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Wind Energy Science The interactive open-access journal of the European Academy of Wind Energy
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https://doi.org/10.5194/wes-2020-67
© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.
https://doi.org/10.5194/wes-2020-67
© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

  13 May 2020

13 May 2020

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A revised version of this preprint is currently under review for the journal WES.

Offshore wind power intermittency: The effect of connecting production sites along the Norwegian continental shelf

Ida Marie Solbrekke1,2, Nils Gunnar Kvamstø1,2, and Asgeir Sorteberg1,2,3 Ida Marie Solbrekke et al.
  • 1Geophysical Institute, University of Bergen, Allegaten 70, 5020 Bergen, Norway
  • 2Bergen Offshore Wind Centre (BOW), University of Bergen, Norway
  • 3Bjerknes Centre for Climate Research (BCCR), University of Bergen, Norway

Abstract. This study uses a unique set of hourly wind speed data observed over a period of 16 years to quantify the potential of collective offshore wind power production. We address the well-known intermittency problem of wind power for five locations along the Norwegian continental shelf. Mitigation of wind power intermittency is investigated using a hypothetical electricity grid. The degree of mitigation is examined by connecting different configurations of the sites. Along with the wind power smoothing effect, we explore the risk probability of the occurrence and duration of wind power shut-down. Typical large-scale atmospheric situations resulting in long term shut-down periods are identified. We find that both the wind power variability and the risk of not producing any wind power decrease significantly with an increasing array of connected sites. The risk of no wind power production for a given hour is reduced from 10 % for a single site to under 4 % for two sites. Increasing the array-size further reduces the risk, but to a lesser extend. The average atmospheric weather pattern resulting in wind speed that is too low (too high) to produce wind power is associated with a high- (low-) pressure system near the production sites.

Ida Marie Solbrekke et al.

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Ida Marie Solbrekke et al.

Ida Marie Solbrekke et al.

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Latest update: 25 Sep 2020
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Short summary
The potential of collective offshore wind power is quantified using 16 years of hourly wind speed observations. Wind power intermittency is reduced through a hypothetical electricity grid connecting five sites at the Norwegian continental shelf. We identify large-scale atmospheric situations resulting in long term periods of power shut-down. Wind power variability and risk-measures decrease in an interconnected wind power system.
The potential of collective offshore wind power is quantified using 16 years of hourly wind...
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