From: Ultra Safe Nuclear Technologies
Posted: Tuesday, October 20, 2020
Ultra Safe Nuclear Technologies (USNC-Tech) has delivered a design concept to NASA as part of a study on nuclear thermal propulsion (NTP) flight demonstration. NTP technology provides unprecedented high-impulse thrust performance for deep space missions such as crewed missions to the moon and Mars. The NASA-sponsored study, managed by Analytical Mechanics Associates (AMA), explored NTP concepts and designs enabling deep space travel.
"We want to lead the effort to open new frontiers in space, and do it quickly and safely," said Dr. Michael Eades, principal engineer at USNC-Tech. "Our engine maximizes the use of proven technology, eliminates failure modes of previous NTP concepts, and has a specific impulse more than twice that of chemical systems."
Advancements in nuclear fuel design and passive safety measures pioneered by Ultra Safe Nuclear (USNC, USNC-Tech's parent company) with Fully Ceramic Micro-encapsulated (FCM™) fuel enabled USNC-Tech to create a novel NTP concept with specialized performance capabilities. The enhanced safety characteristics and design flexibility of the USNC-Tech concept is a critical step forward in achieving extensibility of NTP systems to deep-space missions.
"Key to USNC-Tech's design is a conscious overlap between terrestrial and space reactor technologies," explained Dr. Paolo Venneri, CEO of USNC-Tech. "This allows us to leverage the advancements in nuclear technology and infrastructure from terrestrial systems and apply them to our space reactors." A prime example of this is the nuclear fuel at the core of the USNC-Tech NTP concept.
The USNC-Tech NTP concept uses a specialized variation of USNC's FCM™ fuel, featuring high-assay low-enriched Uranium (HALEU) ZrC-encapsulated fuel particles. This variation enables high-temperature operation while maintaining the integrity of the fuel. FCM™ fuel is extremely rugged, enabling a new family of inherently safe space-optimized reactor designs that ensure astronaut safety and environmental protection. Using low quantities of HALEU, this unique NTP concept delivers high thrust and specific impulse previously only achievable through high-enriched uranium. Furthermore, FCM™ fuel leverages pre-existing supply chains and manufacturing facilities used by terrestrial nuclear reactor developers, reducing production risks and enabling sustainable industry involvement.
In an NTP system, exceptionally high levels of thrust are achieved by passing propellant through a specialized reactor core, reducing interplanetary transfer durations. Additionally, NTP systems achieve expanded payload mass capabilities due to their two-fold increase in specific impulse compared with chemical propulsion systems. As a result, NTP offers an entirely new mode of in-space transportation, enabling rapid movement of high-mass spacecraft architectures to deep space destinations (current NTP designs could deliver a crew to Mars in as few as three months) and a new, highly agile degree of cislunar mobility. If designed with commercial sustainability in mind, modern NTP systems can offer these benefits to commercial space entities in addition to government agencies like NASA and the DOD, enabling new business opportunities such as rapid orbital logistics services.
USNC-Tech prioritizes technologies and architectures that enable commercial manufacturing and near-term deployment while meeting safety and mission requirements. The NTP concept delivered by USNC-Tech was designed to enable a successful near-term system demonstration and reduce barriers to full-scale deployment.
If you would like to learn more about the NTP concept designed by USNC-Tech and AMA, please contact USNC-Tech by email at firstname.lastname@example.org.
About Ultra Safe Nuclear Technologies A subsidiary of Ultra Safe Nuclear, Ultra Safe Nuclear Technologies (USNC-Tech) designs and deploys advanced nuclear technologies for space exploration and other operations in remote and extreme environments. Based in Seattle, WA, USNC-Tech's technologies include fission and radioisotope power sources that can be used across various vehicles, spacecraft, and mission architectures from the deep sea to deep space. Since 2015, USNC-Tech has collaborated closely with NASA and other US Government agencies and industry partners to mature space nuclear power and propulsion technologies.
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