Ground motions induced by wind turbines

Sven Nagel, Toni Zieger, Birger Luhmann, Peter Knödel, Joachim Ritter, Thomas Ummenhofer
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引用次数: 5

Abstract

Wind flow transfers forces to the wind turbine's rotor blades. These then set the rotor in motion. The hub and the gearbox, where present, transfer this rotational energy to the generator for conversion into electrical power. All the rotating components have significant mass and are located at the head of a slender, elastic load-bearing tower in which they induce dynamic effects. The resulting vibrations, generated at the upper end of the tower, are modified by the dynamic properties of the tower structure and pass through the foundations into the ground. Broadband seismometers record these ground vibrations not only directly adjacent to the wind turbine but also at greater distances of (up to) several kilometers from the turbine. We are aware that local residents and opponents of wind power consider that these vibration phenomena bear potential negative health effects. In the context of this paper, seismic vibrations were measured at the foundation of a 2 MW reference turbine. These seismic signals were compared to numerical simulations. Based on this, we explain the physical background. In the past, any ground vibrations measured have usually been attributed exclusively to the excitation frequencies from the rotor. However, the investigations presented here show that the structural properties of the tower structure significantly influence the type and intensity of the vibrations induced in the ground and dominate the ground motion amplitudes. Finally, we show that the targeted use of absorbers can significantly reduce the vibrations induced in the ground.

Abstract Image

风力涡轮机引起的地面运动
气流将力传递给风力涡轮机的转子叶片。这些然后设置转子在运动。轮毂和齿轮箱,如果存在,将这种旋转能量转移到发电机转换成电能。所有的旋转部件都有显著的质量,并位于一个细长的,弹性承重塔的头部,在那里它们引起动力效应。由此产生的振动在塔的上端产生,被塔结构的动力特性所修正,并通过基础进入地面。宽带地震仪不仅直接记录风力涡轮机附近的地面振动,而且还记录距离涡轮机几公里远的地方的地面振动。我们知道,当地居民和风力发电的反对者认为这些振动现象对健康有潜在的负面影响。在本文的背景下,在一个2mw参考涡轮机的基础上测量了地震振动。将这些地震信号与数值模拟进行了比较。在此基础上,我们解释了物理背景。在过去,任何地面振动的测量通常只归因于转子的激励频率。然而,本文的研究表明,塔结构的结构特性显著地影响了地面振动的类型和强度,并主导了地面运动的振幅。最后,我们表明,有针对性地使用吸收器可以显著减少在地面上引起的振动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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