Measurement uncertainty caused by distance errors during in situ tests of wind turbines

IF 0.6 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Advances in Radio Science Pub Date : 2019-09-19 DOI:10.5194/ars-17-19-2019

Cornelia Reschka, Sebastian Koj, S. Fisahn, H. Garbe

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引用次数: 1

Abstract

Abstract. During the assessment of the electromagnetic emissions of wind turbines (WTs), the aspects of measurement uncertainty must be taken into account. Therefore, this work focuses on the measurement uncertainty which arises through distance errors of the measuring positions around a WT. The measurement distance given by the corresponding standard is 30 m with respect to the WT tower. However, this determined distance will always differ e.g. due to unevenness of the surrounding ground, leading to measurement uncertainties. These uncertainties can be estimated with the knowledge of the electromagnetic field distribution. It is assumed in standard measurements, that the electromagnetic field present is a pure transversal electromagnetic field (far field). Simulations of a simplified WT model with a hub height of 100 m shows that this assumption is not effective for the whole frequency range from 150 kHz to 1 GHz. For frequencies below 3 MHz the field distribution is monotonically decreasing with the distance from the WT since it behaves like an electrical small radiator. Whereas for frequencies above 3 MHz, where the investigated model forms an electrical large radiator, the field distribution becomes more complex and the measurement uncertainty of the field strength at the observation point increases. Therefore, this work focuses on investigations where the near field becomes a far field. Based on the simulation results, a method for minimizing the uncertainty contribution caused by distance errors is presented. Therefore, advanced measurement uncertainty during in situ test of WTs can be reduced.

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风力发电机现场试验中距离误差引起的测量不确定度

摘要在评估风力涡轮机（WT）的电磁发射时，必须考虑测量不确定性的各个方面。因此，本工作的重点是由于WT周围测量位置的距离误差而产生的测量不确定度。相应标准给出的测量距离为30 m。然而，这个确定的距离总是会有所不同，例如，由于周围地面的不均匀性，导致测量的不确定性。这些不确定性可以通过电磁场分布的知识来估计。在标准测量中，假设存在的电磁场是纯横向电磁场（远场）。轮毂高度为100的简化WT模型的仿真 m表明，这个假设对150的整个频率范围无效 kHz到1 GHz。频率低于3 MHz，场分布随着与WT的距离单调递减，因为它的行为类似于小型电辐射器。而对于3以上的频率 MHz，当所研究的模型形成一个大型电辐射器时，场分布变得更加复杂，观测点场强的测量不确定度增加。因此，这项工作的重点是研究近场变成远场的情况。基于仿真结果，提出了一种最小化距离误差引起的不确定性贡献的方法。因此，可以降低WTs现场测试过程中的高级测量不确定度。

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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来源期刊

Advances in Radio Science ENGINEERING, ELECTRICAL & ELECTRONIC-

CiteScore

0.90

自引率

0.00%

发文量

审稿时长

45 weeks