with huge amount of wind energy require innovative floating platforms to arrange and install wind turbines in order to harness wind energy and generate electricity. The conventional floating offshore wind turbine system is typically in the state of force imbalance due to the unique sway characteristics caused by the unfixed foundation and the high center of gravity of the platform. Therefore, a floating wind farm for 3×3 barge array platforms with shared mooring system is presented here to increase stability for floating platform. The NREL 5 MW wind turbine and ITI Energy barge reference model is taken as a basis for this work. Furthermore, the unsteady aerodynamic load solution model of the floating wind turbine is established considering the tip loss, hub loss and dynamic stall correction based on the blade element momentum (BEM) theory. The second development of AQWA is realized by FORTRAN programming language, and aerodynamic — hydrodynamic — Mooring coupled dynamics model is established to realize the algorithm solution of the model. Finally, the 6 degrees of freedom (DOF) dynamic response of single barge platform and barge array under extreme sea condition considering the coupling effect of wind and wave were observed and investigated in detail. The research results validate the feasibility of establishing barge array floating wind farm, and provide theoretical basis for further research on new floating wind farm.