Stf Technologies Llc
CAGE Code: 6XCW5
NCAGE Code: 6XCW5
Status: Active
Type: Commercial Supplier
Dun & Bradstreet (DUNS): 078845304
Summary
Stf Technologies Llc is an Active Commercial Supplier with the Cage Code 6XCW5 and is tracked by Dun & Bradstreet under DUNS Number 078845304..
Address
58 Darien Rd
Newark DE 19711-2024
United States
Points of Contact
No Points of Contact...
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Frequently Asked Questions (FAQ) for CAGE 6XCW5
- What is CAGE Code 6XCW5?
- 6XCW5 is the unique identifier used by NATO Organizations to reference the physical entity known as Stf Technologies Llc located at 58 Darien Rd, Newark DE 19711-2024, United States.
- Who is CAGE Code 6XCW5?
- 6XCW5 refers to Stf Technologies Llc located at 58 Darien Rd, Newark DE 19711-2024, United States.
- Where is CAGE Code 6XCW5 Located?
- CAGE Code 6XCW5 is located in Newark, DE, USA.
Contracting History for CAGE 6XCW5 Most Recent 25 Records
- 80NSSC23PB584
- Sttr Phase I - Sintered Powder Textile Surface Modification For Extreme Environments
- 27 Jul 2023
- Sttr Phase I - Sintered Powder Textile Surface Modification For Extreme Environments
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $149,999.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC23PB584
- Sttr Phase I - Sintered Powder Textile Surface Modification For Extreme Environments
- 13 Dec 2023
- Sttr Phase I - Sintered Powder Textile Surface Modification For Extreme Environments
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $149,999.00
- National Aeronautics And Space Administration (Nasa)
- W15QKN22C0046
- Phase I Sbir Effort With Stf Technologies Llc.
- 15 Mar 2022
- Phase I Sbir Effort With Stf Technologies Llc.
- W6qk Acc-Pica
- Department Of Defense (Dod)
- $259,612.42
- Department Of Defense (Dod)
- 80NSSC18C0129
- We Propose An Innovative Hybrid Composite Material Containing Shear Thickening Fluid (Stf) Energy Absorbing Layers (Seals) That Provides Superior Impact Protection And Novel, Self-Healing Functionality To Prevent Leakage After Impact. The Proposed Innovation Directly Addresses The Need For Thin, Lightweight, Impact-Resistant Composite Materials That Can Be Fabricated In Complex Geometries For Next-Generation Space Suits. The Proposed Phase Ii Research Leverages Successful Phase I R&D And Extensive Composite Materials And Space Suit Expertise Of Our Partners To Advance Commercialization And Trl Of Impact-Resistant, Damage-Tolerant Seal-Composites Innovation To Produce A Prototype Suit Component Suitable For System-Level Integration And Testing. In Phase I It Was Shown That The Seal-Composites Provide Significantly Improved Impact Properties And Weight Savings Vs. Leading Conventional Composite Materials From The Z-2 Prototype. Futhermore, Seal-Composites Impart Self-Healing Functionality To Mitigate Air Leakage If Damaged. The Phase Ii Objectives And Work Plan Follow A Logical Sequence To Test And Downselect Improved Seal-Composite Materials, To Develop And Validate A Computational Model And Conduct Model-Based Design Optimization, To Develop High-Fidelity Test Methods, To Refine The Manufacturing Process To Make Aerospace-Grade Seal-Composites, And To Deliver A Validated Suit Prototype Component Made From Seal-Composites. Further, We Will Leverage Synergistic Environmental Protection Garment (Epg) Research Being Conducted At Stf Technologies And The University Of Delaware To Perform System-Level Development And Optimization Of The Seal-Composites Combined With Emerging, State-Of-The-Art Epgs. Overall, The Proposed Phase Ii Will Produce A Validated Seal-Composite Prototype Suit Component Meeting The Needs For Improved Impact-Resistance And Damage-Tolerance To Offer Superior Astronaut Protection In A Wide Range Of Future Martian And Lunar Surface Eva Scenarios.
