Summary
The main objective of this project is to significantly reduce costs of concentrated solar power, in order to pave the way for its deserved competitiveness on the power market. Specifically, the solar-to-electric conversion efficiency of the plant will be improved by increased receiver operating temperatures as well as an innovative power cycle configuration also providing advantages regarding plant operation. Additionally, improved control methodologies based on dynamic multi-aiming-point strategies for heliostats will further enhance efficiency. Besides the improvement of the plants efficiency and operation, also the construction and operational costs will be minimized via mass production of heliostats and smart heliostat calibration systems.
The global objective of this project is to increase plant efficiencies and reduce levelized cost of electricity (LCOE) by developing all relevant components that allow implementing an innovative plant configuration. This plant configuration is based on a multi-tower decoupled advanced solar combined cycle approach that not only increases cycle efficiencies but also avoids frequent transients and inefficient partial loads, thus maximizing overall efficiency, reliability as well as dispatchability, all of which are important factors directly related to cost competitiveness on the power market. The core topic of the project, the innovative solar receiver, will be an open volumetric receiver allowing operating temperatures beyond 1200 ºC, providing the absorbed solar heat to the pressurized air circuit of the Brayton cycle via a network of fixed bed regenerative heat exchangers working in alternating modes (non-pressurized heating period, pressurized cooling period).
The global objective of this project is to increase plant efficiencies and reduce levelized cost of electricity (LCOE) by developing all relevant components that allow implementing an innovative plant configuration. This plant configuration is based on a multi-tower decoupled advanced solar combined cycle approach that not only increases cycle efficiencies but also avoids frequent transients and inefficient partial loads, thus maximizing overall efficiency, reliability as well as dispatchability, all of which are important factors directly related to cost competitiveness on the power market. The core topic of the project, the innovative solar receiver, will be an open volumetric receiver allowing operating temperatures beyond 1200 ºC, providing the absorbed solar heat to the pressurized air circuit of the Brayton cycle via a network of fixed bed regenerative heat exchangers working in alternating modes (non-pressurized heating period, pressurized cooling period).
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/640905 |
| Start date: | 01-05-2015 |
| End date: | 31-07-2020 |
| Total budget - Public funding: | 6 461 970,43 Euro - 6 104 032,00 Euro |
Cordis data
Original description
The main objective of this project is to significantly reduce costs of concentrated solar power, in order to pave the way for its deserved competitiveness on the power market. Specifically, the solar-to-electric conversion efficiency of the plant will be improved by increased receiver operating temperatures as well as an innovative power cycle configuration also providing advantages regarding plant operation. Additionally, improved control methodologies based on dynamic multi-aiming-point strategies for heliostats will further enhance efficiency. Besides the improvement of the plants efficiency and operation, also the construction and operational costs will be minimized via mass production of heliostats and smart heliostat calibration systems.The global objective of this project is to increase plant efficiencies and reduce levelized cost of electricity (LCOE) by developing all relevant components that allow implementing an innovative plant configuration. This plant configuration is based on a multi-tower decoupled advanced solar combined cycle approach that not only increases cycle efficiencies but also avoids frequent transients and inefficient partial loads, thus maximizing overall efficiency, reliability as well as dispatchability, all of which are important factors directly related to cost competitiveness on the power market. The core topic of the project, the innovative solar receiver, will be an open volumetric receiver allowing operating temperatures beyond 1200 ºC, providing the absorbed solar heat to the pressurized air circuit of the Brayton cycle via a network of fixed bed regenerative heat exchangers working in alternating modes (non-pressurized heating period, pressurized cooling period).
Status
CLOSEDCall topic
LCE-02-2014Update Date
26-10-2022
Images
No images available.
Geographical location(s)
Structured mapping
Unfold all
/
Fold all
Search
Organisations
-
| FUNDACION CENER (Coördinator)
-
| BLUEBOX ENERGY LTD
-
| CENTRO DE INVESTIGACIONES ENERGETICAS, MEDIOAMBIENTALES Y TECNOLOGICAS-CIEMAT
-
| CERA SYSTEM VERSCHLEIßSCHUTZ GMBH
-
| COMMISSARIAT A L ENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES (CEA)
-
| ELECTRICITE DE FRANCE (EDF)
-
| EUREC EESV
-
| FCT INGENIEURKERAMIK GMBH
-
| FRAUNHOFER GESELLSCHAFT ZUR FOERDERUNG DER ANGEWANDTEN FORSCHUNG E.V.
-
| Fundación Tekniker
-
| HAVER & BOECKER OHG
-
| K CONTROLS LTD
-
| QUERDENKFABRIK AG
-
| SOCIETE INDUSTRIELLE DE SONCEBOZ SA
-
| TSK ELECTRONICA Y ELECTRICIDAD SA