An analysis of offshore wind farm SCADA measurements to identify key parameters influencing the magnitude of wake effects
For offshore wind farms, wake effects are among the largest sources of losses in energy production. At the same time, wake modelling is still associated with very high uncertainties. Therefore current research focusses on improving wake model predictions. It is known that atmospheric conditions,...
Main Authors: | , , , , , , |
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Format: | Article |
Language: | English |
Published: |
Copernicus Publications
2017-10-01
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Series: | Wind Energy Science |
Online Access: | https://www.wind-energ-sci.net/2/477/2017/wes-2-477-2017.pdf |
Summary: | For offshore wind farms, wake effects
are among the largest sources of losses in energy production. At the same
time, wake modelling is still associated with very high uncertainties.
Therefore current research focusses on improving wake model predictions. It
is known that atmospheric conditions, especially atmospheric stability,
crucially influence the magnitude of those wake effects. The classification
of atmospheric stability is usually based on measurements from met masts,
buoys or lidar (light detection and ranging). In offshore conditions these
measurements are expensive and scarce. However, every wind farm permanently
produces SCADA (supervisory control and data acquisition) measurements. The
objective of this study is to establish a classification for the magnitude of
wake effects based on SCADA data. This delivers a basis to fit engineering
wake models better to the ambient conditions in an offshore wind farm. The
method is established with data from two offshore wind farms which each have a
met mast nearby. A correlation is established between the stability
classification from the met mast and signals within the SCADA data from the
wind farm. The significance of these new signals on power production is
demonstrated with data from two wind farms with met mast and long-range
lidar
measurements. Additionally, the method is validated with data from another
wind farm without a met mast. The proposed signal consists of a good
correlation between the standard deviation of active power divided by the
average power of wind turbines in free flow with the ambient turbulence
intensity (TI) when the wind turbines were operating in partial load. It
allows us to distinguish between conditions with different magnitudes of wake
effects. The proposed signal is very sensitive to increased turbulence
induced by neighbouring turbines and wind farms, even at a distance of more
than 38 rotor diameters. |
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ISSN: | 2366-7443 2366-7451 |