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A Solar Electric Propulsion Mission with Lunar Power Beaming. Henry W. Brandhorst, Jr. , Julie A. Rodiek and Michael S. Crumpler Space Research Institute, Auburn University Mark J. O’Neill ENTECH, Inc. June 4, 2007. Outline. Introduction Getting to the moon Lunar Orbit Equatorial Orbit - PowerPoint PPT Presentation
Space Research Institute
SPACE
RESEARCH
INSTITUTE
Rutgers Symposium on Lunar Settlements, June 4-8, 2007
A Solar Electric Propulsion Mission with Lunar Power Beaming
Henry W. Brandhorst, Jr., Julie A. Rodiek and Michael S. Crumpler
Space Research Institute, Auburn University
Mark J. O’Neill
ENTECH, Inc.
June 4, 2007
Space Research Institute
SPACE
RESEARCH
INSTITUTE
Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Outline
Introduction
Getting to the moon
Lunar Orbit» Equatorial Orbit
Orbital analysis Power delivery
» Polar Orbit Orbital analysis Power delivery
Summary and Conclusions
Space Research Institute
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Rationale
NASA’s Vision for Space Exploration to return to the moon» Lunar south pole desired location
Up to 70% sunlight per year
» Other locations being driven by science Equatorial and high latitude locations
Energy storage for the lunar night is massive» Solar array/RFC system – 20 kWe
» Weight ~6 MT with cryogenic storage Can power beaming reduce the mass of night time storage?
» Orbital options to provide power to locations within ±45º of the equator» Molniya-type orbits for polar -90 to 45º S (or +90 to 45º N)» Two year orbital analysis
Space Research Institute
SPACE
RESEARCH
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Getting to the Moon
Solar electric propulsion mission» ~4343 kg spacecraft
1400 kg Xe propellant Hall thrusters – 10 to 50 kW (3)
» 100 kW Stretched Lens Solar Array 300 W/kg, 300 W/m2, TJ cells
No detailed design of spacecraft
Spiral out through Van Allen belts» 500 km initial orbit, 28º inclination
89 day trip time, plane change at moon
Compared to 272 day trip time from previous SEP space tug analysis
» Radiation dose calculated with SPENVIS
Provides solar array degradation
70%
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Coverglass Thickness (mils)
P/P
o (
%)
SEP Laser Mission
600 kW Tug Mission
Selected shielding
Space Research Institute
SPACE
RESEARCH
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Lunar Orbit – Single Spacecraft
Wide range of elliptical equatorial orbits examined
» Chose 500 x 30,000 km orbit
Ran STK 7.1 for arbitrary 2-year period
» July 1, 2008 to June 30, 2010
Determined when surface sites between ±45º were in view of the satellite
» AND the satellite was in sunlight
Times without satellite coverage were up to 164 hours (6.83 days)
» Offers no major reduction in energy storage mass
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Space Research Institute
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Lunar Orbit – Two Spacecraft(500 x 30,000 km equatorial orbits)
2nd satellite access times with orbital location
Equatorial satellite orbits about the moon with beaming
Satellite 2 Base Access Time vs. Satellite 1 Argument of Perigee Delta
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Satellite 2 vs. Satellite 1 Argument of Perigee Delta(Degrees)
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Space Research Institute
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Dual Satellite View Times
Adding second satellite had a major impact on view times
» Adjusting orbital relationship between the satellites boosted view times
Satellite 2: 3870 hrs access» Power beaming times increased
significantly: Only 8 periods of 84 hrs (3.5
days) with no access Rest of the time it’s lower than 54
hrs (2.25 days)
Substantially reduces the mass of surface storage system
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Space Research Institute
SPACE
RESEARCH
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Overlapping Coverage
Because the satellites are in equatorial orbits, their view times often overlap
Provides an opportunity for substantial power increases
» Beaming laser power to a planar GaAs (1-J) photovoltaic array on surface
» Monochromatic laser beam cannot excite multiple junction solar cells
Can’t use tracking concentrator array to simultaneously view two satellites
Space Research Institute
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
