{"project":{"acronym":"","projectId":93385,"title":"Asymmetric Conductance Thermoelectric Cooling Modules for Cryogenic Applications","primaryTaxonomyNodes":[{"taxonomyNodeId":10931,"taxonomyRootId":8816,"parentNodeId":10929,"level":3,"code":"TX14.2.2","title":"Heat Transport","definition":"Heat transport enables moving waste energy from a vehicle component and/or system for either rejection to the environment or re-use elsewhere within the vehicle. This area includes technologies for both spacecraft and electrified aircraft propulsion thermal management. The transport of energy is accomplished using active and/or passive capabilities within a thermal control system. Technologies include those items that can more effectively transfer heat, as well as methods to advance robustness, life, efficiency, and temperature range of operability.","exampleTechnologies":"Heat pipes (e.g. constant conductance, variable conductance, diode), capillary pumped fluid loops, loop heat pipes, mechanically pumped fluid loops (e.g., single phase and two phase), thermal straps, forced air cooling (heating, ventilation, and air conditioning (HVAC)), fans, heat pumps (e.g., thermoelectric coolers, vapor compression systems), vapor cooling, heat switches (e.g. paraffin, coefficient of thermal expansion, shape memory alloys), solid state conduction bars/doublers (e.g. high thermal conductivity composites), loop heat pipe and high heat load transport (500 kW - 1 MW), two phase heat transport and pool boiling","hasChildren":false,"hasInteriorContent":true}],"startTrl":2,"currentTrl":3,"endTrl":3,"benefits":"Space science instruments require dedicated/localized cooling to meet their stringent requirements. TECs have the advantage of small size, long life, solid state design, and no moving parts or fluid operation. Improving the efficiency of TECs and enabling them to provide the cold temperatures needed by certain types of space science instruments would be an enhancing, or possibly an enabling, technology. Based on the 2015 NASA Technology Roadmap, programs the concept could impact include Explorer, Earth Venture Suborbital, DRM 6 (Crewed to Near Earth Asteroid), DRM 7 (Crewed to Lunar Surface), and DRM 8 & 9 (Crewed to Mars Moons and Mars Surface).
Thermoelectric coolers (TECs) are used throughout the military, aerospace, electronics, and consumer products industries. Their compact construction, quiet operation, long lifetimes, and lack of moving parts makes them the preferred choice for refrigeration applications. The commercial potential of the laminate TEC device is extremely large, with residential refrigeration alone being a large untapped market. These market segments are dependent on traditional vapor compression technology, which has the disadvantages of weight, noise, moderate reliability, and the use of environmentally-unfriendly refrigerants. Thermoelectric coolers could provide localized cooling (and heating) capability in a lightweight, compact, convenient form factor, characterized by low noise, essentially no maintenance, ease of installation, and no use of environmentally harmful working fluids. In summary, the market potential of the laminate TEC approach is enormous, while offering a significant civic and environmental benefit, as well.","description":"Thermoelectric coolers (TECs) have long been noted for their compact construction, high reliability, and clean, quiet operation, and they are now widely used in consumer products. However, TECs are inefficient devices requiring large electrical currents to provide a refrigerant effect. Even modest improvements in TEC performance would vastly increase the market potential of thermoelectric cooling, expanding its role into maintaining space science instrument components at cryogenic temperatures (<90K), as well as increasing adoption in consumer appliances such as refrigerators and air conditioners. microVection has identified a means of improving the efficiencies of TECs with minor design and fabrication changes. This involves shifting the peak temperature location through modification of the conductance in a simple and controlled manner. This was demonstrated first analytically and then by using a small cell of 3 couples (6 legs), and the results showed a significant (~30%) increase in the temperature differential of the cell at no heat load. The simplicity of the concept suggests that it offers a near-term, affordable cooling solution that can take advantage of both advanced materials and reductions in scale to improve temperature differentials by as much as 30%. Conversely, the same temperature differential can be achieved at lower input power levels, or at higher cold-side heat fluxes, with input power being reduced by as much as 60%. The overarching goal of the proposed effort is to bring high-performance thermoelectric cooling technology to a maturity suitable for the space science and commercial marketplaces, and to demonstrate analytically and experimentally that asymmetric conductance TEC designs offer significant advantages over conventional thermoelectric devices. The specific objective of the Phase I is to show that asymmetric conductance thermoelectric devices offer near-term improvements to thermoelectric coolers in high current design scenarios.","startYear":2017,"startMonth":6,"endYear":2017,"endMonth":12,"statusDescription":"Completed","principalInvestigators":[{"contactId":161507,"canUserEdit":false,"firstName":"Geoffrey","lastName":"Campbell","fullName":"Geoffrey Campbell","fullNameInverted":"Campbell, Geoffrey","primaryEmail":"geoff@microvection.com","publicEmail":true,"nacontact":false}],"programDirectors":[{"contactId":206378,"canUserEdit":false,"firstName":"Jason","lastName":"Kessler","fullName":"Jason L Kessler","fullNameInverted":"Kessler, Jason