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Current Issue

Inventi Impact: Wind & Waves

Current Issue : October-December
Volume : 2024
Issue Number : 4
Articles : 5 Articles

Articles

  • Inventi:eww/80831/24
    Analysis of Wind Resource Characteristics in the Ulanqab Wind Power Base (Wind Farm): Mesoscale Modeling Approach
    Dong Xu, Feifei Xue, Yuqi Wu, Yangzhou Li, Wei Liu, Chang Xu, Jing Sun
    >Research  Download Full Text

    With the rapid development and construction of large-scale wind power bases under the “Carbon Peaking and Carbon Neutrality Goals” target, traditional wind energy resource assessment methods typically rely on a limited amount of wind mast data, providing only limited wind resource analysis results. These methods are incapable of capturing the spatiotemporal distribution of wind energy resources throughout the entire base, thus failing to meet the construction requirements of wind power bases. In this study, the mesoscale WRF (The Weather Research and Forecasting Model) was employed for wind resource simulation in a large wind power base. Based on the terrain, meteorological observation data, and boundary conditions, high-resolution wind field simulation results were generated, providing more comprehensive spatiotemporal distribution information within the Ulanqab region’s wind power base. Through the analysis and comparison of measured data and simulation results at different horizontal resolutions, the model was evaluated. Taking the Ulanqab wind power base as an example, the WRF model was used to study the distribution patterns of key parameters, such as annual average wind speed, turbulence intensity, annual average wind power density, and wind direction. The results indicate that a 4 km horizontal resolution can simultaneously ensure the accuracy of wind speed and wind direction simulations, demonstrating good engineering applicability. The analysis of wind resource characteristics in the Ulanqab wind power base based on the mesoscale model provides reliable reference value and data support for its macro- and micro-siting....

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  • Inventi:eww/80830/24
    Design of a Robotic Platform for Hybrid Wind Tunnel Experiments of Floating Wind Farms
    A Fontanella, G Palombini, A Piffer, H Giberti, M Belloli
    >Research  Download Full Text

    Wind tunnel experiments incorporating factors like realistic ambient wind conditions, merging of multiple wakes, and active wake controls are needed to understand and improve modeling of floating wind farms. A key technology for this kind of experiments is the robotic system emulating the wind turbine motion. This article addresses the design of a robotic platform with three degrees-of-freedom (surge, pitch, and yaw) specifically tailored for wind tunnel experiments on floating wind farms. This robotic system aims to accurately reproduce the motion spectrum of floating wind turbines of 10-22MW and to simulate rotoratmospheric wind interactions. The robotic platform has a compact design to be positioned in multiple units inside the wind tunnel and avoid disturbing the wake of the wind turbine on top of it. To achieve these goals, the wind turbine is partially integrated in the robotic platform that employs a parallel kinematic scheme and has all actuators close to the wind tunnel floor....

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  • Inventi:eww/80829/24
    Development of a Novel Method for the Correction of the Nacelle Wind Speed in Stall-Controlled Wind Turbines
    Larisa Vivas, Francesco Papi, Vasilis Papatsiros, Olivier Maudhuit, Alessandro Bianchini
    >Research  Download Full Text

    Accurate estimation of the oncoming wind is key to ensure an accurate control of any wind turbine. The wind speed is commonly measured with an anemometer located on the nacelle; hence, the measurement is influenced by the rotor and the nacelle itself and needs to be corrected so as not to incur inaccurate energy yield assessments. This study introduces an innovative method for correcting the nacelle wind speed in stall-controlled wind turbines. The development of the method has benefitted from the unique possibility of exploiting two datasets containing 10-minute averaged wind data from two identical EUNICE EW16 wind turbines and a meteorological mast located at the same site. The innovative method is systematically compared with the Nacelle Transfer Function outlined in the IEC 61400-12-2, serving as a benchmark for evaluation. The high accuracy and simplicity of the proposed method make it particularly suitable for the optimization of wind turbine performance in industrial applications. Moreover, an accurate estimation of the incoming wind speed can enable innovative control techniques, such as those based on Tip-Speed-Ratio (TSR) tracking. This is addressed in the study through simulations by comparing a TSR-Tracking strategy with the most common k-2 strategy. The study demonstrated that the TSR-Tracking strategy could be adopted in stall-controlled wind turbines if an accurate estimation of the free-stream wind speed is available....

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  • Inventi:eww/80827/24
    Effects of Wind Turbine Rotor Tilt on Large-Scale Wind Farms
    Jens H Kasper, Richard J A M Stevens
    >Research  Download Full Text

    Recent studies have explored the use of rotor tilt adjustments to reduce wake losses in wind farms. While downward wake deflection in aligned wind farms has shown promise for significant power gains, the impact of wind farm layout on the effectiveness of tilt strategies is not yet fully understood. Additionally, the effect on downstream farms remains unclear. Our large eddy simulations reveal that a rotor tilt of 20 degrees significantly reduces wake losses in aligned wind farms. For wind farms with 8 turbine rows, we observe an overall increase in wind farm productivity of up to 11%. However, tilting the rotors may decrease power production in staggered wind farms, where wake losses are inherently lower due to the increased spacing between turbines. Our findings also suggest that a downstream wind farm might benefit from an upstream farm implementing rotor tilt, although this advantage is primarily observed in the first row of the downstream farm....

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  • Inventi:eww/80828/24
    Wind Farm Wakes and Farm-to-Farm Interactions: Lidar and Wind Tunnel Tests
    W U Ahmed, C Moss, S Roy, M Shams Solari, M Puccioni, K Panthi, P Moriarty, G V Iungo
    >Research  Download Full Text

    Recent experimental and numerical evidence has shown that the cumulative wake generated from the overlapping of multiple wakes within a wind farm could reduce power performance and enhance fatigue loads of wind turbines installed in neighboring downstream wind farms and may also extend up to distances one order of magnitude larger than those typically considered for intra-farm wake interactions. Similar to individual wind turbine wakes, wind farm wakes have a velocity deficit and added turbulence intensity, both affected by the turbine rotor thrust forces and the incoming turbulence intensity. Therefore, the evolution of wind farm wakes will vary for different operational and atmospheric conditions. In this paper, lidar measurements collected during the American WAKE experimeNt (AWAKEN) and wind tunnel tests of wind farms reproduced by porous disks are leveraged to investigate wind farm wakes....

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