Robust Exploration and Commercial Missions to the Moon Using LANTR Propulsion and In-Situ Propellants Derived From Lunar Polar Ice (LPI) Deposits
Since the 1960s, scientists have conjectured that water icecould survive in the cold, permanently shadowed craters located at the Moons poles Clementine (1994), Lunar Prospector (1998),Chandrayaan-1 (2008), and Lunar Reconnaissance Orbiter (LRO) and Lunar CRater Observation and Sensing Satellite(LCR...
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2017
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| Online Access: | http://hdl.handle.net/2060/20180000364 |
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ftnasantrs:oai:casi.ntrs.nasa.gov:20180000364 |
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ftnasantrs:oai:casi.ntrs.nasa.gov:20180000364 2023-05-15T17:40:04+02:00 Robust Exploration and Commercial Missions to the Moon Using LANTR Propulsion and In-Situ Propellants Derived From Lunar Polar Ice (LPI) Deposits McCurdy, David R. Borowski, Stanley K. Fittje, James E. Burke, Laura M. Ryan, Stephen W. Joyner, Claude R. Unclassified, Unlimited, Publicly available September 13, 2017 application/pdf http://hdl.handle.net/2060/20180000364 unknown Document ID: 20180000364 http://hdl.handle.net/2060/20180000364 Copyright, Public use permitted CASI Spacecraft Propulsion and Power AIAA Paper 2017-5272 GRC-E-DAA-TN46402 American Institute of Aeronautics and Astronautics (AIAA) Space Forum and Exposition - Space 2017; 12-14 Sep. 2017; Orlando, FL; United States 2017 ftnasantrs 2019-07-20T23:21:26Z Since the 1960s, scientists have conjectured that water icecould survive in the cold, permanently shadowed craters located at the Moons poles Clementine (1994), Lunar Prospector (1998),Chandrayaan-1 (2008), and Lunar Reconnaissance Orbiter (LRO) and Lunar CRater Observation and Sensing Satellite(LCROSS) (2009) lunar probes have provided data indicating the existence of large quantities of water ice at the lunar poles The Mini-SAR onboard Chandrayaan-1discovered more than 40 permanently shadowed craters near the lunar north pole that are thought to contain 600 million metric tons of water ice. Using neutron spectrometer data, the Lunar Prospector science team estimated a water ice content (1.5 +-0.8 wt in the regolith) found in the Moons polar cold trap sand estimated the total amount of water at both poles at 2 billion metric tons Using Mini-RF and spectrometry data, the LRO LCROSS science team estimated the water ice content in the regolith in the south polar region to be 5.6 +-2.9 wt. On the basis of the above scientific data, it appears that the water ice content can vary from 1-10 wt and the total quantity of LPI at both poles can range from 600 million to 2 billion metric tons NTP offers significant benefits for lunar missions and can take advantage of the leverage provided from using LDPs when they become available by transitioning to LANTR propulsion. LANTR provides a variablethrust and Isp capability, shortens burn times and extends engine life, and allows bipropellant operation The combination of LANTR and LDP has performance capability equivalent to that of a hypothetical gaseousfuel core NTR (effective Isp 1575 s) and can lead to a robust LTS with unique mission capabilities that include short transit time crewed cargo transports and routine commuter flights to the Moon The biggest challenge to making this vision a reality will be the production of increasing amounts of LDP andthe development of propellant depots in LEO, LLO and LPO. An industry-operated, privately financed venture, with NASA as its initial customer, might provide a possible blueprint for future development and operation With industry interested in developing cislunar space and commerce, and competitive forces at work, the timeline for developing this capability could well be accelerated, quicker than any of us can imagine, and just the beginning of things to come. Other/Unknown Material North Pole NASA Technical Reports Server (NTRS) North Pole |
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Open Polar |
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NASA Technical Reports Server (NTRS) |
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ftnasantrs |
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unknown |
| topic |
Spacecraft Propulsion and Power |
| spellingShingle |