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Laser Power Beaming
Uses 850 nm diode pumped laser, 4 m2 area (2.26 m dia) beaming aperture
» Aperture controls surface beam size» ~90 kW satellite power available
Laser beam incidence angles determined by satellite orbit
» Surface array may track in the E-W axis when in sunlight
Laser intensity varies due to view angles and orbital elevation
» Satellite near moon when beaming starts – high intensity
» At 30,000 km, beam intensity drops to ~0.2 AM0 sunlight
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Laser beam incidence angles
Space Research Institute
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Surface Solar Array/Laser Beam
Assuming 1-J GaAs cell surface solar array
» Nominal 40 kW surface power» ~18% efficient GaAs cells» Temperature corrected
Size of laser beam on surface GaAs solar array determined
» Less than total array area for maximum power delivery
» Largest beam size is at 30,000 km distance
About 60% of GaAs surface solar array is covered
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Space Research Institute
SPACE
RESEARCH
INSTITUTE
Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Lunar Power Produced by Laser
Chose 45º N site for calculation» Most difficult case
Calculated laser beam power from satellite
» 50% conversion of orbital electricity into laser beam
» Plus 12% mirror losses Calculated laser power received
by surface GaAs solar array» 45% conversion efficiency
18 kW power delivered to site» Adequate for night time power
needs» Storage for 64 hrs maximum
However, NASA’s interest is in a south polar location, so…
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Po
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kW)
Space Research Institute
SPACE
RESEARCH
INSTITUTE
Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Polar Power Beaming Satellites
Two satellites in polar elliptical orbit
» Offset by ~180º» 500 x 5,000 km orbit» ~7.5 hr orbital time» Apogee over the south pole
850 nm laser beam» 1.5 m2 aperture (1.38 m dia)
Increases beam size on surface vs previous case
Uses 1-J GaAs tracking array on surface
» Can track only one satellite» Or can use fixed array
Reduces surface power
Space Research Institute
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RESEARCH
INSTITUTE
Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Satellite Parameters – 8/23-24/08(500 x 5,000 km Polar Orbit)
Space Research Institute
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Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Access Times for Polar Orbits
Polar orbits give excellent access times
» From the pole to ~30º
» 5,000 km apogee has least time Requires the second satellite Both satellite access times are
comparable Access time depends on satellite
altitude» Higher provides more access
Longer beam distance reduces power received
» Second satellite can provide more power
If it can also be tracked Or use planar array
Space Research Institute
SPACE
RESEARCH
INSTITUTE
Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Power Delivered to Surface
With a tracking array, power to the surface is essentially constant
» ~16.8 kW per satellite» 50% power conversion to laser beam» 45% conversion of laser into power
Includes other losses as well
» Assumes a 15 kW surface array (in sunlight, 62 m2 in area)
Neither receiving array area nor laser beam intensity is excessive
Can also adjust beaming parameters
With two satellites, the longest time a receiver at 45º does not receive power is:
» Only 1.5 hours maximum, less for a polar site» Substantially reduces storage!
Beaming is a very plausible option!
Space Research Institute
SPACE
RESEARCH
INSTITUTE
Rutgers Symposium on Lunar Settlements, June 4-8, 2007
Summary
Two cases of lunar power beaming were studied» Equatorial orbit, ±45º N-S, two satellites, 500 x 30,000 km (2 year)
850 nm laser, 4 m2 beaming aperture Delivers up to 18 kW with two satellites to GaAs surface array
› Partial tracking
Eight times with storage times of 84 hrs, rest of time <54 hrs
» Polar orbit, -90 to 45º S two satellites, 500 x 5,000 km (same for N) 850 nm laser, 1.5 m2 beaming aperture Delivers 16.8 kW with either satellites Maximum dark time of only 1.5 hrs
› Insignificant storage time
Laser power beaming to lunar surface seems feasible» Multiple orbits are possible» Substantial reduction in energy storage times for any location» Can yield significant mass savings for exploration architecture
