Abstract
Abstract. Wind turbine power production deviates from the reference power curve in real-world atmospheric conditions. Correctly predicting turbine power performance requires models to be validated for a wide range of wind turbines using inflow in different locations. The Share-3 exercise is the most recent intelligence-sharing exercise of the Power Curve Working Group, which aims to advance the modeling of turbine performance. The goal of the exercise is to search for modeling methods that reduce error and uncertainty in power prediction when wind shear and turbulence digress from design conditions. Herein, we analyze data from 55 wind turbine power performance tests from nine contributing organizations with statistical tests to quantify the skills of the prediction-correction methods. We assess the accuracy and precision of four proposed trial methods against the baseline method, which uses the conventional definition of a power curve with wind speed and air density at hub height. The trial methods reduce power-production prediction errors compared to the baseline method at high wind speeds, which contribute heavily to power production; however, the trial methods fail to significantly reduce prediction uncertainty in most meteorological conditions. For the meteorological conditions when a wind turbine produces less than the power its reference power curve suggests, using power deviation matrices leads to more accurate power prediction. We also determine that for more than half of the submissions, the data set has a large influence on the effectiveness of a trial method. Overall, this work affirms the value of data-sharing efforts in advancing power curve modeling and establishes the groundwork for future collaborations.
Highlights
Predicting the power output of a wind turbine for a given set of climatic conditions is a fundamental challenge in wind energy resource assessment
This study discusses the findings from the Share3 exercise, which is an intelligence-sharing initiative of the Power Curve Working Group (PCWG), its analysis tool for data collection, and its definitions of inner range and outer range conditions
In addition to the background information of the Share-3 exercise, this study summarizes the analysis based on the 55 power performance tests with modern wind turbines from nine contributing organizations
Summary
Predicting the power output of a wind turbine for a given set of climatic conditions is a fundamental challenge in wind energy resource assessment. Current industry practices involve predicting power output using a power curve, which defines power production as a function of hub-height wind speed. Besides the traditional understanding of a power curve, wind power production depends on other meteorological variables including air density, turbulence, and wind shear. A power curve is only strictly valid for a subset of all atmospheric conditions. 2) refers to this subset of meteorological conditions as the “inner range”. The corresponding “outer range” represents all other possible scenarios. The definitions are discussed in detail in Sect.
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