Teilvorhaben 2: „Ökonomische und Ökologische Analyse“ (Flex2BioMethane)
Third Party Funds Group - Sub project
Acronym: Flex2BioMethane
Start date : 01.10.2025
End date : 30.09.2027
Overall project details
Overall project
Katalytische Direktmethanisierung und Produktgasrückführung in den Fermenter zur Flexibilisierung von Biogasanlagen: Konzeptionelle Optimierung sowie Bewertung der ökonomischen Tragfähigkeit und praktischen Umsetzbarkeit
Project details
Short description
Short description
Due to the increasing expansion of renewable energies, the German electricity supply system is undergoing a period of transition. Germany’s future energy system will be based on fluctuating renewable energies, primarily wind and solar energy, which will create an increasing demand for flexible and controllable generation plants. Flexible biogas plants offer one way of balancing out fluctuating generation. In the successfully completed project “FlexBiomethane”, the Technical University of Ingolstadt, the Friedrich-Alexander University of Erlangen-Nuremberg and regineering GmbH have already developed an innovative approach to increasing the flexibility of biogas plants. Biogas is continuously extracted from the fermenters/biogas storage tanks, the CO2 contained in the biogas is converted into methane using hydrogen produced from surplus electricity, and then returned to the fermenter. The methane content in the existing biogas storage tank is continuously increased, while at the same time the fermenter is heated by returning the hot product gas from the methanisation reactor and the substrate in the fermenter is mixed. As a result, both heating and stirring energy can be saved. Catalytic direct methanisation and product gas recirculation into the fermenter thus enable the storage of surplus electricity and its feed-in into the power grid as required. Product gas recirculation allows the methane content in the biogas storage tank to be increased to up to 85–90 vol.%. The FlexBiomethane project successfully demonstrated the basic functionality of the concept, but also raised a number of questions that are very important for the commercial implementation of the project.
Building on FlexBiomethane, the follow-up project Flex2Biomethane will focus on conceptual, procedural and economic optimisation of the concept with a view to achieving electricity grid-compatible, economical and efficient operation and the practical implementation of the concept for direct methanisation and recirculation of the product gas into the fermenter.
Once the research project has been successfully completed, all the necessary energy, economic, ecological and legal information will be available to implement the concept at a real biogas plant.
Scientific Abstract
Due to the increasing expansion of renewable energies, the German electricity supply system is undergoing a period of transition. Germany’s future energy system will be based on fluctuating renewable energies, primarily wind and solar energy, which will create an increasing demand for flexible and controllable generation plants. Flexible biogas plants offer one way of balancing out fluctuating generation. In the successfully completed project “FlexBiomethane”, the Technical University of Ingolstadt, the Friedrich-Alexander University of Erlangen-Nuremberg and regineering GmbH have already developed an innovative approach to increasing the flexibility of biogas plants. Biogas is continuously extracted from the fermenters/biogas storage tanks, the CO2 contained in the biogas is converted into methane using hydrogen produced from surplus electricity, and then returned to the fermenter. The methane content in the existing biogas storage tank is continuously increased, while at the same time the fermenter is heated by returning the hot product gas from the methanisation reactor and the substrate in the fermenter is mixed. As a result, both heating and stirring energy can be saved. Catalytic direct methanisation and product gas recirculation into the fermenter thus enable the storage of surplus electricity and its feed-in into the power grid as required. Product gas recirculation allows the methane content in the biogas storage tank to be increased to up to 85–90 vol.%. The FlexBiomethane project successfully demonstrated the basic functionality of the concept, but also raised a number of questions that are very important for the commercial implementation of the project.
Building on FlexBiomethane, the follow-up project Flex2Biomethane will focus on conceptual, procedural and economic optimisation of the concept with a view to achieving electricity grid-compatible, economical and efficient operation and the practical implementation of the concept for direct methanisation and recirculation of the product gas into the fermenter.
Once the research project has been successfully completed, all the necessary energy, economic, ecological and legal information will be available to implement the concept at a real biogas plant.
