Probabilistic forecasting of wind power production losses in cold climates: a case study
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Published:2018-10-09
Issue:2
Volume:3
Page:667-680
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ISSN:2366-7451
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Container-title:Wind Energy Science
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language:en
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Short-container-title:Wind Energ. Sci.
Author:
Molinder Jennie, Körnich HeinerORCID, Olsson Esbjörn, Bergström Hans, Sjöblom AnnaORCID
Abstract
Abstract. The problem of icing on wind turbines in cold climates is addressed using
probabilistic forecasting to improve next-day forecasts of icing and related
production losses. A case study of probabilistic forecasts was generated for
a 2-week period. Uncertainties in initial and boundary conditions are
represented with an ensemble forecasting system, while uncertainties in the
spatial representation are included with a neighbourhood method. Using
probabilistic forecasting instead of one single forecast was shown to improve
the forecast skill of the ice-related production loss forecasts and hence the
icing forecasts. The spread of the multiple forecasts can be used as an
estimate of the forecast uncertainty and of the likelihood for icing and
severe production losses. Best results, both in terms of forecast skill and
forecasted uncertainty, were achieved using both the ensemble forecast and
the neighbourhood method combined. This demonstrates that the application of
probabilistic forecasting for wind power in cold climates can be valuable when
planning next-day energy production, in the usage of de-icing systems and
for site safety.
Publisher
Copernicus GmbH
Subject
Energy Engineering and Power Technology,Renewable Energy, Sustainability and the Environment
Reference37 articles.
1. Al-Yahyai, S., Charabi, Y., Al-Badi, A., and Gastli, A.: Nested ensemble NWP
approach for wind energy assessment, Renew. Energ., 37, 150–160,
https://doi.org/10.1016/j.renene.2011.06.014, 2011. a 2. Andrae, U. and MetCoOp-Team: ALADIN-HIRLAM Newsletter, available at:
http://www.umr-cnrm.fr/aladin/meshtml/NL8-final.pdf (last access:
1 October 2018), 2017. a 3. Bengtsson, L., Andrae, U., Aspelien, T., Batrak, Y., Calvo, J., De Rooy,
W.,
Gleeson, E., Hansen-Sass, B., Homleid, M., Hartal, M., Ivarsson, K.-I.,
Lenderink, G., Miemelä, S., Pagh Nielsen, K., Onvlee, J., Rontu, L.,
Samuelsson, P., Santos Munoz, D., Subias, A., Tijm, S., Toll, V., Yang, X.,
and Ødegaard Køltzow, M.: The HARMONIE – AROME Model Configuration
in the ALADIN – HIRLAM NWP System, Mon. Weather Rev., 145, 1919–1935,
https://doi.org/10.1175/MWR-D-16-0417.1, 2017. a 4. Bergström, H., Olsson, E., Söderberg, S., Thorsson, P., and
Undén, P.: Wind power in cold climates, Ice mapping methods, Tech.
rep., Elforsk, Stockholm, available at:
http://www.diva-portal.org/smash/record.jsf?pid=diva2:704372&dswid=6571
(last access: 1 October 2018), 2013. a, b, c, d, e, f, g 5. Bouttier, F., Raynaud, L., Nuisser, O., and Ménétrier, B.:
Sensitivity of the AROME ensemble to initial and surface perturbations
during HyMeX, Q. J. Roy. Meteor. Soc., 142, 390–403,
https://doi.org/10.1002/qj.2622, 2015. a
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