Illustration of the Cold Operable Lunar Deployable Arm (COLDArm), which is able to considerably enhance the utility of robotic arms for lunar landers. Credit: NASA, JPL-Caltech
COLDArm, the Cold Operable Lunar Deployable Arm, will considerably enhance the utility of robotic arms for lunar landers. The arm will allow manipulation capabilities in very low temperatures, together with through the lunar night time, when temperatures can drop under -280 levels Fahrenheit (-173 degrees Celsius). COLDArm is being developed by NASA’s Jet Propulsion Laboratory (JPL) in Southern California.
The robotic arm, which is designed for a lunar lander, leverages a highly capable smartphone processing technology used for the Mars Helicopter, Ingenuity, and can perform a variety of tasks in extremely cold temperatures without the need for a heater. This includes things like scooping and analyzing lunar soil, deploying instruments, and capturing photos of the lander’s surroundings.
Current robotic arm designs for lunar landers require heaters to keep the gears inside the arm from stressing and breaking when exposed to extremely cold temperatures experienced during the lunar night. COLDArm’s design features special gears and motor controllers that can operate in extreme temperatures without the need for heat, and thus, conserves power and mass for the mission.
This sketch displays the COLDArm design of a lunar lander. Credit: NASA, JPL-Caltech
Similar to the Mars Phoenix and Mars InSight robotic arms, COLDArm features 4 degrees of freedom (movable joints), is approximately 6.5 feet (2 meters) long and can produce approximately 10 pounds of force. A sensor embedded near the arm’s “wrist” will measure and regulate the amount of force the arm exerts during any particular movement to stop the arm when the directed loads have been met and to protect the arm. The arm will be equipped with cameras for 3D mapping, lunar surface imaging, and general operations.
The COLDArm team is evaluating a variety of attachments and small instruments to potentially operate at the end of the arm, including a 3D-printed titanium scoop with features to collect geotechnical properties of the lunar regolith. This includes working with the awardees of the NASA@Work “Be the Game Changer” and the open-to-the-public “Honey, I Shrunk the Payloads” Challenges for potential integration of their payload instruments with COLDArm for a future demonstration.
The avionics could eventually be programmed to autonomously control the arm’s joints to perform various movements and collect pictures and sensor data. Through future software developments, COLDArm’s avionics could enable autonomous operations on ocean worlds like Jupiter’s moon, Europa.
COLDArm’s gears are being developed under the Bulk Metallic Glass Gear project. Under the NASA Small Business Innovative Research Program, Motiv Space Systems, Inc. is leading the design and fabrication of the arm and motor controllers for COLDArm. Demonstrating these technologies will enable missions to future lunar, Martian, and ocean worlds extreme environments.
This past September, in a JPL test bed filled with material to simulate lunar regolith (broken rock and dust on the Moon), COLDArm successfully completed experiments that assessed its ability to gather data on the properties of that regolith. Now COLDArm has been sent on to complete the same rigorous testing in spacelike conditions that every mission faces. It’s targeting a launch in the late 2020s. The COLDArm project is funded through the Lunar Surface Innovation Initiative (LSII) and managed by the Game Changing Development (GCD) program in NASA’s Space Technology Mission Directorate.
