An experimental loop for simulating nuclear reactors in space

Date:
September 22, 2021
Source:
Penn State
Summary:
Nuclear thermal propulsion, which uses heat from nuclear reactions
as fuel, could be used one day in human spaceflight, possibly
even for missions to Mars. Its development, however, poses a
challenge. The materials used must be able to withstand high heat
and bombardment of high-energy particles on a regular basis. A
nuclear engineering doctoral student is contributing to research
that could make these advancements more feasible.



FULL STORY ========================================================================== Nuclear thermal propulsion, which uses heat from nuclear reactions as
fuel, could be used one day in human spaceflight, possibly even for
missions to Mars.

Its development, however, poses a challenge. The materials used must be
able to withstand high heat and bombardment of high-energy particles on
a regular basis.


==========================================================================
Will Searight, a nuclear engineering doctoral student at penn State,
is contributing to research that could make these advancements more
feasible. He published findings from a preliminary design simulation
in Fusion Science and Technology, a publication of the American Nuclear Society.

To better investigate nuclear thermal propulsion, Searight simulated a
small- scale laboratory experiment known as a hydrogen test loop. The
setup mimics a reactor's operation in space, where flowing hydrogen
travels through?the core and propels the rocket -- at temperatures up to
nearly 2,200 degrees Fahrenheit. Searight developed the simulation using dimensions from detailed drawings of tie tubes, the components that make
up much of the test loop through which hydrogen flows. Industry partner
Ultra Safe Nuclear Corporation (USNC) provided the drawings.

"Understanding how USNC's components behave in a hot hydrogen environment
is crucial to bringing our rockets to space," Searight said. "We're
thrilled to be working with one of the main reactor contractors for
NASA's space nuclear propulsion project, which is seeking to produce
a demonstration nuclear thermal propulsion engine within a decade."
Advised by Leigh Winfrey, associate professor and undergraduate program
chair of nuclear engineering, Searight used Ansys Fluent, a modeling
software, to design a simulation loop from a stainless steel pipe with
an outer diameter of about two inches. In the model, the loop connects
to a hydrogen pump and circulates hot hydrogen through a test section
adjacent to a heating element.

Searight found that while consistent heating of hydrogen to 2,200 degrees Fahrenheit was possible, it was necessary to include a heating element
directly above the test section to prevent a reduction in heating. Data collected from the modeling software showed that the flow of hydrogen
through the test section was smooth and uniform, reducing uneven
distribution of heat through the loop that could jeopardize the setup's
safety and lifespan. Analysis of the results also verified that stainless
steel would allow for more convenient and cost- effective construction
of the loop.

"We are excited to take the first steps in developing a unique capability
for extreme environment simulation at Penn State," Winfrey said. "This preliminary work will enable us to pursue research that could have a
major impact on the future of space exploration." With further research, Searight's preliminary work could enable expanded testing of materials
that could one day be implemented to create faster, more efficient space
travel using reactor-fueled rockets.

Recently, Searight received the George P. Shultz and James W. Behrens
Graduate Scholarship from ANS. Searight will use the award to support
his future work on the test loop. The $3,000 scholarship honors Shultz,
a nuclear nonproliferation advocate and Presidential Medal of Freedom
recipient who died in February, and Behrens, a previous ANS board member
who held numerous positions in the national security sector.

A NASA Small Business Innovation Research contract supported this work.

========================================================================== Story Source: Materials provided by Penn_State. Original written by
Gabrielle Stewart. Note: Content may be edited for style and length.


========================================================================== Journal Reference:
1. William Searight, Leigh Winfrey. Preliminary Design of a Hot
Hydrogen
Test Loop for Plasma-Material-Interaction Evaluation. Fusion
Science and Technology, 2021; 1 DOI: 10.1080/15361055.2021.1913373 ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2021/09/210922121831.htm

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