- 28 Sep 2021
- We Propose An Innovative Hybrid Composite Material Containing Shear Thickening Fluid (Stf) Energy Absorbing Layers (Seals) That Provides Superior Impact Protection And Novel, Self-Healing Functionality To Prevent Leakage After Impact. The Proposed Innovation Directly Addresses The Need For Thin, Lightweight, Impact-Resistant Composite Materials That Can Be Fabricated In Complex Geometries For Next-Generation Space Suits. The Proposed Phase Ii Research Leverages Successful Phase I R&D And Extensive Composite Materials And Space Suit Expertise Of Our Partners To Advance Commercialization And Trl Of Impact-Resistant, Damage-Tolerant Seal-Composites Innovation To Produce A Prototype Suit Component Suitable For System-Level Integration And Testing. In Phase I It Was Shown That The Seal-Composites Provide Significantly Improved Impact Properties And Weight Savings Vs. Leading Conventional Composite Materials From The Z-2 Prototype. Futhermore, Seal-Composites Impart Self-Healing Functionality To Mitigate Air Leakage If Damaged. The Phase Ii Objectives And Work Plan Follow A Logical Sequence To Test And Downselect Improved Seal-Composite Materials, To Develop And Validate A Computational Model And Conduct Model-Based Design Optimization, To Develop High-Fidelity Test Methods, To Refine The Manufacturing Process To Make Aerospace-Grade Seal-Composites, And To Deliver A Validated Suit Prototype Component Made From Seal-Composites. Further, We Will Leverage Synergistic Environmental Protection Garment (Epg) Research Being Conducted At Stf Technologies And The University Of Delaware To Perform System-Level Development And Optimization Of The Seal-Composites Combined With Emerging, State-Of-The-Art Epgs. Overall, The Proposed Phase Ii Will Produce A Validated Seal-Composite Prototype Suit Component Meeting The Needs For Improved Impact-Resistance And Damage-Tolerance To Offer Superior Astronaut Protection In A Wide Range Of Future Martian And Lunar Surface Eva Scenarios.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $746,818.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC18C0129
- We Propose An Innovative Hybrid Composite Material Containing Shear Thickening Fluid (Stf) Energy Absorbing Layers (Seals) That Provides Superior Impact Protection And Novel, Self-Healing Functionality To Prevent Leakage After Impact. The Proposed Innovation Directly Addresses The Need For Thin, Lightweight, Impact-Resistant Composite Materials That Can Be Fabricated In Complex Geometries For Next-Generation Space Suits. The Proposed Phase Ii Research Leverages Successful Phase I R&D And Extensive Composite Materials And Space Suit Expertise Of Our Partners To Advance Commercialization And Trl Of Impact-Resistant, Damage-Tolerant Seal-Composites Innovation To Produce A Prototype Suit Component Suitable For System-Level Integration And Testing. In Phase I It Was Shown That The Seal-Composites Provide Significantly Improved Impact Properties And Weight Savings Vs. Leading Conventional Composite Materials From The Z-2 Prototype. Futhermore, Seal-Composites Impart Self-Healing Functionality To Mitigate Air Leakage If Damaged. The Phase Ii Objectives And Work Plan Follow A Logical Sequence To Test And Downselect Improved Seal-Composite Materials, To Develop And Validate A Computational Model And Conduct Model-Based Design Optimization, To Develop High-Fidelity Test Methods, To Refine The Manufacturing Process To Make Aerospace-Grade Seal-Composites, And To Deliver A Validated Suit Prototype Component Made From Seal-Composites. Further, We Will Leverage Synergistic Environmental Protection Garment (Epg) Research Being Conducted At Stf Technologies And The University Of Delaware To Perform System-Level Development And Optimization Of The Seal-Composites Combined With Emerging, State-Of-The-Art Epgs. Overall, The Proposed Phase Ii Will Produce A Validated Seal-Composite Prototype Suit Component Meeting The Needs For Improved Impact-Resistance And Damage-Tolerance To Offer Superior Astronaut Protection In A Wide Range Of Future Martian And Lunar Surface Eva Scenarios.
- 24 Jun 2021
- We Propose An Innovative Hybrid Composite Material Containing Shear Thickening Fluid (Stf) Energy Absorbing Layers (Seals) That Provides Superior Impact Protection And Novel, Self-Healing Functionality To Prevent Leakage After Impact. The Proposed Innovation Directly Addresses The Need For Thin, Lightweight, Impact-Resistant Composite Materials That Can Be Fabricated In Complex Geometries For Next-Generation Space Suits. The Proposed Phase Ii Research Leverages Successful Phase I R&D And Extensive Composite Materials And Space Suit Expertise Of Our Partners To Advance Commercialization And Trl Of Impact-Resistant, Damage-Tolerant Seal-Composites Innovation To Produce A Prototype Suit Component Suitable For System-Level Integration And Testing. In Phase I It Was Shown That The Seal-Composites Provide Significantly Improved Impact Properties And Weight Savings Vs. Leading Conventional Composite Materials From The Z-2 Prototype. Futhermore, Seal-Composites Impart Self-Healing Functionality To Mitigate Air Leakage If Damaged. The Phase Ii Objectives And Work Plan Follow A Logical Sequence To Test And Downselect Improved Seal-Composite Materials, To Develop And Validate A Computational Model And Conduct Model-Based Design Optimization, To Develop High-Fidelity Test Methods, To Refine The Manufacturing Process To Make Aerospace-Grade Seal-Composites, And To Deliver A Validated Suit Prototype Component Made From Seal-Composites. Further, We Will Leverage Synergistic Environmental Protection Garment (Epg) Research Being Conducted At Stf Technologies And The University Of Delaware To Perform System-Level Development And Optimization Of The Seal-Composites Combined With Emerging, State-Of-The-Art Epgs. Overall, The Proposed Phase Ii Will Produce A Validated Seal-Composite Prototype Suit Component Meeting The Needs For Improved Impact-Resistance And Damage-Tolerance To Offer Superior Astronaut Protection In A Wide Range Of Future Martian And Lunar Surface Eva Scenarios.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $746,818.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC18C0129
