The surface of the Moon is a harsh environment with no air, low gravity, dust, and micrometeorites—tiny rocks or metal particles—flying faster than 22,000 mph. These conditions can pose a hazard to astronauts, their dwellings, and spacecraft.
Engineers at NASA Glenn Research Center's Ballistic Impact Lab are
working to help the agency select materials for future Artemis missions and
predict how they will perform while on the lunar surface.
The innovative lab, which features a 40-foot-long air
gun capable of firing at velocities of 3,000 feet per second, has
become a go-to destination for NASA as it examines situations ranging from the
effects of bird collisions with aircraft to ballistic impacts on spacecraft.
Now, the team has been called to test several
different textiles that will protect humans during Artemis missions to
the Moon and beyond.
“If the object is pressurized, a leak can be
catastrophic depending on how big and fast the leak is,” said Mike Pereira, the
Ballistic Impact Lab’s technical lead. “Running this type of ballistic impact
test is essential to a variety of NASA aeronautics and space exploration
missions to ensure equipment and materials reliability.”
In the first series of tests, the team evaluated
materials NASA is considering for habitats, which are designed to be relatively
soft and flexible, but very stiff if struck.
To assess the potential fabrics and gauge how many
layers would be needed to stop micrometeorite penetration, engineers used the
facility’s air gun to fire steel ball bearings at various fabrics. The team
connected the air gun to a vacuum chamber to remove air resistance, allowing it
to shoot faster, while a suite of sensors and high-speed cameras measured how
each material absorbed or deflected energy.
Mike Pereira, the Ballistic Impact Lab’s technical lead, prepares an impact-drop tester before a spacesuit materials test. Credits: NASA
The resulting impacts take each fabric to
the brink of failure to better understand the upper limits of durability and to
ensure each can handle the harsh, punishing environment of space exploration.
Other materials tested included spacesuits that could
be used for extravehicular activities on the lunar surface and in orbit.
Understanding how materials respond to impacts is important for astronaut
safety, according to Pereira.
The composite materials were a combination of
substances that include fibers for strength and bonding resins to allow
transfer of stress and energy. To evaluate these potential materials, engineers
used the lab’s vertical-impact-drop tester to hurl mock simulated Moon rocks
made of basalt onto potential spacesuit materials.
Engineers at NASA’s Johnson Space
Center are analyzing the ballistics testing
data to determine which materials will be best for a variety of lunar
exploration items.
The next challenge for the Glenn team is testing
materials that could capture space debris. New types of aerogels that are lighter and stronger might be the key to developing and
deploying in-space devices given ease of use and reduced mass for launch.
Top Image: Engineers pummeled potential spacesuit
materials with mock moon rocks made of basalt like these to see how the fabrics
would hold up on the lunar surface.
Ellen Bausback
NASA
Glenn Research Center
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