Insights into wind turbine reflectivity and radar cross-section (RCS) and their variability using X-band weather radar observations

Martin Lainer,Montserrat F.-Bolaños,Jordi Figueras i Ventura,Reto Pauli,Marco Gabella,Jacopo Grazioli,Zaira Schauwecker

doi:10.5194/amt-14-3541-2021

Abstract

Abstract. The increasing need of renewable energy fosters the expansion of wind turbine sites for power production throughout Europe with manifold effects, both on the positive and negative side. The latter concerns, among others, radar observations in the proximity of wind turbine (WT) sites. With the aim of better understanding the effects of large, moving scatterers like wind turbines on radar returns, MeteoSwiss performed two dedicated measurement campaigns with a mobile X-band Doppler polarimetric weather radar (METEOR 50DX) in the northeastern part of Switzerland in March 2019 and March 2020. Based on the usage of an X-band radar system, the performed campaigns are up to now unique. The main goal was to quantify the effects of wind turbines on the observed radar moments, to retrieve the radar cross-section (RCS) of the turbines themselves and to investigate the conditions leading to the occurrence of the largest RCS. Dedicated scan strategies, consisting of PPI (plan position indicator), RHI (range–height indicator) and fixed-pointing modes, were defined and used for observing a wind park consisting of three large wind turbines. During both campaigns, measurements were taken in 24/7 operation. The highest measured maxima of horizontal reflectivity (ZH) and RCS reached 78.5 dBZ and 44.1 dBsm, respectively. A wind turbine orientation (yawing) stratified statistical analysis shows no clear correlation with the received maximum returns. However, the median values and 99th percentiles of ZH show different enhancements for specific relative orientations. Some of them remain still for Doppler-filtered data, supporting the importance of the moving parts of the wind turbine for the radar returns. Further, we show, based on investigating correlations and an OLS (ordinary least square) model analysis, that the fast-changing rotor blade angle (pitch) is a key parameter, which strongly contributes to the variability in the observed returns.

Highlights

The rapid development and expansion of wind farms in the latest years are a significant source of concern for the weather (e.g., Norin, 2017) and aviation radar community (de la Vega et al, 2016; Cuadra et al, 2019)
The primary focus of this paper is to present a statistical analysis of radar reflectivity (ZH) and retrieved radar cross-section (RCS) values and to find the relation between those variables and the operational data of the wind turbines
The interaction between wind turbines and radar systems is complex in nature due to a large set of parameters affecting the scattering behavior of the turbine object

Summary

Introduction

The rapid development and expansion of wind farms in the latest years are a significant source of concern for the weather (e.g., Norin, 2017) and aviation radar community (de la Vega et al, 2016; Cuadra et al, 2019). As analyzed by Komusanac et al (2020) in 2019, about 15.4 GW of new wind power capacity was installed in the European Union (EU). This is 27 % higher than in 2018. The total capacity of wind energy in the EU at the end of 2019 was 205 GW. With the fact that green energy is becoming trendy, a realistic outlook until 2030 is to have around 323 GW of wind turbine power installed

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