|dc.contributor.author||Memmott, Matthew J.||
|dc.contributor.other||Advanced Nuclear Power Technology Program (Massachusetts Institute of Technology)||en_US
|dc.description.abstract||The sodium fast reactor (SFR) is currently being reconsidered as an instrument for
actinide management throughout the world, thanks in part to international programs such
as the Generation-IV and especially the Global Nuclear Energy Partnership (GNEP). The
success of these programs, in particular the GNEP, is dependent upon the ability of the
SFR to manage actinide inventory while remaining economically competitive. In order to
achieve these goals, the fuel must be able to operate reliably at high power densities.
However, the power density of the fuel is limited by fuel-clad chemical interaction
(FCCI) for metallic fuel, cladding thermal and irradiation strain, the fuel melting point,
sodium boiling, and to a lesser extent the sodium pressure drop in the fuel channels.
Therefore, innovative fuel configurations that reduce clad stresses, sodium pressure
drops, and fuel/clad temperatures could be applied to the SFR core to directly improve
the performance and economics. Two particular designs of interest that could potentially
improve the performance of the SFR core are the internally and externally cooled annular
fuel and the bottle-shaped fuel.
In order to evaluate the thermal-hydraulic performance of these fuels, the capabilities of
the RELAP5-3D code have been expanded to perform subchannel analysis in sodiumcooled
fuel assemblies with non-conventional geometries. This expansion was enabled by
the use of control variables in the code. When compared to the SUPERENERGY II code,
the prediction of core outlet temperature agreed within 2%. In addition, the RELAP5-3D
subchannel model was applied to the ORNL 19-pin test, and it was found that the code
could predict the measured outlet temperature distribution with a maximum error of ~8%.
As an application of this subchannel model, duct ribs were explored as a means of
reducing core outlet temperature peaking within the fuel assemblies. The performance of
the annular and bottle-shaped fuel was also investigated using this subchannel model.
The annular fuel configurations are best suited for low conversion ratio cores. The
magnitude of the power uprate enabled by metal annular fuel in the CR = 0.25 cores is
20%, and is limited by the FCCI constraint during a hypothetical flow blockage of the
inner-annular channel due to the small diameters of the inner-annular flow channel (3.6
mm). On the other hand, a complete blockage of the hottest inner-annular flow channel in
the oxide fuel case results in sodium boiling, which renders the annular oxide fuel
concept unacceptable for use in a SFR. The bottle-shaped fuel configurations are best
suited for high conversion ratio cores. In the CR = 0.71 cores, the bottle-shaped fuel
configuration reduces the overall core pressure drop in the fuel channels by up to 36.3%.
The corresponding increase in core height with bottle-shaped fuel is between 15.6% and
A full-plant RELAP5-3D model was created to evaluate the transient performance of the
base and innovative fuel configurations during station blackout and UTOP transients. The
transient analysis confirmed the good thermal-hydraulic performance of the annular and
bottle-shaped fuel designs with respect to their respective solid fuel pin cases.||en_US
|dc.description.sponsorship||Idaho National Laboratory||en_US
|dc.description.sponsorship||United States. Dept. of Energy||en_US
|dc.description.sponsorship||U.S. Nuclear Regulatory Commission||en_US
|dc.publisher||Massachusetts Institute of Technology. Center for Advanced Nuclear Energy Systems. Advanced Nuclear Power Program||en_US
|dc.title||Thermal-Hydraulic Analysis of Innovative Fuel Configurations for the Sodium Fast Reactor||en_US
|dc.contributor.mitauthor||Memmott, Matthew J.||
|dspace.orderedauthors||Memmott, Matthew J.; Hejzlar, Pavel; Buongiorno, Jacopo||en_US