- Eo14042 We Propose An Innovative Hybrid Composite Material Containing Shear Thickening Fluid (Stf) Energy Absorbing Layers (Seals) That Provides Superior Impact Protection And Novel, Self-Healing Functionality To Prevent Leakage After Impact. The Proposed Innovation Directly Addresses The Need For Thin, Lightweight, Impact-Resistant Composite Materials That Can Be Fabricated In Complex Geometries For Next-Generation Space Suits. The Proposed Phase Ii Research Leverages Successful Phase I R&D And Extensive Composite Materials And Space Suit Expertise Of Our Partners To Advance Commercialization And Trl Of Impact-Resistant, Damage-Tolerant Seal-Composites Innovation To Produce A Prototype Suit Component Suitable For System-Level Integration And Testing. In Phase I It Was Shown That The Seal-Composites Provide Significantly Improved Impact Properties And Weight Savings Vs. Leading Conventional Composite Materials From The Z-2 Prototype. Futhermore, Seal-Composites Impart Self-Healing Functionality To Mitigate Air Leakage If Damaged. The Phase Ii Objectives And Work Plan Follow A Logical Sequence To Test And Downselect Improved Seal-Composite Materials, To Develop And Validate A Computational Model And Conduct Model-Based Design Optimization, To Develop High-Fidelity Test Methods, To Refine The Manufacturing Process To Make Aerospace-Grade Seal-Composites, And To Deliver A Validated Suit Prototype Component Made From Seal-Composites. Further, We Will Leverage Synergistic Environmental Protection Garment (Epg) Research Being Conducted At Stf Technologies And The University Of Delaware To Perform System-Level Development And Optimization Of The Seal-Composites Combined With Emerging, State-Of-The-Art Epgs. Overall, The Proposed Phase Ii Will Produce A Validated Seal-Composite Prototype Suit Component Meeting The Needs For Improved Impact-Resistance And Damage-Tolerance To Offer Superior Astronaut Protection In A Wide Range Of Future Martian And Lunar Surface Eva Scenarios.
- 12 Oct 2021
- Eo14042 We Propose An Innovative Hybrid Composite Material Containing Shear Thickening Fluid (Stf) Energy Absorbing Layers (Seals) That Provides Superior Impact Protection And Novel, Self-Healing Functionality To Prevent Leakage After Impact. The Proposed Innovation Directly Addresses The Need For Thin, Lightweight, Impact-Resistant Composite Materials That Can Be Fabricated In Complex Geometries For Next-Generation Space Suits. The Proposed Phase Ii Research Leverages Successful Phase I R&D And Extensive Composite Materials And Space Suit Expertise Of Our Partners To Advance Commercialization And Trl Of Impact-Resistant, Damage-Tolerant Seal-Composites Innovation To Produce A Prototype Suit Component Suitable For System-Level Integration And Testing. In Phase I It Was Shown That The Seal-Composites Provide Significantly Improved Impact Properties And Weight Savings Vs. Leading Conventional Composite Materials From The Z-2 Prototype. Futhermore, Seal-Composites Impart Self-Healing Functionality To Mitigate Air Leakage If Damaged. The Phase Ii Objectives And Work Plan Follow A Logical Sequence To Test And Downselect Improved Seal-Composite Materials, To Develop And Validate A Computational Model And Conduct Model-Based Design Optimization, To Develop High-Fidelity Test Methods, To Refine The Manufacturing Process To Make Aerospace-Grade Seal-Composites, And To Deliver A Validated Suit Prototype Component Made From Seal-Composites. Further, We Will Leverage Synergistic Environmental Protection Garment (Epg) Research Being Conducted At Stf Technologies And The University Of Delaware To Perform System-Level Development And Optimization Of The Seal-Composites Combined With Emerging, State-Of-The-Art Epgs. Overall, The Proposed Phase Ii Will Produce A Validated Seal-Composite Prototype Suit Component Meeting The Needs For Improved Impact-Resistance And Damage-Tolerance To Offer Superior Astronaut Protection In A Wide Range Of Future Martian And Lunar Surface Eva Scenarios.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $746,818.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC20C0232
- Stf-Enhanced Textiles For Durable, Puncture- And Cut-Resistant Epgs
- 17 Jun 2020
- Stf-Enhanced Textiles For Durable, Puncture- And Cut-Resistant Epgs
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $165,000.00
- National Aeronautics And Space Administration (Nasa)
- 80NSSC20C0232
- Stf-Enhanced Textiles For Durable, Puncture- And Cut-Resistant Epgs
- 7 Jul 2021
- Stf-Enhanced Textiles For Durable, Puncture- And Cut-Resistant Epgs
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $165,000.00
- National Aeronautics And Space Administration (Nasa)