Aquifer thermal energy storage systems can largely contribute to climate-friendly heating and cooling of buildings: Heated water is stored in the underground and pumped up, if needed. Researchers of Karlsruhe Institute of Technology (KIT) have now found that low-temperature aquifer thermal energy storage is of great potential in Germany. This potential is expected to grow in future due to climate change. The study includes the so far most detailed map of potential aquifer storage systems in Germany. The results are reported in Geothermal Energy. (DOI: 10.1186/s40517-022-00234-2)
More than 30 percent of domestic energy consumption currently consumed in Germany is used for heating and cooling buildings. Decarbonization of this sector could therefore lead to major greenhouse gas emission reductions and largely contribute to climate protection. Aquifer thermal energy storage systems, i.e. water-bearing layers in the underground, are suited well for the seasonal storage and flexible use of heat and cold. Water has a high capacity of storing thermal energy. The surrounding rocks have an insulating effect. Underground aquifer thermal energy storage systems are accessed by boreholes and used to store heat from solarthermal plants or waste heat from industrial facilities. If required, the heat can be pumped up again. Such storage systems can be combined perfectly with heat networks and heat pumps. Near-surface low-temperature aquifer thermal energy storage systems (LT-ATES) have proved to be particularly efficient. As the water temperature is not much higher than the temperature of the environment, little heat is lost during storage.
More than Half of the German Territory Is Suited Well or Very Well
Researchers from KIT’s Institute of Applied Geosciences (AGW) and the Sustainable Geoenergy Junior Research Group have now identified the regions suited for low-temperature aquifer thermal energy storage in Germany. “Criteria for an efficient LT-ATES operation include favorable hydrogeological conditions, such as the productivity of groundwater resources and groundwater flow velocity,” Ruben Stemmle explains. The member of AGW’s Engineering Geology Group and first author of the study adds: “Moreover, energy consumption for heating and cooling must be balanced. It can be approximated by the ratio of heating and cooling degree days.”
Read more at Karlsruher Institut für Technologie (KIT)