Investigation of wind veer characteristics on complex terrain using ground-based lidar

International Journal of Renewable Energy Development Pub Date : 2023-10-26 DOI:10.14710/ijred.2023.56352

Undarmaa Tumenbayar, Kyungnam Ko

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Abstract

The wind direction shift with height significantly influences wind turbine performance, particularly in relation to terrain conditions. In this work, wind conditions at 12 measurement heights ranging from 40 m to 200 m using a ground lidar, Windcube V2, installed on a 16 m tall building were analysed to examine the characteristics of wind veer angles in complex terrain. The measurement campaign was carried out from January 1st to December 31st, 2022, in the southeastern part of South Korea. The terrain complexity around the ground lidar system was evaluated using the ruggedness index (RIX), whose result was 14.06 percent corresponding to complex terrain. The ground lidar measurements were compared with mesoscale data, EMD-WRF South Korea, for the data accuracy check. Wind veer frequencies and wind roses were derived to identify directional shifts with height. Furthermore, diurnal, monthly, and seasonal variations of wind veer characteristics were analysed. Wind shear exponent factor (WSE) and turbulence kinetic energy (TKE) were calculated, and wind veer profiles were constructed based on these parameters. The relative errors of wind speeds were analysed for rotor equivalent wind speed (REWS) and hub height wind speed (HHWS), with REWS with wind veer correction, REWSveer, as a reference. Additionally, atmospheric stability conditions were classified using WSE and TKE, and the vertical changes in wind veering were analysed according to the stability conditions. The findings reveal lower wind speeds exhibited larger wind veer values and fluctuations. The relative errors for the REWS and the HHWS were 0.04 % and 0.20 % on average, respectively. The study demonstrates that terrain conditions significantly impacted wind veer angles at heights below 100 m, whereas the influence diminished with increasing height above 100 m. The results could be helpful for wind farm developers to make decisions on the siting as well as the hub height of wind turbines on complex terrain

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基于地面激光雷达的复杂地形风转向特性研究

风向随高度的变化显著影响风力发电机的性能，特别是在地形条件下。在这项工作中，使用安装在16米高的建筑物上的地面激光雷达Windcube V2，分析了12个测量高度(从40米到200米)的风况，以检查复杂地形中的风转向角特征。这项测量活动于2022年1月1日至12月31日在韩国东南部进行。采用崎岖指数(RIX)对地面激光雷达系统周围的地形复杂性进行评估，其结果为14.06%，对应于复杂地形。将地面激光雷达测量数据与中尺度数据EMD-WRF韩国进行比较，以检查数据的准确性。推导风转向频率和风玫瑰来确定方向随高度的变化。此外，还分析了风向特征的日变化、月变化和季节变化。计算了风切变指数因子(WSE)和湍流动能(TKE)，并在此基础上构建了风转向廓线。以风向校正后的风向等效风速(REWSveer)为参考，分析了转子等效风速(REWS)和轮毂高度风速(HHWS)的相对误差。此外，利用WSE和TKE对大气稳定条件进行分类，并根据稳定条件分析风转向的垂直变化。研究结果表明，风速越低，风转向值和波动越大。REWS和HHWS的相对误差平均分别为0.04%和0.20%。研究表明，在100 m以下高度，地形条件对风转向角的影响显著，而在100 m以上高度，地形条件对风转向角的影响随高度的增加而减小。研究结果可能有助于风电场开发商在复杂地形上对风力涡轮机的选址和轮毂高度做出决策

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International Journal of Renewable Energy Development

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