NEXT-CSP | High Temparature concentrated solar thermal power plan with particle receiver and direct thermal storage

Summary
According to the Integrated Roadmap of the Set-plan, and to reach the new EU target of 27% of renewable energies in 2030, there is the need to rapidly expand the use of all renewable energy sources in Europe to accelerate the fight against global climate change. This requires the acceleration of development of new options that are emerging today, particularly, technologies that solve the key issue of energy storage.
The next-CSP Project is a response to this need and addresses significant improvements in all three elements targeted by the LCE-07-2016 call related to concentrated solar power: heat transfer fluids, which can be used for direct thermal energy storage; the solar field; and high temperature receivers allowing for new cycles. The proposed fluidized particle-in-tube concept is a breakthrough innovation that opens the route to the development of a new generation of CSP plants allowing high efficiency new cycles (50% and more) and 20% improvement of CSP plant efficiency.
The Next-CSP technology that cumulates the know-how acquired during the CSP2 FP7 EU project on the particle-in-tube technology can be rapidly cost-competitive and introduced in the market. A cost reduction by 38% is expected with respect to current CSP electricity cost.
The project will demonstrate at industrial pilot scale (TRL5) the validity of the particle-in-tube concept atop the Themis facility solar tower. A 4-MWth tubular solar receiver able to heat particles up to 800°C will be constructed and tested as well as the rest of the loop: a two-tank particle heat storage and a particle-to-pressurized air heat exchanger coupled to a 1.2 MWel gas turbine.
A commercial scale power plant (150 MWel) will also be designed on the basis of experimental and simulation results and associated costs assessed. The consortium includes 6 companies that will lead the development of the first worldwide demonstration of this innovative technology and pave the way for future commercial exploitation.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/727762
Start date: 01-10-2016
End date: 30-09-2020
Total budget - Public funding: 4 947 420,00 Euro - 4 947 420,00 Euro
Cordis data

Original description

According to the Integrated Roadmap of the Set-plan, and to reach the new EU target of 27% of renewable energies in 2030, there is the need to rapidly expand the use of all renewable energy sources in Europe to accelerate the fight against global climate change. This requires the acceleration of development of new options that are emerging today, particularly, technologies that solve the key issue of energy storage.
The next-CSP Project is a response to this need and addresses significant improvements in all three elements targeted by the LCE-07-2016 call related to concentrated solar power: heat transfer fluids, which can be used for direct thermal energy storage; the solar field; and high temperature receivers allowing for new cycles. The proposed fluidized particle-in-tube concept is a breakthrough innovation that opens the route to the development of a new generation of CSP plants allowing high efficiency new cycles (50% and more) and 20% improvement of CSP plant efficiency.
The Next-CSP technology that cumulates the know-how acquired during the CSP2 FP7 EU project on the particle-in-tube technology can be rapidly cost-competitive and introduced in the market. A cost reduction by 38% is expected with respect to current CSP electricity cost.
The project will demonstrate at industrial pilot scale (TRL5) the validity of the particle-in-tube concept atop the Themis facility solar tower. A 4-MWth tubular solar receiver able to heat particles up to 800°C will be constructed and tested as well as the rest of the loop: a two-tank particle heat storage and a particle-to-pressurized air heat exchanger coupled to a 1.2 MWel gas turbine.
A commercial scale power plant (150 MWel) will also be designed on the basis of experimental and simulation results and associated costs assessed. The consortium includes 6 companies that will lead the development of the first worldwide demonstration of this innovative technology and pave the way for future commercial exploitation.

Status

CLOSED

Call topic

LCE-07-2016-2017

Update Date

26-10-2022
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Horizon 2020
H2020-EU.3. SOCIETAL CHALLENGES
H2020-EU.3.3. SOCIETAL CHALLENGES - Secure, clean and efficient energy
H2020-EU.3.3.2. Low-cost, low-carbon energy supply
H2020-EU.3.3.2.0. Cross-cutting call topics
H2020-LCE-2016-RES-CCS-RIA
LCE-07-2016-2017 Developing the next generation technologies of renewable electricity and heating/cooling
H2020-LCE-2017-RES-RIA-TwoStage
LCE-07-2016-2017 Developing the next generation technologies of renewable electricity and heating/cooling