UNDERSTANDING CHARGE MASS AND HEAT TRANSFER IN FUEL CELLS FOR TRANSPORT APPLICA...
UNDERSTANDING CHARGE MASS AND HEAT TRANSFER IN FUEL CELLS FOR TRANSPORT APPLICATIONS
The CAMELOT proposal brings together highly experienced research institutes (SINTEF, IMTEK), universities (TUC), fuel cell MEA suppliers (JMFC) and transport OEMs (BMW, FCP) to improve understanding of the limitations in fuel cell...
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31/12/2023
SINTEF
2M€
Presupuesto del proyecto: 2M€
Líder del proyecto
SINTEF AS
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Información proyecto CAMELOT
Duración del proyecto: 48 meses
Fecha Inicio: 2019-12-12
Fecha Fin: 2023-12-31
Líder del proyecto
SINTEF AS
No se ha especificado una descripción o un objeto social para esta compañía.
Presupuesto del proyecto
2M€
Fecha límite de participación
Sin fecha límite de participación.
Descripción del proyecto
The CAMELOT proposal brings together highly experienced research institutes (SINTEF, IMTEK), universities (TUC), fuel cell MEA suppliers (JMFC) and transport OEMs (BMW, FCP) to improve understanding of the limitations in fuel cell electrodes.
Based on previous FCH2JU projects, the consortium is uniquely positioned to investigate ultra-thin, ultra-low loading layers needed for the next generation of MEAs. CAMELOT will use a combination of numerical modelling and advanced in situ characterisation to build a scientific understanding of the limitations on state of the art MEAs. Camelot will update an open source simulation tool (FFC) to accurately describe the charge, mass and heat transport mechanisms in SOA materials with the latest MEA designs. This tool will enable the partners to investigate the impact of new MEA designs at the single repeat unit level, providing guidance on the next generation of MEA enabling the performance required by the 2024 MAWP.
The presence of two OEMs and an MEA manufacturer will ensure that the modelling results are validated on the latest generation of fuel cell hardware and are directly exploitable by the industry. Dissemination will also play an important role thanks to the use of an open source model, meaning that the scientific developments in the project will be easily available for the global fuel cell community to exploit.