Summary
Increasing further the safety of light water nuclear reactors in the new operating conditions induced by their integration in a more varied energy mix brings many new challenges for fuel development. This calls for effective and validated tools enabling one to capture the complexity of the behaviour of fuel elements under various operation conditions from nominal to design basis accident ones.. The objective of the OperaHPC proposal is to develop open tools using High Performance Computing (HPC) enabling a full 3D high-fidelity thermo-mechanical simulation of the fuel element including the material microstructure. This will contribute to the design of so-called fuel element digital twins. This development includes an ambitious basic research program devoted to the investigation of non-linear mechanical behaviour of irradiated fuel using multiscale experiments and simulations from the atomic scale up to the material law. This will yield the detailed description of the in-pile behaviour of the fuel element and the materials data necessary for the simulation. The tools developed will be assessed against state-of-the-art 1D/3D fuel performance codes for verification, definition of boundary conditions and coupling with neutronic, thermochemical and thermohydraulic codes. Validation and uncertainty analyses will also be performed through the comparison of the results of the 3D simulations with the experimental data available from irradiation programs. The knowledge from these advanced simulations will be transferred to industrial fuel performance codes thanks to the application of new methods based on reduced order and meta models, including Artificial Intelligence. The HPC tools will finally be applied to the detailed evaluation of innovative fuel element concepts, including (enhanced) accident tolerant fuels, under transient conditions in several light water reactor designs.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101061453 |
| Start date: | 01-11-2022 |
| End date: | 30-04-2027 |
| Total budget - Public funding: | 4 515 551,70 Euro - 2 846 944,00 Euro |
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Original description
Increasing further the safety of light water nuclear reactors in the new operating conditions induced by their integration in a more varied energy mix brings many new challenges for fuel development. This calls for effective and validated tools enabling one to capture the complexity of the behaviour of fuel elements under various operation conditions from nominal to design basis accident ones.. The objective of the OperaHPC proposal is to develop open tools using High Performance Computing (HPC) enabling a full 3D high-fidelity thermo-mechanical simulation of the fuel element including the material microstructure. This will contribute to the design of so-called fuel element digital twins. This development includes an ambitious basic research program devoted to the investigation of non-linear mechanical behaviour of irradiated fuel using multiscale experiments and simulations from the atomic scale up to the material law. This will yield the detailed description of the in-pile behaviour of the fuel element and the materials data necessary for the simulation. The tools developed will be assessed against state-of-the-art 1D/3D fuel performance codes for verification, definition of boundary conditions and coupling with neutronic, thermochemical and thermohydraulic codes. Validation and uncertainty analyses will also be performed through the comparison of the results of the 3D simulations with the experimental data available from irradiation programs. The knowledge from these advanced simulations will be transferred to industrial fuel performance codes thanks to the application of new methods based on reduced order and meta models, including Artificial Intelligence. The HPC tools will finally be applied to the detailed evaluation of innovative fuel element concepts, including (enhanced) accident tolerant fuels, under transient conditions in several light water reactor designs.Status
SIGNEDCall topic
HORIZON-EURATOM-2021-NRT-01-01Update Date
01-11-2023
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EURATOM.1 Nuclear research and training for continuous improvement of nuclear safety, security and radiation protection, and for complementing the achievement of Horizon Europe s objectives inter alia in the context of the energy transition
EURATOM.1.1 Improve and support nuclear safety, security, safeguards, radiation protection, safe spent fuel and radioactive waste management and decommissioning, including the safe and secure use of nuclear power and of non-power applications of ionizing radiation
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Organisations
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| COMMISSARIAT A L ENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES (CEA) (Coördinator)
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| BANGOR UNIVERSITY
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| CENTRO DE INVESTIGACIONES ENERGETICAS, MEDIOAMBIENTALES Y TECNOLOGICAS-CIEMAT
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| ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE (EPFL)
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| ELECTRICITE DE FRANCE (EDF)
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| ENEA - Italian National Agency for New Technologies, Energy and Sustainable Economic Development
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| FRAMATOME
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| JRC -JOINT RESEARCH CENTRE- EUROPEAN COMMISSION
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| KUNGLIGA TEKNISKA HOEGSKOLAN
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| LIETUVOS ENERGETIKOS INSTITUTAS
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| NATIONAL NUCLEAR LABORATORY LIMITED
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| NINE NUCLEAR AND INDUSTRIAL ENGINEERING SRL
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| PAUL SCHERRER INSTITUT (PSI)
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| Politecnico di Milano
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| SINTEC SRL