Renewable Solutions Are Out of This World

The European Space Agency (ESA) believes orbiting satellites can provide a wide variety of data that can help with many aspects of the building and management of renewable energy plants. The ESA maintains that outer space technology can enable the world’s population to more effectively harness the free and endless energy resources, of the Sun, wind and water.

Frascati, Italy – August 12, 2003 [] At its Frascati-based center in Italy, ESA explored how satellite data can be exploited to further the development of renewable energy. Representatives of the Earth Observation (EO) service industry, renewable energy companies and utilities attended the workshop. The Earth Observation (EO) Market Development section of ESA announced plans to fund an international project to foster the development of EO-based services for the wind, solar and hydropower energy industries. EO notes that Europe is already the world leader in renewable energy. Denmark is flanked by some 2,300 wind turbines, which supplying 15 percent of its electricity. Germany is on course to have 140,000 solar-paneled rooftops installed by 2005. More than half of Scandinavia’s energy comes from hydropower. And as part of Kyoto-protocol efforts to curb carbon emissions, the European Commission has pledged that renewable sources will make up 22 percent of Europe’s energy supply by the end of this decade (up from 14 percent in 1997). As the importance of the renewables sector grows, the idea has arisen to use satellite data for better exploitation of its various energy sources. Meteorological satellites such as the Meteosat Second Generation (MSG) series can provide “sunshine maps” that can help select optimal sites to build new solar-cell plants. At the Frascati workshop, Murray Cameron of the European Photovoltaic Industry Association (EPIA) explained how space data could also be used to help quantify the potential power expected from a given solar plant and its associated performance. Christof Stork of UK-based Garrad Hassan said that selecting optimal locations for wind farms is very important. Stork told the Frascati workshop how satellite data on land use, surface topography and roughness could improve the accuracy of regional wind atlases currently used to site land-based wind farms. Offshore wind farms are more productive and most future farms are likely to be built in the coastal ocean due to the saturation of land-based sites. To be viable, offshore developments have to generate at least 200 MW, and to build on such a scale costs at least €300 million (US$ 339 million). One problem according to the ESA is there is hardly any offshore wind data available to industry. Furthermore, existing data record mainly extreme wind events. Gathering in-site data from a single offshore meteorological mast can cost €1 million (US$1.13 million) a year, and provide data only for a small area. But using satellites enables a shift from a local to a global view. The sophisticated Synthetic Aperture Radar (SAR) instruments on board ESA’s satellites, ERS-2 and Envisat, can provide high-resolution 100-meter data on the wind field, and a decade-long data archive is available. Other space-borne instruments could come into play through the cycle of wind turbine planning, construction and maintenance. Optical sensors such as Envisat’s Medium Resolution Imaging Spectrometer (MERIS) could be used to carry out environmental impact assessments. And satellite images could also be used for marine traffic management during initial construction and later repair work, as well as for daily energy production forecasting. Hydropower, which currently supplies around one fifth of the world’s energy needs, requires accurate quantification of how much water will flow from a given region at any one time; as the data is extremely useful for optimizing hydroelectric power production, deciding dam levels and setting electricity prices. In Norway, where hydropower supplies almost all the country’s energy needs, around half of all winter precipitation accumulates on the ground throughout the winter as snow. By measuring snow coverage and thickness, then combining this information with meteorological data such as ground temperature, run-off can be accurately modeled and predicted. Optical EO data is already used to monitor snow coverage, together with ground observation. But the operational use of optical data remains severely limited by the presence of clouds. However, radar instruments such as those aboard ERS-2 and Envisat have the potential to greatly supplement the amount of snow data gathered, because they can see right through clouds. Anders Rognes of the Norwegian Computing Center told the Frascati workshop how they have worked with Statkraft, a major Scandinavian hydropower company, to prepare a snow reservoir mapping system called SnowStar. The SnowStar server automatically processes satellite information of several different systems, including radar imagery, for display within geographic information system (GIS) software. Representing a first in the EO field, the Invitation to Tender issued by ESA in July is open for applications until 5 September 2003. The hope is that pilot services to the renewables sector can be developed, then grow to become self-sustaining. “The ESA gathering was very useful in getting service providers and potential service users together,” said workshop participant Marion Schroedter-Homscheidt of the German Aerospace Centre DLR. “Now the Invitation to Tender gives both sides the opportunity to turn the ideas we discussed into reality.”
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