2223197
Project Grant
Overview
Grant Description
SBIR Phase I: Hydrologic Open Cooling System (HOCS) for Low-Energy Refrigeration - The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase I project is the development of a technology enabling low-energy, resilient cooling that is capable of mitigating the environmental impacts and high costs of conventional refrigeration.
There is a critical need for sustainable cooling solutions that provide an alternative to hydrofluorocarbon-based refrigerants that rely on carbon dioxide (CO2)-emitting systems. This project seeks to develop a Hydrologic Open Cooling System (HOCS) that can maintain cooling chambers at 1.5-5°C utilizing 10% or less of the electrical power of conventional systems.
This project unlocks environmental heat as an energy reservoir and offsets significant energy costs of conventional cooling systems. The technology can support highly efficient refrigeration at a fraction of the operational cost and electrical demand of traditional systems. Adoption of this cooling technology by small- to mid-size supermarkets would enable significant cost savings for electricity.
On a broader scale, widespread implementation of this innovation across a variety of refrigeration applications would reduce greenhouse gas emissions and energy consumption, meeting the need for sustainable technologies to support food and energy security while upholding climate goals.
This SBIR Phase I project develops a renewable, closed container cooling system incorporating a rechargeable vacuum insulation and a novel two-stage heat pump. This project involves:
1) Developing a rechargeable vacuum insulation technology that does not use vacuum pumps;
2) Creating a modified Dewar connected to a fully renewable cooling system enabling cooled inner chambers; and
3) Evaluating the ability to use environmental heat to restore the solutions that power the cooling system allowing their reuse.
The novel heat pump technology is based on two asynchronous stages: the first utilizes concentration gradients as a driving mechanism enabling thermal transfer, while the second uses environmental heat to re-concentrate saline solutions after dilution during stage one. Together, these two stages enable cooling of a closed container.
The project will examine system configurations able to generate large thermal gradients, enabling maintenance of 1.5-5°C temperatures within the Dewar. Advantages of this system include:
1) The system's ability to cool continues in the absence of electricity making it resilient to power outages from itinerant weather, wildfires, and earthquakes;
2) Lossless storage of cooling capacity; and
3) Significantly reducing the greenhouse gas footprint compared to conventional refrigeration.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
There is a critical need for sustainable cooling solutions that provide an alternative to hydrofluorocarbon-based refrigerants that rely on carbon dioxide (CO2)-emitting systems. This project seeks to develop a Hydrologic Open Cooling System (HOCS) that can maintain cooling chambers at 1.5-5°C utilizing 10% or less of the electrical power of conventional systems.
This project unlocks environmental heat as an energy reservoir and offsets significant energy costs of conventional cooling systems. The technology can support highly efficient refrigeration at a fraction of the operational cost and electrical demand of traditional systems. Adoption of this cooling technology by small- to mid-size supermarkets would enable significant cost savings for electricity.
On a broader scale, widespread implementation of this innovation across a variety of refrigeration applications would reduce greenhouse gas emissions and energy consumption, meeting the need for sustainable technologies to support food and energy security while upholding climate goals.
This SBIR Phase I project develops a renewable, closed container cooling system incorporating a rechargeable vacuum insulation and a novel two-stage heat pump. This project involves:
1) Developing a rechargeable vacuum insulation technology that does not use vacuum pumps;
2) Creating a modified Dewar connected to a fully renewable cooling system enabling cooled inner chambers; and
3) Evaluating the ability to use environmental heat to restore the solutions that power the cooling system allowing their reuse.
The novel heat pump technology is based on two asynchronous stages: the first utilizes concentration gradients as a driving mechanism enabling thermal transfer, while the second uses environmental heat to re-concentrate saline solutions after dilution during stage one. Together, these two stages enable cooling of a closed container.
