EffiTorch | Efficient valorisation of CO2 and bio-waste for long-term energy storage using a microwave plasma torch and quenching using the reverse Boudouard reaction

Summary
Now that renewable energy generation is already competitive in cost with electricity obtained from fossil fuels, the development of efficient long term energy storage methods seems crucial for a faster transition to a net-zero greenhouse gas emissions EU economy. Power-to-X methods are promising due to their negligible discharge rate but up to now all the efforts have been based on the use of H2 obtained by electrolysis, and the TEAs have shown that the high cost of the electrolysers hinders greatly its possibilities of industrial use.
EffiTorch aims at developing an alternative breakthrough technology for Power-to-X based on the direct splitting of CO2, using an ultra-high temperature thermal plasma, with the simultaneous valorisation of low value bio-waste, leading to the efficient production of syngas. EffiTorch aims to reach carbon efficiencies higher than 90% and energy efficiencies higher than 60%, outperforming the best solutions available presently.
Some of the research groups in Effitorch have a vast experience in CO2 splitting using Microwave (MW) plasma torches. Nevertheless, recently a compound approach that combines CO2 splitting by thermal plasmas with a quenching using the very endothermic reverse Bouduard reaction (RBR) has been developed in China that vastly improves the promising results obtained in the splitting of CO2 , while solving one of the yet unresolved issues, that of the efficient separation of the gases obtained.
EffiTorch aims to explore the possibilities offered by a much improved version of the experimental set-ups used by the Chinese groups, including additional sophistications like the ultrasonic atomization of a bio-oil obtained by Hydrothermal Liquefaction (HTL) from sewage sludge, the use of high temperature reactors with plasma confinement and the implementation of a secondary heating of the plasma by induction with HF frequency (100-400 KHz), that could improve the energy efficiency and reduce costs.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/101172766
Start date: 01-10-2024
End date: 30-09-2028
Total budget - Public funding: 2 980 222,50 Euro - 2 980 222,00 Euro
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Original description

Now that renewable energy generation is already competitive in cost with electricity obtained from fossil fuels, the development of efficient long term energy storage methods seems crucial for a faster transition to a net-zero greenhouse gas emissions EU economy. Power-to-X methods are promising due to their negligible discharge rate but up to now all the efforts have been based on the use of H2 obtained by electrolysis, and the TEAs have shown that the high cost of the electrolysers hinders greatly its possibilities of industrial use.
EffiTorch aims at developing an alternative breakthrough technology for Power-to-X based on the direct splitting of CO2, using an ultra-high temperature thermal plasma, with the simultaneous valorisation of low value bio-waste, leading to the efficient production of syngas. EffiTorch aims to reach carbon efficiencies higher than 90% and energy efficiencies higher than 60%, outperforming the best solutions available presently.
Some of the research groups in Effitorch have a vast experience in CO2 splitting using Microwave (MW) plasma torches. Nevertheless, recently a compound approach that combines CO2 splitting by thermal plasmas with a quenching using the very endothermic reverse Bouduard reaction (RBR) has been developed in China that vastly improves the promising results obtained in the splitting of CO2 , while solving one of the yet unresolved issues, that of the efficient separation of the gases obtained.
EffiTorch aims to explore the possibilities offered by a much improved version of the experimental set-ups used by the Chinese groups, including additional sophistications like the ultrasonic atomization of a bio-oil obtained by Hydrothermal Liquefaction (HTL) from sewage sludge, the use of high temperature reactors with plasma confinement and the implementation of a secondary heating of the plasma by induction with HF frequency (100-400 KHz), that could improve the energy efficiency and reduce costs.

Status

SIGNED

Call topic

HORIZON-CL5-2024-D3-01-10

Update Date

23-12-2024
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Horizon Europe
HORIZON.2 Global Challenges and European Industrial Competitiveness
HORIZON.2.5 Climate, Energy and Mobility
HORIZON.2.5.2 Energy Supply
HORIZON-CL5-2024-D3-01
HORIZON-CL5-2024-D3-01-10 Next generation of renewable energy technologies