Planetary Regolith Delivery Systems for ISRU
Publication: Journal of Aerospace Engineering
Volume 26, Issue 1
Abstract
This paper describes tests conducted since 2008 at the National Aeronautics and Space Administration (NASA) Kennedy Space Center (KSC) to address engineering challenges associated with delivering planetary regolith to in situ resource utilization (ISRU) systems. The need to excavate regolith under reduced-gravity conditions on a planetary surface and then deliver it to systems for material analysis and/or processing constrains the possible engineering approaches that can be used in space. Mission costs may further limit the mass and available power of a regolith delivery system. Mechanical systems operating in a planetary environment require high reliability with respect to system service life because it is usually difficult or impossible to perform maintenance robotically on a planetary surface. The regolith delivery system for most ISRU systems must have a leak-tight interface between the near-vacuum found on a planetary surface and the pressurized atmosphere within the ISRU reactor. Depending on the mission, the amount of regolith that must be delivered may range from a few grams (e.g., for analysis) to tens of kilograms (e.g., for oxygen production). Hot, spent regolith from an ISRU reactor must eventually be returned to the planetary environment by means of an interface that is capable of operating and sealing over a potentially large temperature range. In this paper, we will describe pneumatic and auger methods of conveying large amounts of regolith that have been studied and demonstrated at NASA KSC and at ISRU field tests and discuss other regolith delivery systems that are being designed for future field tests.
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References
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Information & Authors
Information
Published In
Journal of Aerospace Engineering
Volume 26 • Issue 1 • January 2013
Pages: 169 - 175
Copyright
© 2013 American Society of Civil Engineers.
History
Received: May 21, 2012
Accepted: Jul 20, 2012
Published ahead of production: Jul 24, 2012
Published online: Jul 25, 2012
Published in print: Jan 1, 2013
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