The project will examine system configurations able to generate large thermal gradients, enabling maintenance of 1.5-5°C temperatures within the Dewar. Advantages of this system include:
1) The system's ability to cool continues in the absence of electricity making it resilient to power outages from itinerant weather, wildfires, and earthquakes;
2) Lossless storage of cooling capacity; and
3) Significantly reducing the greenhouse gas footprint compared to conventional refrigeration.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
Awardee
Grant Program (CFDA)
Awarding / Funding Agency
Place of Performance
Batavia,
Illinois
60510-2772
United States
Geographic Scope
Single Zip Code
Related Opportunity
None
Analysis Notes
Amendment Since initial award the total obligations have decreased 50% from $550,000 to $275,000.
Kazadi Enterprises was awarded
Project Grant 2223197
worth $275,000
from National Science Foundation in March 2023 with work to be completed primarily in Batavia Illinois United States.
The grant
has a duration of 8 months and
was awarded through assistance program 47.084 NSF Technology, Innovation, and Partnerships.
SBIR Details
Research Type
SBIR Phase I
Title
SBIR Phase I:Hydrologic Open Cooling System (HOCS) for low-energy refrigeration
Abstract
The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase I project is the development of a technology enabling low-energy, resilient cooling that is capable of mitigating the environmental impacts and high costs of conventional refrigeration. There is a critical need for sustainable cooling solutions that provide an alternative to hydrofluorocarbon-based refrigerants that rely on carbon dioxide (CO2)-emitting systems. This project seeks to develop a Hydrologic Open Cooling System (HOCS) that can maintain cooling chambers at 1.5-5°C utilizing 10% or less of the electrical power of conventional systems. This project unlocks environmental heat as an energy reservoir and offsets significant energy costs of conventional cooling systems. The technology can support highly efficient refrigeration at a fraction of the operational cost and electrical demand of traditional systems. Adoption of this cooling technology by small- to mid-size supermarkets would enable significant cost savings for electricity. On a broader scale, widespread implementation of this innovation across a variety of refrigeration applications would reduce greenhouse gas emissions and energy consumption, meeting the need for sustainable technologies to support food and energy security while upholding climate goals._x000D_ _x000D_ This SBIR Phase I project develops a renewable, closed container cooling system incorporating a rechargeable vacuum insulation and a novel two-stage heat pump. This project involves 1) developing a rechargeable vacuum insulation technology that does not use vacuum pumps; 2) creating a modified dewar connected to a fully renewable cooling system enabling cooled inner chambers; and 3) evaluating the ability to use environmental heat to restore the solutions that power the cooling system allowing their reuse. The novel heat pump technology is based on two asynchronous stages: the first utilizes concentration gradients as a driving mechanism enabling thermal transfer, while the second uses environmental heat to re-concentrate saline solutions after dilution during stage one. Together, these two stages enable cooling of a closed container. The project will examine system configurations able to generate large thermal gradients, enabling maintenance of 1.5-5°C temperatures within the dewar. Advantages of this system include 1) the system’s ability to cool continues in the absence of electricity making it resilient to power outages from itinerant weather, wildfires, and earthquakes; 2) lossless storage of cooling capacity; and 3) significantly reducing the greenhouse gas footprint compared to conventional refrigeration._x000D_ _x000D_ This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
Topic Code
ET
Solicitation Number
NSF 22-551
Status
(Complete)
Last Modified 3/21/23
Period of Performance
3/15/23
Start Date
11/30/23
End Date
Funding Split
$275.0K
Federal Obligation
$0.0
Non-Federal Obligation
$275.0K
Total Obligated
Activity Timeline
Additional Detail
Award ID FAIN
2223197
SAI Number
None
Award ID URI
SAI EXEMPT
Awardee Classifications
Small Business
Awarding Office
491503 TRANSLATIONAL IMPACTS
Funding Office
491503 TRANSLATIONAL IMPACTS
Awardee UEI
Q7ECK9SGC9U4
Awardee CAGE
8NPY2
Performance District
Not Applicable
Budget Funding
| Federal Account | Budget Subfunction | Object Class | Total | Percentage |
|---|---|---|---|---|
| Research and Related Activities, National Science Foundation (049-0100) | General science and basic research | Grants, subsidies, and contributions (41.0) | $275,000 | 100% |
Modified: 3/21/23