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The Award database is continually updated throughout the year. As a result, data for FY24 is not expected to be complete until March, 2025.

Download all SBIR.gov award data either with award abstracts (290MB) or without award abstracts (65MB). A data dictionary and additional information is located on the Data Resource Page. Files are refreshed monthly.

The SBIR.gov award data files now contain the required fields to calculate award timeliness for individual awards or for an agency or branch. Additional information on calculating award timeliness is available on the Data Resource Page.

  1. Lightweight, Stable Optical Bench with Integrated Vibration Attenuation

    SBC: SAN DIEGO COMPOSITES, INC.            Topic: MDA13T007

    The goal of this program is to design a lightweight optical bench capable of remaining stable under temperature and moisture changes, while isolating the precision optical array from vibrations such as engine noise and air turbulence. By integrating a customizable periodic stack in the bench, vibrations are attenuated more effectively than commercially available mounts. Additionally, the periodic ...

    STTR Phase II 2016 Department of DefenseMissile Defense Agency
  2. Embedded Sensors for Flight Test (Every Aircraft a Test Aircraft)

    SBC: NEXTGEN AERONAUTICS, INC.            Topic: AF14AT01

    Increasing system capabilities in terms of weapon systems, ISR payloads, GNC, etc., enabled by smaller and more capable electronics systems have led to a trend for overall size reduction in military aircraft. This has resulted in a reduction in the avail...

    STTR Phase II 2016 Department of DefenseAir Force
  3. High Fidelity Computational Models for Aggregated Tissue Interaction in Surgical Simulations

    SBC: CFD RESEARCH CORPORATION            Topic: DHP16A001

    Surgical simulations aiming to support surgeon practices and medical education have attracted enormous research effort over the last two decades. However, the physical reality, especially on simulating aggregated tissue interaction, is still unsatisfactory. In this proposed work, an open source surgery simulation framework, SoFMIS, will be utilized and enhanced with tissue interaction models to a ...

    STTR Phase I 2016 Department of DefenseDefense Health Agency
  4. Process diagnostics to quantify mechanical performance of AM parts

    SBC: POLARONYX INC            Topic: N16AT004

    This Navy STTR Phase I proposal presents an unprecedented NDI tool to quantify mechanical properties of metal parts made with laser additive manufacturing with material characteristics and process parameters. A fiber laser SAW and heterodyne detection is used with LIBS to study both in-process and post-process for both flat and shaped parts. It is the enabling technology for characterize the AM pa ...

    STTR Phase I 2016 Department of DefenseNavy
  5. Quantifying Uncertainty in the Mechanical Performance of Additively Manufactured Parts Due to Material and Process Variation

    SBC: QUESTEK INNOVATIONS LLC            Topic: N16AT004

    Additive manufacturing (AM) promises to be an innovative technology that can enable rapid manufacturing of complicated parts and greatly reduced cycle time. However, the AM process is complex and involves a large number of processing steps, each with its own set of uncertainties. These uncertainties compound through the AM build process, resulting in parts with widely varying properties across dif ...

    STTR Phase I 2016 Department of DefenseNavy
  6. Air Cycle Machine Low Friction, Medium Temperature, Foil Bearing Coating

    SBC: ACREE TECHNOLOGIES INCORPORATED            Topic: N16AT005

    The purpose of this project is to demonstrate the feasibility of using an innovative, durable, low friction, and non-toxic solid lubricant coating for foil air bearings for air cycle machines (ACM). Acrees coating provides superior wear characteristics at all temperatures and provides a substantial improvement over polyimide type coatings that are currently used on ACMs. The coating consists of tw ...

    STTR Phase I 2016 Department of DefenseNavy
  7. Novel, High-Efficiency, Light-weight, Flexible Solar Cells as Electrical Power Generation Source

    SBC: MICROLINK DEVICES INC            Topic: N16AT006

    MicroLink Devices proposes to integrate its novel, high-efficiency, lightweight, and flexible solar sheet technology to a small unmanned aircraft system (UAS) that will provide a significant source of power, enabling long endurance flights spanning one full day to several days of continuous operation. This will be a breakthrough technology that will enhance the performance and utility of the Navys ...

    STTR Phase I 2016 Department of DefenseNavy
  8. Optimized High Performance Stainless Steel Powder for Selective Laser Melting Additive Manufacturing (AM)

    SBC: QUESTEK INNOVATIONS LLC            Topic: N16AT007

    Additive Manufacturing (AM) promises to be an innovative technology that can enable rapid manufacturing of complex parts at greatly reduced cycle time. With the maturation of selective laser melting (SLM) AM technologies there is increasing interest in applying this manufacturing method to the production of aircraft structural components, many of which are made of high-strength stainless steels. H ...

    STTR Phase I 2016 Department of DefenseNavy
  9. Novel Separator Materials for Achieving High Energy/Power Density, Safe, Long-Lasting Lithium-ion Batteries for Navy Aircraft Applications.

    SBC: OCEANIT LABORATORIES INC            Topic: N16AT008

    Oceanit proposes to develop and demonstrate novel, tailored, designer separator materials with optimized properties to maximize lithium-ion cell/battery performance, life, safety and reliability.

    STTR Phase I 2016 Department of DefenseNavy
  10. Additive Manufacturing for Microwave Vacuum Electron Device Cost Reduction

    SBC: RADIABEAM TECHNOLOGIES, LLC            Topic: N16AT010

    The Department of the Navy has a need for the development of an additive manufacturing (AM) process for key vacuum electronic device components to meet on-demand, flexible, and affordable manufacturing requirements. The developed manufacturing method has a potential to reduce cost of vacuum electronics by as much as 70% as well as simplify and hence expedite production process of these devices by ...

    STTR Phase I 2016 Department of DefenseNavy
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