Transient testing of uranium silicide fuel in zircaloy and silicon carbide cladding

Using the newly restarted Transient Reactor Test (TREAT) facility at Idaho National Laboratories, fresh (unirradiated) U3Si2 fuel pellets were tested under reactivity-initiated accident conditions in dry helium capsules. These tests were performed with total energy depositions sufficient to induce m...

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Bibliographic Details
Published in:Annals of nuclear energy 2021-05, Vol.160
Main Authors: Kamerman, David, Woolstenhulme, Nicolas, Imholte, Devin, Fleming, Austin, Jensen, Colby, Folsom, Charles, Woolum, Connor, Tritthart, Korbin, Schulthess, Jason, Wachs, Dan
Format: Article
Language:English
Subjects:
Irradiation environment
Irradiation testing
NUCLEAR FUEL CYCLE AND FUEL MATERIALS
Nuclear fuel safety research
Nuclear testing
Silicon carbide
Transient testing
Uranium silicide
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Summary:Using the newly restarted Transient Reactor Test (TREAT) facility at Idaho National Laboratories, fresh (unirradiated) U3Si2 fuel pellets were tested under reactivity-initiated accident conditions in dry helium capsules. These tests were performed with total energy depositions sufficient to induce melting of the U3Si2 fuel pellets based on available thermophysical property data. The instrumented experiments utilized in-pile thermocouples and infrared pyrometers to measure the cladding temperature during the transient, which are in reasonable agreement with predicted peak cladding temperatures using a simple BISON fuel performance model. This same model is then used to predict expected cladding stresses during the transients in areas where pellet cladding interaction is expected. It was shown that for transient energy depositions up to 528J/g rod like geometry of the test articles was maintained. While it is acknowledged that more confirmatory testing is required in more prototypic environments, these first of their kind experiments have demonstrated that unirradiated U3Si2 fuel and unirradiated SiC-SiC claddings can likely retain a “rod like” geometry for transient energy depositions up to 528J/g.
ISSN:0306-4549
1873-2100