Tech for use in Advanced Reactors vs. Existing Fleet
The objective of this project was to provide FEI with design recommendations for the implementation of nuclear material accountancy and enable FEI to meet its sustainability and operational goals for the LFTR.
Liquid Fluoride Thorium Reactor (LFTR) Preliminary Safeguards Assessment, Flibe Energy Read More »
The goal of this project was to develop a method for analyzing the oxygen content using a commercial inert gas fusion analyzer. This included the development of a calibration curve for the method, quantification of its performance, and testing on FLiBe samples from several sources, including ORNL-produced FLiBe as well as Kairos Power Flibe.
Chemical Method Development for Quantifying Oxygen in Beryllium Salts, Kairos Power Read More »
General Electric-Hitachi, Argonne National Laboratory and the Idaho National Laboratory provided improved operational guidance for the current and advanced BWR off-gas system designs and identified off-gas system design improvements for use in BWR SMRs.
The objective of this project was to improve nuclear power generation’s safety and competitiveness by providing robust information about the flow patterns and formations throughout the simulated fluid domain.
The objective of this project was to determine if currently available technology can be used to modernize the PSP to a level of cost-effectiveness to realize the potential cost saving in the nuclear fuel cycle.
Elysium intended to demonstrate the viability, safety, and economic improvement of using spent nuclear fuel and plutonium in molten chloride salt fast reactor fuel salt. A main objective was to eliminate waste and close the fuel cycle, thereby minimizing proliferation, in addition to providing dispatchable power complementary to renewables.
Oak Ridge National Laboratory (ORNL) worked with Westinghouse Electric Co. to optimize AFA steels for applications specific to LFRs, as reliable materials for key components such as fuel rod cladding, heat exchangers, reactor internals and the reactor vessel.
This project will enable NexDefense to evaluate their existing software on a production nuclear test bed, hence laying the path for future commercial adoption.
Nuclear Cybersecurity Initiative, NexDefense Inc. Read More »
The objective of this project was to measure thermophysical property data for molten salt compositions characteristic of those proposed for use in the ThorCon molten salt reactor. The measured property data support reactor design activities and safety case development.
The objective of this project was to test the Enduray Vision System developed by Vega Wave Systems Inc., using 3 MeV X-rays generated by the Van de Graaff system, to assess the radiation tolerance of the system. These tests showed that the Enduray Vision System was 10× more radiation-hard than the best available commercial competitor in terms of dose rate and can easily sustain radiation dose rates and total doses seen in the most extreme commercial applications in the nuclear energy industry.
Radiation Testing for Nuclear Inspection Systems, Vega Wave Systems Read More »
