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NASA project developing New Gears that can Withstand Impact, Freezing Temperatures During Lunar Missions

NASA - National Aeronautics and Space AdministrationHampton, VA – Many exploration destinations in our solar system are frigid and require hardware that can withstand the extreme cold. During NASA’s Artemis missions, temperatures at the Moon’s South Pole will drop drastically during the lunar night. Farther into the solar system, on Jupiter’s moon Europa, temperatures never rise above -260 degrees Fahrenheit (-162 degrees Celsius) at the equator.

One NASA project is developing special gears that can withstand the extreme temperatures experienced during missions to the Moon and beyond. Typically, in extremely low temperatures, gears – and the housing in which they’re encased, called a gearbox – are heated.

Andrew Kennett (left) watches as Dominic Aldi (right) uses liquid nitrogen to cool a motor integrated bulk metallic glass gearbox prior to shock testing it. The motor and gearbox are inside the frosty metal “bucket” that contains the liquid nitrogen. The tooling, including the “bucket” is designed to be mounted both vertically (shown) and horizontally on the cube for testing the motor and gearbox in three orientations. (NASA/JPL-Caltech)
Andrew Kennett (left) watches as Dominic Aldi (right) uses liquid nitrogen to cool a motor integrated bulk metallic glass gearbox prior to shock testing it. The motor and gearbox are inside the frosty metal “bucket” that contains the liquid nitrogen. The tooling, including the “bucket” is designed to be mounted both vertically (shown) and horizontally on the cube for testing the motor and gearbox in three orientations. (NASA/JPL-Caltech)

After heating, a lubricant helps the gears function correctly and prevents the steel alloys from becoming brittle and, eventually, breaking.

NASA’s Bulk Metallic Glass Gears (BMGG) project team is creating material made of “metallic glass” for gearboxes that can function in and survive extreme cold environments without heating, which requires energy.

Operations in cold and dim or dark environments are currently limited due to the amount of available power on a rover or lander.

The BMGG unheated gearboxes will reduce the overall power needed for a rover or lander’s operations, such as pointing antennas and cameras, moving robotic arms, handling and analyzing samples, and mobility (for a rover). The power saved with the BMGG gearbox could extend a mission or allow for more instruments.

The motor and gearbox are mounted for testing in one of two horizontal orientations. Frost forms on the surface of the “bucket” when liquid nitrogen is used to cool the hardware to the test temperature of -279 degrees Fahrenheit (-173 degrees Celsius). (NASA/JPL-Caltech)
The motor and gearbox are mounted for testing in one of two horizontal orientations. Frost forms on the surface of the “bucket” when liquid nitrogen is used to cool the hardware to the test temperature of -279 degrees Fahrenheit (-173 degrees Celsius). (NASA/JPL-Caltech)

The team recently tested the gears at NASA’s Jet Propulsion Laboratory in Southern California. At JPL’s Environmental Test Laboratory, engineers mounted the motor and gearbox on a tunable beam designed to measure the response an item has to a shock, or forceful impact. Team members then used liquid nitrogen to cool the gears down to roughly to -279 degrees Fahrenheit (-173 degrees Celsius).

Next, they fired a cylindrical steel projectile at the beam to simulate a “shock event.” Shock testing is used to ensure spacecraft hardware will not break during events that cause a sudden jolt, such as the release of an antenna or what a spacecraft experiences during entry, descent, and landing.

 

 

The test simulated how the bulk metallic glass gears might behave when collecting a regolith sample during the lunar night – which spans roughly 14 days on Earth – or deploying a science instrument on an ocean world in our solar system.

“Before NASA sends hardware like gearboxes, particularly those made with new materials, to extremely cold environments, we want to make sure they will not be damaged by the stressful events that occur during the life of a mission,” said Peter Dillon, BMGG project manager at JPL. “This shock testing simulates the stresses of entry, descent, and landing, and potential surface operations.”

The shock for the test is generated by launching a steel mass (one of the round cylinders in the lower left of the image) into the bottom of the long steel beam. The large clamps set the length of the beam that can “ring” from the impact. By changing the clamp position the profile of the shock can be tuned, hence the name “tunable beam.” The large cube mounted to the beam simplifies mounting of hardware for testing. The shock event is captured using an accelerometer mounted at the hardware. (NASA/JPL-Caltech)
The shock for the test is generated by launching a steel mass (one of the round cylinders in the lower left of the image) into the bottom of the long steel beam. The large clamps set the length of the beam that can “ring” from the impact. By changing the clamp position the profile of the shock can be tuned, hence the name “tunable beam.” The large cube mounted to the beam simplifies mounting of hardware for testing. The shock event is captured using an accelerometer mounted at the hardware. (NASA/JPL-Caltech)

Before each shock test, a team member poured liquid nitrogen over the motor and gearbox contained in a “bucket.” Liquid nitrogen, which boils at -320 degrees Fahrenheit (-196 degrees Celsius), brought the gearbox’s temperature below -279 degrees Fahrenheit (-173 degrees Celsius). The liquid nitrogen drained and, within a few seconds, a steel impactor fired at a steel beam on which the motor and gearbox were mounted.

The team then ran the motor to drive the gearbox to determine whether or not the shock event had damaged the gearbox and its motor. The team monitored the electrical current required to run the motor and listened for any irregular sounds that indicated damage. The motor and gearbox were shock tested twice in three different orientations.

 

 

Each test demonstrated that the gears could withstand a “shock event” at a temperature as low as -279 degrees Fahrenheit (-173 degrees Celsius).

“This is an exciting event as it demonstrates both the mechanical resilience of the bulk metallic glass alloy and the design of the gearbox,” Dillon said. “These gears could help enable potential operations during the lunar night, in permanently shadowed lunar craters, in polar regions on the Moon, and on ocean worlds.”  

The BMGG team will perform additional cold temperature testing next year to qualify the gears for use in future NASA missions.

Learn more about the BMGG project: www.nasa.gov/directorates/spacetech/game_changing_development/projects/BMGG/

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