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Ceramic Coatings for PBR Components

Published online by Cambridge University Press:  22 February 2011

Robert. E. Barletta ,
H. Ludewig ,
J. R. Powell  and
P. E. Vanier
Robert. E. Barletta
Affiliation:
Brookhaven National Laboratory, Upton, NY 11973
H. Ludewig
Affiliation:
Brookhaven National Laboratory, Upton, NY 11973
J. R. Powell
Affiliation:
Brookhaven National Laboratory, Upton, NY 11973
P. E. Vanier
Affiliation:
Brookhaven National Laboratory, Upton, NY 11973
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Abstract

Particle bed reactors (PBRs) have the potential for providing compact power sources for both space power and propulsion applications. The reactors operate in the temperature range of 2000 to 3000 K and, for propulsion systems, utilize hydrogen as a coolant. Given these overall operating conditions, the need exists to develop and verify the performance of various reactor components, particularly those which must operate at the more extreme conditions of temperature and hydrogen flow rate. These components must undergo multiple thermal cycles between cryogenic and exit temperatures. In addition, some of the components are subject to a thermal gradient of thousands of degrees Kelvin over a few centimeters.

A number of approaches directed towards meeting these needs have been developed. These include both monolithic ceramics (e.g. boron nitride) as well as coated composites consisting of refractory carbides (ZrC, NbC and TaC) on carbon-based substrates. Full and partial scale components have been fabricated and tested under prototypic conditions. The results of this developmental effort will be described.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 327: Symposium N – Covalent Ceramics II: Non-Oxides , 1993 , 177
Copyright
Copyright © Materials Research Society 1994

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References

1. Ludewig, H., “Summary of Particle Bed ReactorDesigns for the Space Nuclear Thermal Propulsion Program”, BNL Informal Report, BNL-52408, 1994.Google Scholar
2. Powell, J., Ludewig, H., Maise, G., Steinberg, M., Todosow, M., “High Flux Particle Bed Reactor Systems for Rapid Transmutation of Actinides and Long Lived Fission Products”, presented at Global '93, Future Nuclear Systems : Emerging Fuel Cycles & Waste Disposal Options, Seattle, 1993.Google Scholar
3. Rey, M. C. and Bartlett, M. W., “Machining and Testing of Hot Frits - Hoop Compression Testing”, FMI Final Contract Report for contract 424528, 1990.Google Scholar
4. Elliot, R. P., Constitution of Binary Alloys. First Supplement (Genium Publishing Schenectady, 1985) pp. 226–7.Google Scholar
5. Vanier, P. E., Barletta, R., Adams, J. and Svandrlik, J., “Testing of Protective Coatings in Hydrogen”, BNL Informal Report, BNL 49386, 1993.Google Scholar
6. Barletta, R. E., P. E., , Vanier, J. W., Adams, J. F. Svandrlik and Powell, J. R., “Performance of Carbon Based Hot Frit Substrates. 2. Coating Performance Studies in Hydrogen at Atmospheric Pressure”, BNL Informal Report, BNL-49385, 1993.Google Scholar
7. Adams, J. W., Barletta, R. E., Svandrlik, J. and Vanier, P. E., “Performance of CVD and CVR Coated Carbon-Carbon in High Temperature Hydrogen”, in Covalent Ceramics II: Non-Oxides, editied by Barron, A. R. (Mat. Res. Soc. Proc. 327, Pittsburgh, PA, 1994).Google Scholar