L","middleInitial":"L","primaryEmail":"jason.l.kessler@nasa.gov","publicEmail":true,"nacontact":false}],"programExecutives":[{"contactId":215154,"canUserEdit":false,"firstName":"Jennifer","lastName":"Gustetic","fullName":"Jennifer L Gustetic","fullNameInverted":"Gustetic, Jennifer L","middleInitial":"L","primaryEmail":"jennifer.l.gustetic@nasa.gov","publicEmail":true,"nacontact":false}],"programManagers":[{"contactId":62051,"canUserEdit":false,"firstName":"Carlos","lastName":"Torrez","fullName":"Carlos Torrez","fullNameInverted":"Torrez, Carlos","primaryEmail":"carlos.torrez@nasa.gov","publicEmail":true,"nacontact":false}],"projectManagers":[{"contactId":3164052,"canUserEdit":false,"firstName":"Mark","lastName":"Kobel","fullName":"Mark Kobel","fullNameInverted":"Kobel, Mark","primaryEmail":"Mark.C.Kobel@nasa.gov","publicEmail":true,"nacontact":false},{"contactId":461333,"canUserEdit":false,"firstName":"Theresa","lastName":"Stanley","fullName":"Theresa M Stanley","fullNameInverted":"Stanley, Theresa M","middleInitial":"M","primaryEmail":"theresa.m.stanley@nasa.gov","publicEmail":true,"nacontact":false}],"website":"","libraryItems":[{"file":{"fileExtension":"pdf","fileId":299624,"fileName":"SBIR_2017_1_BC_S3.06-8747","fileSize":93104,"objectId":296162,"objectType":{"lkuCodeId":889,"code":"LIBRARY_ITEMS","description":"Library Items","lkuCodeTypeId":182,"lkuCodeType":{"codeType":"OBJECT_TYPE","description":"Object Type"}},"objectTypeId":889,"fileSizeString":"90.9 KB"},"files":[{"fileExtension":"pdf","fileId":299624,"fileName":"SBIR_2017_1_BC_S3.06-8747","fileSize":93104,"objectId":296162,"objectType":{"lkuCodeId":889,"code":"LIBRARY_ITEMS","description":"Library Items","lkuCodeTypeId":182,"lkuCodeType":{"codeType":"OBJECT_TYPE","description":"Object Type"}},"objectTypeId":889,"fileSizeString":"90.9 KB"}],"id":296162,"title":"Briefing Chart","description":"Asymmetric Conductance Thermoelectric Cooling Modules for Cryogenic Applications, Phase I Briefing Chart","libraryItemTypeId":1222,"projectId":93385,"primary":false,"publishedDateString":"","contentType":{"lkuCodeId":1222,"code":"DOCUMENT","description":"Document","lkuCodeTypeId":341,"lkuCodeType":{"codeType":"LIBRARY_ITEM_TYPE","description":"Library Item Type"}}},{"caption":"Asymmetric Conductance Thermoelectric Cooling Modules for Cryogenic Applications, Phase I Briefing Chart Image","file":{"fileExtension":"png","fileId":295340,"fileName":"SBIR_2017_1_BC_S3.06-8747","fileSize":93844,"objectId":291865,"objectType":{"lkuCodeId":889,"code":"LIBRARY_ITEMS","description":"Library Items","lkuCodeTypeId":182,"lkuCodeType":{"codeType":"OBJECT_TYPE","description":"Object Type"}},"objectTypeId":889,"fileSizeString":"91.6 KB"},"files":[{"fileExtension":"png","fileId":295340,"fileName":"SBIR_2017_1_BC_S3.06-8747","fileSize":93844,"objectId":291865,"objectType":{"lkuCodeId":889,"code":"LIBRARY_ITEMS","description":"Library Items","lkuCodeTypeId":182,"lkuCodeType":{"codeType":"OBJECT_TYPE","description":"Object Type"}},"objectTypeId":889,"fileSizeString":"91.6 KB"}],"id":291865,"title":"Briefing Chart Image","description":"Asymmetric Conductance Thermoelectric Cooling Modules for Cryogenic Applications, Phase I Briefing Chart Image","libraryItemTypeId":1095,"projectId":93385,"primary":true,"publishedDateString":"","contentType":{"lkuCodeId":1095,"code":"IMAGE","description":"Image","lkuCodeTypeId":341,"lkuCodeType":{"codeType":"LIBRARY_ITEM_TYPE","description":"Library Item Type"}}}],"transitions":[],"primaryImage":{"file":{"fileExtension":"png","fileId":295340,"fileSizeString":"0 Byte"},"id":291865,"description":"Asymmetric Conductance Thermoelectric Cooling Modules for Cryogenic Applications, Phase I Briefing Chart Image","projectId":93385,"publishedDateString":""},"responsibleMd":{"acronym":"STMD","canUserEdit":false,"city":"","external":false,"linkCount":0,"organizationId":4875,"organizationName":"Space Technology Mission Directorate","organizationType":"NASA_Mission_Directorate","naorganization":false,"organizationTypePretty":"NASA Mission Directorate"},"program":{"acronym":"SBIR/STTR","active":true,"description":"
The NASA SBIR and STTR programs fund the research, development, and demonstration of innovative technologies that fulfill NASA needs as described in the annual Solicitations and have significant potential for successful commercialization. If you are a small business concern (SBC) with 500 or fewer employees or a non-profit RI such as a university or a research laboratory with ties to an SBC, then NASA encourages you to learn more about the SBIR and STTR programs as a potential source of seed funding for the development of your innovations.
The SBIR and STTR programs have 3 phases:
The SBIR and STTR Phase I contracts last for 6 months with a maximum funding of $125,000, and Phase II contracts last for 24 months with a maximum funding of $750,000 - $1.5 million.
Opportunity for Continued Technology Development Post-Phase II:
The NASA SBIR/STTR Program currently has in place two initiatives for supporting its small business partners past the basic Phase I and Phase II elements of the program that emphasize opportunities for commercialization. Specifically, the NASA SBIR/STTR Program has the Phase II Enhancement (Phase II-E) and Phase II eXpanded (Phase II-X) contract options.
Please review the links below to obtain more information on the SBIR/STTR programs.
Provides an overview of the SBIR and STTR programs as implemented by NASA
Provides access to the annual SBIR/STTR Solicitations containing detailed information on the program eligibility requirements, proposal instructions and research topics and subtopics
Schedule and links for the SBIR/STTR solicitations and selection announcements
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Still have questions? Visit the program FAQs
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