Spacecraft Propulsion and Power McCurdy, David R. Borowski, Stanley K. Fittje, James E. Burke, Laura M. Ryan, Stephen W. Joyner, Claude R. Robust Exploration and Commercial Missions to the Moon Using LANTR Propulsion and In-Situ Propellants Derived From Lunar Polar Ice (LPI) Deposits |
| topic_facet |
Spacecraft Propulsion and Power |
| description |
Since the 1960s, scientists have conjectured that water icecould survive in the cold, permanently shadowed craters located at the Moons poles Clementine (1994), Lunar Prospector (1998),Chandrayaan-1 (2008), and Lunar Reconnaissance Orbiter (LRO) and Lunar CRater Observation and Sensing Satellite(LCROSS) (2009) lunar probes have provided data indicating the existence of large quantities of water ice at the lunar poles The Mini-SAR onboard Chandrayaan-1discovered more than 40 permanently shadowed craters near the lunar north pole that are thought to contain 600 million metric tons of water ice. Using neutron spectrometer data, the Lunar Prospector science team estimated a water ice content (1.5 +-0.8 wt in the regolith) found in the Moons polar cold trap sand estimated the total amount of water at both poles at 2 billion metric tons Using Mini-RF and spectrometry data, the LRO LCROSS science team estimated the water ice content in the regolith in the south polar region to be 5.6 +-2.9 wt. On the basis of the above scientific data, it appears that the water ice content can vary from 1-10 wt and the total quantity of LPI at both poles can range from 600 million to 2 billion metric tons NTP offers significant benefits for lunar missions and can take advantage of the leverage provided from using LDPs when they become available by transitioning to LANTR propulsion. LANTR provides a variablethrust and Isp capability, shortens burn times and extends engine life, and allows bipropellant operation The combination of LANTR and LDP has performance capability equivalent to that of a hypothetical gaseousfuel core NTR (effective Isp 1575 s) and can lead to a robust LTS with unique mission capabilities that include short transit time crewed cargo transports and routine commuter flights to the Moon The biggest challenge to making this vision a reality will be the production of increasing amounts of LDP andthe development of propellant depots in LEO, LLO and LPO. An industry-operated, privately financed venture, with NASA as its initial customer, might provide a possible blueprint for future development and operation With industry interested in developing cislunar space and commerce, and competitive forces at work, the timeline for developing this capability could well be accelerated, quicker than any of us can imagine, and just the beginning of things to come. |
| format |
Other/Unknown Material |
| author |
McCurdy, David R. Borowski, Stanley K. Fittje, James E. Burke, Laura M. Ryan, Stephen W. Joyner, Claude R. |
| author_facet |
McCurdy, David R. Borowski, Stanley K. Fittje, James E. Burke, Laura M. Ryan, Stephen W. Joyner, Claude R. |
| author_sort |
McCurdy, David R. |
| title |
Robust Exploration and Commercial Missions to the Moon Using LANTR Propulsion and In-Situ Propellants Derived From Lunar Polar Ice (LPI) Deposits |
| title_short |
Robust Exploration and Commercial Missions to the Moon Using LANTR Propulsion and In-Situ Propellants Derived From Lunar Polar Ice (LPI) Deposits |
| title_full |
Robust Exploration and Commercial Missions to the Moon Using LANTR Propulsion and In-Situ Propellants Derived From Lunar Polar Ice (LPI) Deposits |
| title_fullStr |
Robust Exploration and Commercial Missions to the Moon Using LANTR Propulsion and In-Situ Propellants Derived From Lunar Polar Ice (LPI) Deposits |
| title_full_unstemmed |
Robust Exploration and Commercial Missions to the Moon Using LANTR Propulsion and In-Situ Propellants Derived From Lunar Polar Ice (LPI) Deposits |
| title_sort |
robust exploration and commercial missions to the moon using lantr propulsion and in-situ propellants derived from lunar polar ice (lpi) deposits |
| publishDate |
2017 |
| url |
http://hdl.handle.net/2060/20180000364 |
| op_coverage |
Unclassified, Unlimited, Publicly available |
| geographic |
North Pole |
| geographic_facet |
North Pole |
| genre |
North Pole |
| genre_facet |
North Pole |
| op_source |
CASI |
| op_relation |
Document ID: 20180000364 http://hdl.handle.net/2060/20180000364 |
| op_rights |
Copyright, Public use permitted |
| _version_ |
1766140852348911616 |