NASA SBIR 2018-I Solicitation

Proposal Summary


PROPOSAL NUMBER:
 18-1- Z10.03-8423
SUBTOPIC TITLE:
 Nuclear Thermal Propulsion (NTP)
PROPOSAL TITLE:
 Novel Technologies for Efficient NTP Reactor Decay Heat Removal and Utilization
SMALL BUSINESS CONCERN (Firm Name, Mail Address, City/State/Zip, Phone)
Ultra Safe Nuclear Corporation
2288 West Commodore Way, Suite 300
Seattle , WA 98199-1465
(206) 906-9741

Principal Investigator (Name, E-mail, Mail Address, City/State/Zip, Phone)
Dr. Michael Eades
m.eades@usnc.com
2284 W COMMODORE WAY, STE 200 Seattle, WA 98199 - 1468
(740) 262-2804

Business Official (Name, E-mail, Mail Address, City/State/Zip, Phone)
Paolo Venneri
p.venneri@usnc.com
2288 West Commodore Way, Suite 300 Seattle, WA 98199 - 1465
(858) 342-4837
Estimated Technology Readiness Level (TRL) :
Begin: 2
End: 3
Technical Abstract

In this SBIR, Ultra Safe Nuclear Corporation (USNC) will investigate and develop a set of novel technologies to minimize the amount of hydrogen needed for reactor decay heat removal after the shutdown of Nuclear Thermal Propulsion (NTP) systems. Decay heat is the energy deposited during the decay of radioactive fission products after the reactor shuts down. Its management is a critical issue for NTP systems. USNC’s technology will be an effective, yet simple, solution to address decay heat removal. Central to USNC’s optimized strategy for decay heat removal is maximizing the temperature that hydrogen is ejected and maximizing radiative heat transfer from the available surfaces of the rocket and nozzle. Furthermore, USNC’s comprehensive solution generates small amounts of electrical power with the removed decay heat, increasing mission flexibility and resilience. Specifically, USNC will primarily investigate four technologies to minimize hydrogen usage: 

- The inclusion of coolant channels on the outside structure of the tie tube between the insulator and fuel that can heat hydrogen to hotter temperatures than the zirconium hydride moderator can maintain. 

- Circulating hydrogen through the tie tube and the outer structure of the core to maximize heat rejection by radiation. 

- Conversion of some of the heat into useful work through the addition of a power generation unit. 

- Using computationally-intensive optimization to find the best possible strategies and power cycle configurations to minimize the amount of hydrogen ejected from the system

Potential NASA Applications

NTP and its supporting technologies have great promise in spreading human presence to Mars and other locations beyond low earth orbit. USNC’s optimized decay heat removal strategies will address key needs in NTP development to make it a viable technology to fulfill NASA human exploration needs. Furthermore, USNC will also provide documented work for hydrogen mass estimates for cooldown that will help in mission planning.

Potential Non-NASA Applications

USNC and other companies are actively developing advanced, small, Earth-based reactors. USNC’s Earth-based reactors are compact and, like NTP systems, require effective ways to deal with decay heat. The work in this SBIR will further USNC’s Earth-based reactor work and may lead to strategies for dealing with decay heat in compact Earth-based reactors.


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