Abstract
The future European electricity system will depend heavily on variable renewable generation, including wind power. To plan and operate reliable electricity supply systems, an understanding of wind power variability over a range of spatio-temporal scales is critical. In complex terrain, such as that found in mountainous Switzerland, wind speeds are influenced by a multitude of meteorological phenomena, many of which occur on scales too fine to capture with commonly used meteorological reanalysis datasets. Past work has shown that anticorrelation at a continental scale is an important way to help balance variable generation. Here, we investigate systematically for the first time the possibility of balancing wind variability by exploiting anticorrelation between weather patterns in complex terrain. We assess the capability for the Consortium for Small-scale Modeling (COSMO)-REA2 and COSMO-REA6 reanalyses (with a 2 and 6 km horizontal resolution, respectively) to reproduce historical measured data from weather stations, hub height anemometers, and wind turbine electricity generation across Switzerland. Both reanalyses are insufficient to reproduce site-specific wind speeds in Switzerland’s complex terrain. We find however that mountain-valley breezes, orographic channelling, and variability imposed by European-scale weather regimes are represented by COSMO-REA2. We discover multi-day periods of wind electricity generation in regions of Switzerland which are anticorrelated with neighbouring European countries. Our results suggest that significantly more work is needed to understand the impact of fine scale wind power variability on national and continental electricity systems, and that higher-resolution reanalyses are necessary to accurately understand the local variability of renewable generation in complex terrain.
Highlights
The European energy system is expected to change dramatically over the 30 years with the phaseout of fossil fuels in order to meet 2050 carbon targets (Fragkos et al 2017)
We used high-resolution regional reanalyses to investigate wind electricity generation variability in complex terrain with a focus on mountain-valley breezes, orographic channelling, and large-scale variability imposed by weather regimes
The relative performance of the reanalyses agree with that found by Jafari et al (2012), who showed that a 3 km grid was able to capture some of the complexity of the terrain, while a 9 km grid was no better than 25 km
Summary
The European energy system is expected to change dramatically over the 30 years with the phaseout of fossil fuels in order to meet 2050 carbon targets (Fragkos et al 2017). On the current trajectory of wind farm deployment, large-scale weather patterns affecting the entire European continent (so-called weather regimes) are likely to cause large swings in wind electricity generation on subseasonal time scales of 10–60 d (Grams et al 2017). To ensure that wind farm electricity generation remains relatively constant on subseasonal time scales, Grams et al (2017) showed that it is important to consider greater wind turbine deployment in southern or high-latitude regions of Europe. Within this northsouth regime performance divide, Swiss wind farms are expected to perform to those in neighbouring, central European countries (Grams et al 2017). Grams et al (2017) did not consider the country’s complex terrain, simulating wind patterns at an aggregated country level based on a global meteorological reanalysis with ∼55 km horizontal resolution (Staffell and Pfenninger 2016)
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