Abstract
Advanced manufacturing has the potential to revitalize US manufacturing, with valuable applications in several industries, including aerospace, automotive, and construction. Some of these applications have clear-cut objectives (e.g., maintain component performance while reducing mass). Applications of advanced manufacturing of nuclear components have aimed at recapturing lost manufacturing capabilities or addressing maintenance of legacy reactor components. Through the Department of Energy, Office of Nuclear Energy, Transformational Challenge Reactor design and analysis thrust, applications of advanced manufacturing, in particular, additive manufacturing, to core design has yielded reactor designs that are free from conventional manufacturing constraints. For applications in core design, the multiphysics nature of the key core metrics (e.g., peak temperature, peak power) in addition to transient safety performance requirements provides a more complex set of objectives that requires more advanced modeling and simulation tools. Additive manufacturing provides high dimensional control and design flexibility to produce complex coolant channel shapes for improved heat transfer properties and low peak material temperatures. Additional mechanisms for improved heat transfer characteristics and temperature-controlled feedback mechanisms have also been explored and incorporated into designs. While some of these enhancements are not directly beneficial for the current operating pressurized water reactor fleet, benefits may be realized in specific reactor applications that have a more constrained design space (e.g., mass, size, material type) or design metrics (e.g., fuel utilization).
Highlights
Continued developments in advanced manufacturing technologies are fundamentally altering the way components are designed and manufactured
A manufacturing-informed design approach has the potential to yield the most benefit from the application of advanced manufacturing in the nuclear industry—leveraging advanced materials, data science, and rapid testing and deployment to drive down costs and development times, and improving future commercial viability
This approach is being demonstrated under the US Department of Energy Office of Nuclear Energy (DOE-NE) Transformational Challenge Reactor (TCR) program
Summary
Continued developments in advanced manufacturing technologies are fundamentally altering the way components are designed and manufactured. A manufacturing-informed design approach has the potential to yield the most benefit from the application of advanced manufacturing in the nuclear industry—leveraging advanced materials, data science, and rapid testing and deployment to drive down costs and development times, and improving future commercial viability This approach is being demonstrated under the US Department of Energy Office of Nuclear Energy (DOE-NE) Transformational Challenge Reactor (TCR) program. An understanding of complex dynamic behaviors and feedback mechanisms is necessary to quantify conditions during steady-state operation and during potential transient scenarios to ensure fission product retention and safe reactor operation These complex physics behaviors and rigorous requirements drive reactor design and the development of modeling and simulation methods: the simulation of this complex physics problem is simplified for repeating core geometries. It is not intended as a complete discussion of potential applications or quantification of the benefits from this manufacturinginformed approach, but it is a discussion of the potential benefits for desired reactor metrics
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