Efficient Additive Manufacturing for Advanced U-X Nuclear Fuel Alloys
ID: BA-894Type: Special Notice
Overview

Buyer

ENERGY, DEPARTMENT OFENERGY, DEPARTMENT OFBATTELLE ENERGY ALLIANCE–DOE CNTRIdaho Falls, ID, 83415, USA

NAICS

Nuclear Electric Power Generation (221113)

PSC

NUCLEAR REACTORS (4470)

Original Source

https://sam.gov/opp/725057c023304c9e9a2ffd8a5f838db6/view
Timeline
    Description

    The Department of Energy, through the Battelle Energy Alliance at the Idaho National Laboratory, is seeking industry partners to license innovative technology for efficient additive manufacturing of advanced U-X nuclear fuel alloys. The objective is to revolutionize the production of U-X compounds, such as U3Si2 and U-Mo alloys, by utilizing a patented Laser Engineered Net Shaping (LENS) process that streamlines manufacturing, reduces costs, and enhances safety compared to traditional methods. This technology is crucial for applications in commercial nuclear reactors, research reactors, and defense and space sectors, facilitating the production of next-generation accident-tolerant fuels. Interested companies should contact the Technology Deployment department at td@inl.gov for collaboration opportunities, as the focus is on licensing rather than procurement or hiring services.

