Summary
As prevention strategies are struggling with respect to some waste categories, biogenic hard-to-recycle streams represent a critical issue, hindering circular bioeconomy and resulting in severe environmental pollution phenomena. The Waste Framework Directive and the EU Green Deal indicate the need for developing pioneering value chains to address the challenge in compliance with sustainability targets. A set of promising thermochemical processes emerged, both in dry (pyrolysis, gasification) and wet aqueous (hydrothermal carbonisation, hydrothermal liquefaction) phases, with their application still limited by technical and non-technical barriers.
The UPCYCLE DN will train the next generation of professionals in the upscaling of these deep conversion technologies for hard-to-recycle biogenic waste and will provide innovative tools for the design of feasible waste upcycle solutions to high-value secondary materials. Such ambition will be achieved by developing an integrated methodology combining cutting-edge experimental and modelling techniques at various scales (molecular, reactor and process) and by covering the entire value chain in continuity with relevant stakeholders. Several priority waste streams will be targeted, namely highly contaminated and poorly reactive sewage sludge and derived products from municipal and industrial wastewater treatment as well as highly contaminated lignocellulosic materials.
The UPCYCLE partners will work synergistically to generate a cohort of 15 well-trained young researchers with a unique multi-disciplinary set of skills, not limited to technical ones, with the goal of making them the future research leaders or entrepreneurs capable of bringing forward a paradigm shift. At once, the project will pave the way for large-scale deployment of sustainable technologies on which a new generation of biorefineries could rely.
The UPCYCLE DN will train the next generation of professionals in the upscaling of these deep conversion technologies for hard-to-recycle biogenic waste and will provide innovative tools for the design of feasible waste upcycle solutions to high-value secondary materials. Such ambition will be achieved by developing an integrated methodology combining cutting-edge experimental and modelling techniques at various scales (molecular, reactor and process) and by covering the entire value chain in continuity with relevant stakeholders. Several priority waste streams will be targeted, namely highly contaminated and poorly reactive sewage sludge and derived products from municipal and industrial wastewater treatment as well as highly contaminated lignocellulosic materials.
The UPCYCLE partners will work synergistically to generate a cohort of 15 well-trained young researchers with a unique multi-disciplinary set of skills, not limited to technical ones, with the goal of making them the future research leaders or entrepreneurs capable of bringing forward a paradigm shift. At once, the project will pave the way for large-scale deployment of sustainable technologies on which a new generation of biorefineries could rely.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101169472 |
| Start date: | 01-02-2025 |
| End date: | 31-01-2029 |
| Total budget - Public funding: | - 3 790 184,00 Euro |
Cordis data
Original description
As prevention strategies are struggling with respect to some waste categories, biogenic hard-to-recycle streams represent a critical issue, hindering circular bioeconomy and resulting in severe environmental pollution phenomena. The Waste Framework Directive and the EU Green Deal indicate the need for developing pioneering value chains to address the challenge in compliance with sustainability targets. A set of promising thermochemical processes emerged, both in dry (pyrolysis, gasification) and wet aqueous (hydrothermal carbonisation, hydrothermal liquefaction) phases, with their application still limited by technical and non-technical barriers.The UPCYCLE DN will train the next generation of professionals in the upscaling of these deep conversion technologies for hard-to-recycle biogenic waste and will provide innovative tools for the design of feasible waste upcycle solutions to high-value secondary materials. Such ambition will be achieved by developing an integrated methodology combining cutting-edge experimental and modelling techniques at various scales (molecular, reactor and process) and by covering the entire value chain in continuity with relevant stakeholders. Several priority waste streams will be targeted, namely highly contaminated and poorly reactive sewage sludge and derived products from municipal and industrial wastewater treatment as well as highly contaminated lignocellulosic materials.
The UPCYCLE partners will work synergistically to generate a cohort of 15 well-trained young researchers with a unique multi-disciplinary set of skills, not limited to technical ones, with the goal of making them the future research leaders or entrepreneurs capable of bringing forward a paradigm shift. At once, the project will pave the way for large-scale deployment of sustainable technologies on which a new generation of biorefineries could rely.
Status
SIGNEDCall topic
HORIZON-MSCA-2023-DN-01-01Update Date
01-10-2024
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Geographical location(s)
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Organisations
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| Politecnico di Milano (Coördinator)
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| CAP HOLDING SPA
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| CARBOREM S.R.L.
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| INGELIA SL
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| IOS, INSTITUT ZA OKOLJEVARSTVO IN SENZORJE, PROIZVODNJA, TRGOVINA IN STORITVE DOO
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| Indaver
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| KATHOLIEKE UNIVERSITEIT LEUVEN
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| NEXTCHEM SPA
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| SULZER MANAGEMENT AG
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| TECHNISCHE UNIVERSITAT DARMSTADT
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| UNIVERSIDAD REY JUAN CARLOS
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| UNIVERSITA DEGLI STUDI DI ROMA LA SAPIENZA
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| University of Ljubljana, Faculty of Mechanical engineering
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| Vyncke