Nanoramic, Inc.
Dba Nanoramic Laboratories
CAGE Code: 5GDR1
NCAGE Code: 5GDR1
Status: Active
Type: Manufacturer
Dun & Bradstreet (DUNS): 830557133
Summary
Nanoramic, Inc., Dba Nanoramic Laboratories is an Active Manufacturer with the Cage Code 5GDR1 and is tracked by Dun & Bradstreet under DUNS Number 830557133..
Address
7 Audubon Rd
Wakefield MA 01880-1256
United States
Points of Contact
No Points of Contact...
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Frequently Asked Questions (FAQ) for CAGE 5GDR1
- What is CAGE Code 5GDR1?
- 5GDR1 is the unique identifier used by NATO Organizations to reference the physical entity known as Nanoramic, Inc. Dba Nanoramic Laboratories located at 7 Audubon Rd, Wakefield MA 01880-1256, United States.
- Who is CAGE Code 5GDR1?
- 5GDR1 refers to Nanoramic, Inc. Dba Nanoramic Laboratories located at 7 Audubon Rd, Wakefield MA 01880-1256, United States.
- Where is CAGE Code 5GDR1 Located?
- CAGE Code 5GDR1 is located in Wakefield, MA, USA.
Contracting History for CAGE 5GDR1 Most Recent 25 Records
- FA864922P0297
- Thermal Interface Materials With High Conductivity For Vibration Tolerant Applications
- 29 Oct 2021
- Thermal Interface Materials With High Conductivity For Vibration Tolerant Applications
- Fa8649 Usaf Sbir Sttr Contracting
- Department Of Defense (Dod)
- $49,558.00
- Department Of Defense (Dod)
- FA864920P0512
- Fx201-Cso1-0229-Nanoramic Laboratories-Advanced High Performance Li-Ion Energy Storage Devices Based On Neocarbonixtm Binder Free Electrodes
- 5 Mar 2020
- Fx201-Cso1-0229-Nanoramic Laboratories-Advanced High Performance Li-Ion Energy Storage Devices Based On Neocarbonixtm Binder Free Electrodes
- Fa8649 Usaf Sbir Sttr Contracting
- Department Of Defense (Dod)
- $49,999.00
- Department Of Defense (Dod)
- NNX17CC23C
- Igf::Ot::Igf Traditionally, The Relatively Small Surface Area And Volume Of A Cube Satellite Has Restricted The Practical Power Limit Of Cube Satellites. To The Extent That The Power Will Be Generated By Solar Panels, Cube Satellites Have A Limited Round Trip Energy Budget. Increasing Solar Panel Efficiency And Complexity Alleviates The Energy Issue To Some Degree. Both However, Occur At The Expense Of The Original Cube Satellite Advantages Of Being Inexpensive, Small, And Reliable. As Such, The Objective Of High Power Capabilities Must Also Assume Fairly Short Time Scales In Order To Preserve The Energy Budget. It's This Mode Of Operation, Maximum Energy And Short High Power Events, Where Hybrid System Designs Typically Make Practical Sense. In All Cases, The Energy Storage Requirements Will Depend On The Payloads Power Profile And Mission Requirements. Cube Satellite Payloads Are Becoming More Sophisticated And, In Many Cases, Power Hungry. Interesting High Power Payloads Currently In Development For Small Satellites Include Synthetic Aperture Radar (Sar) And Mechanical Actuators For Performing Larger Satellite Maintenance. In Order To Continue The Trend Of Increasing Cube Satellite Capabilities, It's Important To Be Ready With Energy Storage That Is Both Capable Of Supplying High Power And Flexible To Suit The Range Of Payload Possibilities. The Hybrid Ultracapacitor Module Proposed Is A Flexible, High Efficiency, Novel Design That Will Enable Satellite Engineers To Quickly And Easily Realize Benefits Such As Extended Battery Lifetime, High Peak Power, And Smaller Size And Weight That May Be Possible Through A Hybrid Energy Storage System. Additionally, The Technology Will Translate To Additional Multifunctional, Structural Applications Such As Microsatellites, Light Aircraft, Ordinance, And Many More.
- 6 Jun 2018
- Igf::Ot::Igf Traditionally, The Relatively Small Surface Area And Volume Of A Cube Satellite Has Restricted The Practical Power Limit Of Cube Satellites. To The Extent That The Power Will Be Generated By Solar Panels, Cube Satellites Have A Limited Round Trip Energy Budget. Increasing Solar Panel Efficiency And Complexity Alleviates The Energy Issue To Some Degree. Both However, Occur At The Expense Of The Original Cube Satellite Advantages Of Being Inexpensive, Small, And Reliable. As Such, The Objective Of High Power Capabilities Must Also Assume Fairly Short Time Scales In Order To Preserve The Energy Budget. It's This Mode Of Operation, Maximum Energy And Short High Power Events, Where Hybrid System Designs Typically Make Practical Sense. In All Cases, The Energy Storage Requirements Will Depend On The Payloads Power Profile And Mission Requirements. Cube Satellite Payloads Are Becoming More Sophisticated And, In Many Cases, Power Hungry. Interesting High Power Payloads Currently In Development For Small Satellites Include Synthetic Aperture Radar (Sar) And Mechanical Actuators For Performing Larger Satellite Maintenance. In Order To Continue The Trend Of Increasing Cube Satellite Capabilities, It's Important To Be Ready With Energy Storage That Is Both Capable Of Supplying High Power And Flexible To Suit The Range Of Payload Possibilities. The Hybrid Ultracapacitor Module Proposed Is A Flexible, High Efficiency, Novel Design That Will Enable Satellite Engineers To Quickly And Easily Realize Benefits Such As Extended Battery Lifetime, High Peak Power, And Smaller Size And Weight That May Be Possible Through A Hybrid Energy Storage System. Additionally, The Technology Will Translate To Additional Multifunctional, Structural Applications Such As Microsatellites, Light Aircraft, Ordinance, And Many More.
- Nasa Shared Services Center
- National Aeronautics And Space Administration (Nasa)
- $724,208.00
- National Aeronautics And Space Administration (Nasa)