Aerodynamic Performance and Wind-Induced Responses of Large Wind Turbine Systems with Meso-Scale Typhoon Effects

Ke, Shitang; Lu, Xu; Wang, Tongguang

doi:10.3390/en12193696

Cited by 4 publications

(2 citation statements)

References 19 publications

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“…To accurately predict the aerodynamic load on a wind turbine blade, it is necessary to combine the micro-scale CFD method with a mesoscale model and to nest a small-scale wind field in the wind field model. Ke et al [40] proposed to use the WRF model to simulate typhoon "Nuri" and fit the near-surface wind profile. A CFD model was used to simulate the flow field around the wind turbine to analyze the aerodynamic response of the wind turbine with a typhoon load.…”

Section: Simulation Of Typhoon Aerodynamic Loadmentioning

confidence: 99%

Typhoon Resistance Analysis of Offshore Wind Turbines: A Review

Jiang

et al. 2022

Atmosphere

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A typhoon is a tropical cyclone in the western Pacific Ocean and the China seas. Typhoons are some of the most destructive natural disasters on Earth. In China, typhoons have had major impacts on the stability and structural integrity of offshore wind turbines in the complex and harsh marine environment. In this research, first, the main causes of wind turbine damage were analyzed based on the characteristics of a typhoon and a wind turbine structure for typical typhoon-induced accidents. Second, the research progress of the anti-typhoon design of offshore wind turbines and the anti-typhoon strategy of wind farms operation and maintenance was summarized. Finally, the problems to be further solved in these research fields were presented to provide references for the development of offshore wind turbines, in particular, floating wind turbines in typhoon-prone areas.

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Section: Simulation Of Typhoon Aerodynamic Loadmentioning

confidence: 99%

Typhoon Resistance Analysis of Offshore Wind Turbines: A Review

Jiang

et al. 2022

Atmosphere

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“…The idea of using the combination of meso-scale W-S-F coupling model and micro-scale CFD model not only assures high-precision simulation of the typhoonwave-current coupling field, but also protects the accurate solving of near-surface loads of wind turbine. It is a relatively ideal meso-micro scale model nesting structure for downscaling simulation of offshore wind turbine (Ke et al, 2018(Ke et al, , 2019.…”

Section: Introductionmentioning

confidence: 99%

Research on hydrodynamics of foundation structure of offshore wind turbine under typhoon-wave-current coupling

Wang

Zhao

et al. 2022

Advances in Structural Engineering

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Offshore wind turbine is facing with extremely complicated climatic environment. The accurate prediction of wave movement caused by strong typhoons and its action on foundation of wind turbine are crucial. To disclose hydrodynamic characteristics of foundation structure of wind turbine under typhoon-wave-current coupling effect on the sea, a 10 MW super-large offshore wind turbine in Wailuo Wind Farm, Guangdong was chosen as a research object and a real-time meso-scale WRF-SWAN-FVCOM (W-S-F) coupling simulation platform was constructed by using Model Coupling Toolkit The spatial-temporal evolution of typhoon-wave-current in the offshore wind farm was simulated when a super typhoon “Rammasun” passed through. Next, the hydrodynamic load distribution characteristics of single pile foundation of wind turbine were analyzed by combining the meso-micro scale nested method. Extreme load model of foundation piles under different wave phases was proposed. Results demonstrated that the constructed W-S-F platform increased the simulation precision of typhoon path by 42.51% than single WRF model. The horizontal wave force of the foundation pile reached the negative and positive peaks at phases T0 and T4 under typhoon-wave-current coupling, and it presented symmetric distribution circumferentially around the 180° angle of wave attack. The phase T4 was the most adverse phase for the strength design of single pile foundation of offshore wind turbine. At the bottom of foundation, the maximum shear reached the 7.68 × 106 magnitude and the maximum bending moment reached the 5.2 × 108 magnitude.

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