Nanostructured surface activated ultra-thin oxygen transport membraneActivity Code: NMP-2008-2.1-1
Coordinator: Dr Wilhelm A. Meulenberg, Institute of Energy Research I, Forschungszentrum Jülich
Sufficiently high oxygen fluxes shall be obtained by:
The major advantages of OTM are significantly lower efficiency losses than conventional technologies and the in principle infinite oxygen selectivity. OCM produces higher hydrocarbons directly without forming CO2 and HCN synthesis can be improved by process intensification resulting in energy and subsequent CO2 savings.
End Date: 31.08.2012
EU Contribution: 3.2 Mio. Euro
Total Costs: 4.98 Mio. Euro
Funding Scheme: Small or medium-scale focused research project
Administrative Contact Person: Dr Klaus Hoppstock,
k.hoppstock@fz-juelich.de
Scientific Coordinator: Dr Wilhelm A. Meulenberg,
w.a.meulenberg@fz-juelich.de
Project Website:http://www.nasa-otm.eu/
Coordinator: Dr Wilhelm A. Meulenberg, Institute of Energy Research I, Forschungszentrum Jülich
Abstract:
The main objective of the proposed project is the development and industry-driven evaluation of highly stable and highly oxygen-permeable nano-structured oxygen transport membrane (OTM) assemblies with infinite selectivity for oxygen separation from air. The new approach proposed to reach this objective is the development of ultra thin membrane layers by e.g. CVD, PVD or Sol-Gel techniques with catalytic activation of the surfaces. This approach is supposed to make available highly stable membrane materials, which are currently out of discussion as the oxygen permeation measured on thick membranes is too low.Sufficiently high oxygen fluxes shall be obtained by:
- ultra thin membrane layers on porous supports to minimize diffusion barriers;
- catalytic surface activation to overcome slow surface exchange/reaction kinetics; and
- thin-film nano-structuring, generating new diffusion paths through the grain boundaries in a nano-crystalline matrix.
The major advantages of OTM are significantly lower efficiency losses than conventional technologies and the in principle infinite oxygen selectivity. OCM produces higher hydrocarbons directly without forming CO2 and HCN synthesis can be improved by process intensification resulting in energy and subsequent CO2 savings.
Project Details:
Start Date: 01.09.2009End Date: 31.08.2012
EU Contribution: 3.2 Mio. Euro
Total Costs: 4.98 Mio. Euro
Funding Scheme: Small or medium-scale focused research project
Administrative Contact Person: Dr Klaus Hoppstock,
k.hoppstock@fz-juelich.de
Scientific Coordinator: Dr Wilhelm A. Meulenberg,
w.a.meulenberg@fz-juelich.de
Project Website:http://www.nasa-otm.eu/
Partners:
- Forschungszentrum Jülich, Germany
- Instalaciones Inabensa SA, Spain
- BASF, Germany
- Latvijas Universitātes Cietvielu fizikas institūts, Latvia
- The University of Queensland, USA
- Gottfried Wilhelm Leibniz Universität Hannover, Germany
- Consejo Superior de Investigaciones Cientificas, Spain
- Danmarks Tekniske Universitet, Denmark