Research and development (R&D) methodology for the practical use of accident tolerant fuel (ATF) in commercial light water reactors is discussed in the present review. The identification and quantification of the R&D-metrics and the attribute of candidate ATF-concepts, recognition of the gap between the present R&D status and the targeted practical use, prioritization of the R&D, and technology screening schemes are important for achieving a common understanding on technology screening process among stakeholders in the near term and in developing an efficient R&D track toward practical use. Technology readiness levels and attribute guides are considered to be proper indices for these evaluations. In the midterm, the selected ATF-concepts will be developed toward the technology readiness level-5, at which stage the performance of the prototype fuel rods and the practicality of industrial scale fuel manufacturing will be verified and validated. Regarding the screenedout concepts, which are recognized to have attractive potentials, the fundamental R&D should be continued in the midterm to find ways of addressing showstoppers.
[1]
Steven J. Zinkle,et al.
Advanced Oxidation Resistant Iron-Based Alloys for LWR Fuel Cladding
,
2014
.
[2]
Kazuo Minato,et al.
Fission product behavior in Triso-coated UO2 fuel particles
,
1994
.
[3]
C. Lemaignan,et al.
Factors governing microstructure development of Cr2O3-doped UO2 during sintering
,
2001
.
[4]
Theodore M. Besmann,et al.
Uranium Nitride as LWR TRISO Fuel: Thermodynamic Modeling of U-C-N and Thermomechanics
,
2012
.
[5]
Frédéric Schuster,et al.
ASSESSMENT AT CEA OF COATED NUCLEAR FUEL CLADDING FOR LWRS WITH INCREASED MARGINS IN LOCA AND BEYOND LOCA CONDITIONS
,
2013
.
[6]
Paul A. Lessing,et al.
Uranium silicide pellet fabrication by powder metallurgy for accident tolerant fuel evaluation and irradiation
,
2015
.
[7]
Akira Kohyama,et al.
Current status and critical issues for development of SiC composites for fusion applications
,
2007
.