    Point(s) of Contact
    Technology Deployment
    td@inl.gov
    Files
    No associated files provided.
    Lifecycle
    Title
    Type
    Efficient Additive Manufacturing for Advanced U-X Nuclear Fuel Alloys
    Currently viewing
    Special Notice
    Similar Opportunities
    Titanium-Tantalum Alloy Manufacturing for Biomedical and Engineering Applications
    Buyer not available
    The Department of Energy, specifically the Battelle Energy Alliance at the Idaho National Laboratory, is seeking industry partners for the licensing of an innovative electrochemical process for manufacturing titanium-tantalum alloys aimed at biomedical and engineering applications. This process addresses the challenges of traditional manufacturing methods, which are energy-intensive and generate significant waste, by enabling direct synthesis of alloys from metal oxides, thus promoting cost efficiency and sustainability. The technology has potential applications in biomedical devices, high-performance structural materials, and corrosion-resistant coatings, making it a valuable opportunity for companies interested in advancing manufacturing technologies. Interested parties can reach out to the Technology Deployment department at td@inl.gov for further collaboration opportunities.
    Available for Licensing: High-Quality Actinide Thin Films via Molecular Beam Epitaxy for Quantum and Optoelectronic Devices
    Buyer not available
    The Department of Energy is offering a licensing opportunity for high-quality actinide thin films produced via molecular beam epitaxy (MBE), specifically targeting applications in quantum and optoelectronic devices. This innovative process developed by researchers at Idaho National Laboratory (INL) allows for the precise deposition of epitaxial crystalline thin films of uranium and thorium, which are crucial for advancing theoretical and experimental research in complex electron correlations and next-generation computing technologies. The successful integration of these high-quality thin films with existing semiconductor technology presents significant potential for advancements in various high-tech applications, including quantum computing and optoelectronics. Interested parties can reach out to Javier Martinez at javier.martinez@inl.gov for further details regarding this opportunity.
    INL Innovation Spotlight Precision Enhancement for Thermocouples: A Leap in Measurement Accuracy
    Buyer not available
    The Department of Energy, through the Battelle Energy Alliance at the Idaho National Laboratory (INL), is seeking partnerships to commercialize an innovative technology aimed at enhancing the precision of thermocouples, which are critical for accurate temperature measurement across various industries. This technology utilizes ohmic heating to stabilize thermocouples, significantly improving their accuracy and lifespan while addressing the common issue of accuracy drift, particularly in high-temperature or radiation environments. With applications spanning manufacturing, aerospace, energy production, and healthcare, this advancement represents a significant leap in measurement reliability. Interested parties can learn more about licensing opportunities by contacting Andrew Rankin at andrew.rankin@inl.gov.
    High-Temperature Compact Heat Exchangers for Harsh Environments
    Buyer not available
    The Department of Energy, through the Battelle Energy Alliance at the Idaho National Laboratory, is seeking industry partners to license innovative high-temperature compact heat exchangers (CHXs) designed for harsh environments. The objective is to develop CHXs utilizing refractory metal designs with embedded sensors that enhance performance and reliability, addressing critical limitations of existing nickel-based alloy solutions, such as temperature constraints and corrosion issues. These advanced CHXs are crucial for applications in power generation, chemical processing, and metallurgy, offering significant improvements in durability, energy efficiency, and cost savings. Interested parties can reach out to the Technology Deployment department at td@inl.gov for collaboration opportunities.
    TECHNOLOGY/BUSINESS OPPORTUNITY Anisotropic, multi-functional polymeric microparticles additives for polymeric formulation enhancement
    Buyer not available
    The Department of Energy, through the Lawrence Livermore National Laboratory (LLNL), is offering a collaboration opportunity to develop and commercialize anisotropic, multi-functional polymeric microparticles additives aimed at enhancing polymeric formulations. This initiative seeks industry partners capable of advancing a synthetic methodology that utilizes a two-phase high shear mixing protocol to create anisotropic polymer microparticles, which can be integrated into 3D printable Direct Ink Write (DIW) inks. The technology, currently at a Technology Readiness Level (TRL) of 3-5, has potential applications in rheology modification and multifunctionality in DIW inks and prints. Interested companies should submit a statement of interest, including their corporate expertise and contact information, to LLNL's Innovation and Partnerships Office by email or written correspondence, with further details available on their website.
    Precision Steam Generation for High-Temperature Electrolysis
    Buyer not available
    The Department of Energy, specifically the Battelle Energy Alliance at the Idaho National Laboratory, is seeking industry partners to license an innovative technology for Precision Steam Generation aimed at enhancing high-temperature electrolysis systems. The objective is to develop a reliable method for generating hydrogen-steam mixtures that addresses the challenges of fluctuating flow rates and pressure variations, while utilizing low-grade waste heat efficiently. This technology is crucial for hydrogen production and energy efficiency in various applications, including hydrogen electrolysis systems, industrial heating, and renewable energy integration. Interested companies should contact the Technology Deployment department at td@inl.gov for collaboration opportunities, as the focus is on licensing rather than procurement or hiring services.
    Transforming Biomass Preprocessing for Advanced Gasification
    Buyer not available
    The Department of Energy, specifically the Battelle Energy Alliance at the Idaho National Laboratory, is seeking industry partners to license innovative technologies aimed at transforming biomass preprocessing for advanced gasification. The objective is to develop efficient and scalable methods for preparing biomass feedstock, addressing challenges such as high energy demands and inconsistent particle morphology that hinder gasification processes. This initiative is crucial for enhancing the performance of gasification systems, supporting renewable energy projects, and facilitating advancements in biomass utilization. Interested companies can reach out to the Technology Deployment department at td@inl.gov for collaboration opportunities, as the focus is on licensing intellectual property rather than procurement or hiring services.
    INL Innovation Spotlight Efficient Protonic Ceramic Power: Dual-Mode Hydrogen and Electricity Generation
    Buyer not available
    The Department of Energy, through the Battelle Energy Alliance at the Idaho National Laboratory (INL), is seeking partnerships to advance its innovative technology in Efficient Protonic Ceramic Power, which enables dual-mode hydrogen production and electricity generation. This opportunity focuses on the development of a reversible solid oxide cell technology that operates efficiently at lower temperatures, addressing the critical need for sustainable energy conversion and storage solutions in the context of a global shift towards renewable energy. The technology, utilizing a high-performance PNC oxide material, offers enhanced efficiency, durability, and versatility for applications in renewable energy storage, hydrogen production, and power generation. Interested parties can engage with INL for licensing opportunities and further discussions by contacting Andrew Rankin at andrew.rankin@inl.gov.
    TECHNOLOGY/BUSINESS OPPORTUNITY All Liquid Two-Photon Polymerization Resin Formulations Using Cationic Polymerization
    Buyer not available
    The Department of Energy, through the Lawrence Livermore National Laboratory (LLNL), is offering a collaboration opportunity to further develop and commercialize its All Liquid Two-Photon Polymerization Resin Formulations Using Cationic Polymerization. This initiative aims to advance the capabilities of cationic photoresists in two-photon polymerization (TPP) by providing a liquid resin formulation that allows for the printing of larger structures with fine resolution, overcoming limitations associated with traditional solid cationic resins. The technology has potential applications in various fields, including battery and fuel cell electrodes, photonic crystals, mechanical metamaterials, and microfluidic devices. Interested companies should submit a statement of interest, including their corporate expertise and contact information, to LLNL's Innovation and Partnerships Office by email or written correspondence, with further details available on their website.
    INL Innovation Spotlight Advanced Radiation Monitoring: Fieldable Long-Length Scintillating Fibers
    Buyer not available
    The Department of Energy, through the Battelle Energy Alliance at the Idaho National Laboratory (INL), is seeking innovative solutions for advanced radiation monitoring utilizing fieldable long-length scintillating fibers. The objective is to develop a technology that effectively detects and monitors radiation in challenging environments, such as nuclear repositories and medical irradiation facilities, by employing durable scintillating fibers exceeding 10 meters in length, combined with standard optical fibers over 100 meters. This technology addresses significant challenges in radiation monitoring, offering enhanced signal integrity and flexible deployment options essential for the safety and security of sensitive sites. Interested parties can contact Andrew Rankin at andrew.rankin@inl.gov for further information on licensing opportunities and collaboration, as this initiative is not a call for external services or funding.