2006
DOI: 10.1063/1.2169292
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Development of a Microchannel In Situ Propellant Production System

Abstract: This document was printed on recycled paper. PNNL-15456 Development of a MicrochannelIn Situ Propellant Production System Executive SummaryAn in situ propellant production plant (ISPP) on future Mars robotic missions can produce oxygen (O 2 ) and methane (CH 4 ) that can be used for propellant for the return voyage. By producing propellants from Mars' atmospheric carbon dioxide (CO 2 ) and hydrogen (H 2 ) brought from Earth, the initial mass launched in low Earth orbit can be reduced by 20 to 45%, as compared… Show more

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Cited by 5 publications
(4 citation statements)
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“…The CO2 capture model is based on empirical data collected at Kennedy Space Center by testing a near-relevant scale CO2 freezer system. The Sabatier model is anchored to the work performed at the Pacific Northwest National Laboratory in the field of microchannel reactors for ISRU 8 . The condenser coil is based on standard thermodynamic equations and not anchored to any specific hardware.…”
Section: B Subsystemsmentioning
confidence: 99%
“…The CO2 capture model is based on empirical data collected at Kennedy Space Center by testing a near-relevant scale CO2 freezer system. The Sabatier model is anchored to the work performed at the Pacific Northwest National Laboratory in the field of microchannel reactors for ISRU 8 . The condenser coil is based on standard thermodynamic equations and not anchored to any specific hardware.…”
Section: B Subsystemsmentioning
confidence: 99%
“…Microchannel RWGS reactors have demonstrated CO 2 conversion from 40 to over 50 percent with selectivity to carbon monoxide of >99.99 percent and with minimal pressure drop. 21 Assuming a conversion of 50 percent, the net reaction is the same as for the solid oxide electrolysis technology, with the assumption that all of the unreacted H 2 and all H 2 from water electrolysis can be recycled back into the reactor (d + f = 1 in eqn 2). In addition to a gas separator to separate the CO from the unconverted CO 2 and H 2 , the RWGS process also requires several additional components: a condenser or other device to separate the water from the CO, CO 2 , and H 2 ; a water electrolyzer; a dryer to dry the oxygen from the electrolyzer before liquefaction and storage; and a dryer to dry the H 2 before recirculation back to the RWGS reactor.…”
Section: A Mars Atmosphere Processingmentioning
confidence: 99%
“…Another acquisition concept with good potential for low mass and power is a rapid cycle sorption pump. 21 In this concept, a material that preferentially adsorbs carbon dioxide is used to adsorb the CO 2 at low temperature and pressure and then release it at higher pressure when heated. The original mission studies envisioned adsorbing for the entire Martian night as with the cryofreezer, but because of the extremely low density of the sorbent material and its ability to adsorb CO 2 at only a fraction of its own weight, this concept resulted in a very large system.…”
Section: A Mars Atmosphere Acquisitionmentioning
confidence: 99%
“…Several compact single-channel adsorbers, such as that shown in Figure 3.8, were fabricated and tested to demonstrate proof-of-concept for CO 2 capture and subsequent delivery in rapid adsorption/desorption cycles Brooks et al 2002;Wegeng et al 2003Wegeng et al , 2004.…”
Section: Development and Testing Of A Single-channel Adsorbermentioning
confidence: 99%