There are multiple steps involved in traditional fuel manufacturing methods in order to convert raw uranium ore into UF6, then into uranium dioxide (UO2) to be used in a light-water reactor’s final fuel. But the AMAFT process, which uses a novel hybrid laser engineering shaping technique to make a small, localized melt pool out of multiple powder sources so a pellet of dense U3Si2 fuel is directly formed, decreases these steps by removing the pre-processing of UF6 to convert it to UO2.Dr. Van Rooyen, a staff scientist in INL’s Fuel Design & Development department, explained, “AMAFT technology uses a novel hybrid additive manufacturing process, which means we combine some traditional and some additive manufacturing processes to reduce the number of steps – and therefore the time and cost – involved in producing fuel for power reactors.”
U3Si2 has the potential to become a better advanced fuel, with greater safety benefits, than the traditional fuels most nuclear power plants use that are based in UO2, due to its great thermal conductivity and density. These qualities help improve economics as well as safety margins.
The hybrid AMAFT process can begin with any feedstock based in uranium – this is what gets rid of the conversion steps and opens the supply chain to other materials. When combined with other advanced manufacturing processes, AMAFT offers fabricators more flexibility, including the option of using different raw materials. Together with University of Florida PhD candidate Jhonathan Rosales, who worked on characterization activities for the development products, Dr. Van Rooyen and Parga are working to make AMAFT easily scalable, which is an important requirement to become commercially viable.
As the innovative AMAFT process moves closer and closer to the market, the INL researchers are working on some benchtop experiments with a pulsed laser and surrogate material. The team, while working out the technical development of the novel fabrication process, is also participating in the DOE’s Energy I-Corps initiative.The initiative partners industry mentors with DOE researchers to further refine their concepts in order to support the specific needs of possible customers.
“It was a surprise to learn how critical partnerships would be to the overall commercialization process,” said Dr. Van Rooyen, the principal investigator for the AMAFT Energy I-Corps team. “Energy I-Corps was an opportunity to think outside the box from our normal everyday research mindset.”
Industry mentor Ed Lahoda and entrepreneurial lead Dr. George Griffith rounded out the rest of the AMAFT Energy I-Corps team.
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[Source: Phys.org]