Nikolas Angelou, Jakob Mann, Camille Dubreuil-Boisclair
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引用次数: 1
摘要
摘要我们研究了世界上第一个浮式风力发电场,Hywind苏格兰海上风力发电场的6兆瓦浮式风力涡轮机的流入和尾流特征。我们使用两个商用的安装在机舱内的激光雷达,分别采用固定和扫描测量几何形状来测量顺风和顺风条件。在分析中,考虑了机舱俯仰角和侧滚角对激光雷达测量位置的影响。逆风条件参数化为轮毂高度的平均水平风矢量、转子上部风廓线的切变和转向以及风力机转子的感应。研究了在8.5-9.5和12.5-13.5 m s - 1两个狭窄风速区间,分别对应于低于和高于转子额定速度,湍流强度在3.3% - 6.4%之间时的尾迹特性。采用平面位置指示方式,利用风激光雷达沿水平方向扫描尾流,测量尾流在下风10 D的位置。本研究主要集中在3 ~ 8 d之间的下游区域,在该区域,我们的观测表明,尾流的横向轮廓可以用遵循高斯分布的自相似风速亏缺来充分描述。我们发现,即使环境湍流强度的微小变化(~ 1% - 2%)也能使尾流恢复速度加快10%。此外,我们没有观察到由于本研究中检查的浮动风力涡轮机的运动而导致的尾流的任何额外扩展。
Revealing inflow and wake conditions of a 6 MW floating turbine
Abstract. We investigate the characteristics of the inflow and the wake of a 6 MW floating wind turbine from the Hywind Scotland offshore wind farm, the world's first floating wind farm. We use two commercial nacelle-mounted lidars to measure the up- and downwind conditions with a fixed and a scanning measuring geometry, respectively. In the analysis, the effect of the pitch and roll angles of the nacelle on the lidar measuring location is taken into account. The upwind conditions are parameterized in terms of the mean horizontal wind vector at hub height, the shear and veer of the wind profile along the upper part of the rotor, and the induction of the wind turbine rotor. The wake characteristics are studied in two narrow wind speed intervals between 8.5–9.5 and 12.5–13.5 m s−1, corresponding to below and above rotor rated speeds, respectively, and for turbulence intensity values between 3.3 %–6.4 %. The wake flow is measured along a horizontal plane by a wind lidar scanning in a plan position indicator mode, which reaches 10 D downwind. This study focuses on the downstream area between 3 and 8 D. In this region, our observations show that the transverse profile of the wake can be adequately described by a self-similar wind speed deficit that follows a Gaussian distribution. We find that even small variations (∼1 %–2 %) in the ambient turbulence intensity can result in an up to 10 % faster wake recovery. Furthermore, we do not observe any additional spread of the wake due to the motion of the floating wind turbine examined in this study.