Lunar Production System for Extracting Oxygen from Regolith

AbstractA study was conducted to determine the mass and power of an in situ propellant production plant producing 10.5 t of liquid oxygen per year from the regolith at the lunar south pole. The carbothermal reduction process was selected for oxygen extraction from the regolith, using direct solar en...

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Bibliographic Details
Published in:Journal of aerospace engineering 2021-07, Vol.34 (4)
Main Authors: Linne, Diane L, Schuler, Jason M, Sibille, Laurent, Kleinhenz, Julie E, Colozza, Anthony J, J. Fincannon, Homer, Oleson, Steven R, Suzuki, Nantel H, Moore, Landon
Format: Article
Language:English
Subjects:
Command and control
Concentrators
Electric power systems
Hardware
In situ propellant production
In situ resources utilization
Liquid oxygen
Lunar surface
Propellant production
Regolith
Solar arrays
Solar collectors
Solar energy
South Pole
Technical Papers
Thermal management
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Summary:AbstractA study was conducted to determine the mass and power of an in situ propellant production plant producing 10.5 t of liquid oxygen per year from the regolith at the lunar south pole. The carbothermal reduction process was selected for oxygen extraction from the regolith, using direct solar energy from a concentrator for the thermal heating in the carbothermal reactor, and solar arrays for the remaining electrical power needs. The baseline lander design selected for delivery of the production plant is capable of landing a payload mass of 3,600 kg and has significant cargo area available below the propulsion deck close to the ground for the in situ resource utilization (ISRU) hardware. Total mass for the 10.5-t oxygen plant, including all power systems, structure, command and control, communication, thermal management, and 30% margin, was 4,145 kg, exceeding the lander’s payload capability. A second design of a smaller plant producing 7 t of oxygen per year resulted in a mass of 3,459 kg, which is within the lander’s capability. Mass payback ratio for the 10.5- and 7-t oxygen plants is 0.4 and 0.5  (kg hardware)/(kg oxygen/yr), respectively, and indicates that a net gain of mass on the lunar surface can be realized in three to four months.
ISSN:0893-1321
1943-5525
DOI:10.1061/(ASCE)AS.1943-5525.0001269