Descripción del proyecto
Energía solar las veinticuatro horas gracias al azufre
El almacenamiento efectivo a largo plazo de la energía solar resulta fundamental para la plena transición de las centrales eléctricas de combustibles fósiles a las fuentes de energía renovables. El equipo del proyecto PEGASUS, financiado con fondos europeos, pretende desarrollar una torre solar de demostración que funcione las veinticuatro horas del día y aproveche el azufre para almacenar termoquímicamente energía renovable. Las actividades en el proyecto incluirán el desarrollo y funcionamiento de prototipos de componentes fundamentales, como un receptor centrífugo solar de partículas y un evaporador y biorreductor de ácido sulfúrico. Además, se desarrollarán y evaluarán materiales adecuados para su uso en la captación, transferencia y almacenamiento de calor solar. Las pruebas solares y el funcionamiento integrado del receptor con el evaporador y el biorreductor se llevarán a cabo en el Centro Aeroespacial Alemán.
Objetivo
PEGASUS (Renewable Power Generation by Solar Particle Receiver Driven Sulphur Storage Cycle) will investigate a novel power cycle for renewable electricity production applying a solar particle receiver with a sulphur storage system for baseload operation. The proposed process combines solid particles as heat transfer fluid that can also be used for direct thermal energy storage with indirect thermochemical storage of solar energy in solid sulphur, rendering thus a solar power plant capable of round-the-clock renewable electricity production. Concepts of solar sulphur power plants will be developed and a flowsheet analysis in conjunction with a techno-economic study will be carried out to simulate the performance of the process. Prototypes of the key components (i.e. solar centrifugal particle receiver, sulphuric acid evaporator, sulphur trioxide decomposer and sulphur combustor) will be developed, constructed and operated at relevant scale. On-sun testing of the particle receiver will be carried out in the newly constructed high-flux solar simulator of the German Aerospace Center (DLR) in Juelich, Germany. Furthermore, an integrated operation of the receiver together with the evaporator and the decomposer will be realised in this facility to demonstrate the suitability of the concept. In addition, materials to be used simultaneously as solar heat capture, transfer and storage media as well as catalytic particles in the solar receiver, evaporator and decomposer will be developed, tested and analysed with respect to reaction kinetics and long-term stability. Moreover, system models of the key components will be implemented, validated with experimental data and applied to simulate the performance of the process components. These models will be integrated into the developed flowsheets for the above mentioned process simulations and techno-economics to predict the prospects of the technology.
Ámbito científico
Programa(s)
Convocatoria de propuestas
Consulte otros proyectos de esta convocatoriaConvocatoria de subcontratación
H2020-LCE-2016-RES-CCS-RIA
Régimen de financiación
RIA - Research and Innovation actionCoordinador
51147 Koln
Alemania