Concentrated Solar Power (CSP) plants track the sun and concentrate its radiation by special mirrors converting solar energy to heat and via a power cycle to electricity. Eventual production of electricity via steam cycle limits the thermal-to-electric conversion efficiencies of CSP plants between 30 - 40%, thereby hampering CSP from becoming competitive to low-cost PVs. By increasing the maximum cycle temperature to 850–1000oC efficiencies of 53% would be achievable in an air-Brayton/Rankine Combined Cycle giving CSP a unique competitive edge.
For 24/7 power supply, a thermal energy storage (TES) system to provide heat when sun is unavailable but demand for electricity remains, is a “must”. The temperature level of the stored heat is limited by the thermal resilience of the HTF, being currently ca. 560/450 oC for state-of-the-art molten salt or thermal oil heat storage units, respectively.
The objectives of ABraytCSPfuture are to demonstrate an innovative, carbon-neutral way for implementing into air-operated CSP plants the much more efficient air-Brayton gas turbine cycle, increasing in parallel the plants’ TES capability by rendering their current sensible-only regenerative storage systems to hybrid sensible-Thermochemical storage (TCS) ones. Both will be achieved by exploiting reversible reduction/oxidation (redox) reaction schemes operating between the oxidized and reduced form of a metal oxide. In the thermal reduction step, the higher-valence oxide state under supply of external heat releases oxygen and transforms to the lower-valence form. Exothermic oxidation of the reduced to the oxidized form via air establishes a cyclic, solar energy TCS process. Materials of choice are such of a perovskite structure, comprising low cost, abundant metals. The ambition is to demonstrate, for the first time ever and at a proof-of-concept level, this radically new idea by the development and operation of a first-of-its-kind, compact, dual-bed thermochemical reactor/heat exchanger, comprised of non-moving, flow-through porous ceramic structures based on such perovskite redox oxides, raising in parallel the temperature to levels required for gas turbine cycles by performing the exothermic oxidation with pressurized air shifting its equilibrium to higher temperatures.