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Award Data

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The Award database is continually updated throughout the year. As a result, data for FY21 is not expected to be complete until September, 2022.

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.

  1. 3D Acoustic Model for Geometrically Constrained Environments

    SBC: HEAT, LIGHT, AND SOUND RESEARCH, INC.            Topic: N16AT018

    Systems that operate in constrained environments depend on the acoustics in several ways. Harbor defense systems detect intruders (people and/or vessels) by either listening for their noises (passively) or by pinging on them and detecting their echoes (actively). Furthermore, such systems may also form the equivalent of an underwater cell phone network using sound to carry the information. The aco ...

    STTR Phase I 2016 Department of DefenseNavy
  2. Perovskite Solar Cells

    SBC: Radiation Monitoring Devices, Inc.            Topic: N16AT006

    The goal of the proposed research is to develop light-weight, flexible, high efficiency solar cells made from perovskite halide light-harvesting materials for use on unmanned aircraft systems (UAS), for use in conjunction with an energy storage system. Solar cells have historically been heavy, costly, and inflexible. In this research, low-cost manufacturing methods will be used to make high effici ...

    STTR Phase I 2016 Department of DefenseNavy
  3. Development of powder bed printing (3DP) for rapid and flexible fabrication of energetic material payloads and munitions

    SBC: MAKEL ENGINEERING, INC.            Topic: DTRA16A001

    This program will demonstrate how additive manufacturing technologies can be used with reactive and high energy materials to create rapid and flexible fabrication of payload and munitions. Our primary approach to this problem will be to use powder bed binder printing techniques to print reactive structures. The anticipated feedstock will consist of composite particles containing all reactant spe ...

    STTR Phase I 2016 Department of DefenseDefense Threat Reduction Agency
  4. Conductive Transmissive Coating for Enhanced-Absorption Thin Film Solar Cells

    SBC: AGILTRON, INC.            Topic: A15AT016

    Thin-film, lightweight, large-area flexible inorganic solar cells have shown promise to meet the militarys remote power needs on the battlefield. However, thin film solar cells normally have inferior conversion efficiencies due to limited absorption of sunlight by the thin active layer. Various approaches have been investigated to improve conversion efficiencies of thin film solar cells. Among the ...

    STTR Phase I 2016 Department of DefenseArmy
  5. Miniature Mass Spectrometer for Peptide Sequencing and Mobile Coupling with Separation Techniques

    SBC: Bayspec, Inc.            Topic: A16AT012

    Using advanced ion optics that was developed by Pacific Northwest National Laboratory (PNNL), BaySpec will develop a prototype of portable mass spectrometer (less than 40 lb. and 300W) with continuous atmospheric pressure inlet that is fully capable of uninterrupted on-line sampling from an ambient environment. The continuous nature of the inlet ensures full compatibility with separation technique ...

    STTR Phase I 2016 Department of DefenseArmy
  6. High Hesitivity Magnetic Materials for Magnetic Toroid and Flat Dipole Antennas

    SBC: Winchester Technologies, LLC            Topic: N16AT001

    Novel approaches are needed to improve the performance and reduce the size, number and signature of antennas with significantly enhanced efficiency in HF-UHF. It has been shown recently hesitivity, which is able to characterize the performance of the material and categorize the radiation efficiency of magnetodielectric wire antennas; the higher the hesitivity, the higher the attainable antenna eff ...

    STTR Phase I 2016 Department of DefenseNavy
  7. System to Evaluate and Assess Holistic Aircrew Workload (SEAHAWK)

    SBC: Charles River Analytics, Inc.            Topic: N16AT002

    The Navy is continually developing new technologies to improve warfighting effectiveness. These technologies risk overloading Aircrews physical and cognitive capacities, thereby degrading performance. To mitigate that risk, the Navy needs a system to assess Aircrews physical and cognitive workloads unobtrusively and objectively. Such a system must (1) perform real-time data collection in a robust ...

    STTR Phase I 2016 Department of DefenseNavy
  8. 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
  9. Air Cycle Machine Low Friction, Medium Temperature, Foil Bearing Coating

    SBC: IBC Materials & Technologies, LLC            Topic: N16AT005

    In this proposed SBIR program, IBC Materials & Technologies, in conjunction with our industry partner Mechanical Solutions, Inc. (MSI) and Texas A&M University, will leverage our knowledge and experience in the domain of industrial metallic coatings to develop a metallurgical coating solution for the Air Foil Bearing. IBC has deep expertise in a variety of industrial coating processes including mu ...

    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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