Renewable Electric Energy Storage Systems by Storage Spheres on the Seabed of Deep Lakes or Oceans
- 1Goethe Universität Frankfurt, Institut für Kernphysik, Germany (hsb@atom.uni-frankfurt.de)
- 2Forschungsstelle Zukunftsenergie, Universität des Saarlandes, Experimentalphysik, FSt. Zukunftsenergie, 66123 Saarbrücken, Germany;
- 3II. Physikalisches Institut, Justus-Liebig-Universität Gießen, 35392 Gießen, Germany;
A new underwater pumped storage hydropower concept (U.PSH) is described that can store electric energy by using the high water pressure on the seabed or in deep lakes to accomplish the energy transition from fossil to renewable sources. Conventional PSH basically consists of two storage reservoirs (upper and lower lake) at different topographical heights. It needs special topographic conditions, which are only limitedly available in mountain regions. Furthermore, due to the lack of acceptance and the environmental impact, new conventional PSH projects are very unlikely to be built in larger numbers in Europe in the near future. The presented solution solves these issues by placing the storage system on the seabed, thus having other geographical requirements. It operates as follows: in contrast to well-known conventional PSH plants, which use two separated water reservoirs of different heights, the U.PSH concept uses the static pressure of the water column in deep waters by installing a hollow concrete sphere in deep water. Storage of electricity is achieved by using a reversible pump in the hollow sphere. Upon opening a valve, water flows into the sphere, driving a turbine/generator, thereby discharging the storage device. In order to re-charge, the water is pumped out of the sphere against the pressure of the surrounding water. The power and energy, respectively, are proportional to the surrounding water pressure at the seabed. The amount of energy stored depends on the water depth and the volume of the spheres. The spheres need a cable connection to the shore or to a close-by floating transformer station (e.g., an offshore wind plant). No other connections such as pipes are needed. The functional principle of this energy storage technology, its state of the art, its storage capacity and the shape and size of the required spheres are discussed in this paper.
How to cite: Schmidt-Boecking, H., Luther, G., and Düren, M.: Renewable Electric Energy Storage Systems by Storage Spheres on the Seabed of Deep Lakes or Oceans, EGU General Assembly 2024, Vienna, Austria, 14–19 Apr 2024, EGU24-15312, https://doi.org/10.5194/egusphere-egu24-15312, 2024.