In-Space Propulsion Technologies
Program
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The In-Space Propulsion Program work being performed
at the Glenn Research Center develops primary propulsion
technologies that can benefit near and mid-term science missions
by reducing cost, mass and/or travel times. The In-Space
Program is working to develop next generation electric propulsion
technologies, including Ion and Hall thrusters. Solar
Sails, which are a form of propellantless propulsion, are
also being developed. Solar Sails rely on the naturally occurring
sunlight for the propulsion energy. Other propulsion technologies
being developed include advanced chemical propulsion and
aerocapture. |
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Next Evolutionary Xenon Thruster
(NEXT) |
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NEXT
is one of the projects in the solar electric propulsion
technology area. This project is developing the next
generation ion engine technology and is managed by the
NASA Glenn Research Center. NEXT is a propulsion
system that could revolutionize the way we send science
missions deeper into the solar system. The thruster
uses xenon gas and electrical power to drive future spacecraft.
The goal of NEXT program is to develop an ion thruster
capable of supporting several key NASA missions in the
next decade. The thruster system will enable NASA
to reach destinations in our solar system that cannot be
reached by conventional chemical propulsion.
The major feature of NEXT is a thruster that utilized
design knowledge gained from the ion thruster that successfully
propelled the Deep Space 1 to a flyby of asteroid Braille
and the comet Borrelly. NEXT will have a significant
increase in power compared to that of Deep Space 1's ion
thruster while increasing efficiency and system performance
characteristics. Advanced power processing, xenon propellant
management and thruster gimbal technologies are also being
developed by the team to complete the NEXT ion propulsion
system |
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+ Next
Evolutionary Xenon Thruster (NEXT) Fact Sheet 
+ Next
Evolutionary Xenon Thruster (NEXT) Image Gallery |
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Thruster
Technologies |
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Ion
Thrusters
An ion propulsion system's efficient use of fuel and
electrical power enable modern spacecraft to travel farther,
faster, and cheaper than any other propulsion technology
currently available. Ion thrusters are currently used
for stationkeeping on communication satellites and for main
propulsion on deep space probes. |
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+ Ion
Propulsion Research at Glenn |
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Hall
Thrusters
Hall thrusters use an electric field to accelerate
ions, similar to Ion thrusters. Hall thrusters utilize
a radial magnetic field to generate an azimuthal Hall current. This
current interacts with the radial magnetic field producing
a volumetric (j X B) accelerating force on the plasma. As
with gridded ion thrusters, Hall thrusters can be categorized
according to their respective power sources.
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+ Hall
Thruster Images |
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Solar Sails |
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Solar
sail propulsion uses the Sun's energy to enable travel
through space, much the way wind pushes sailboats across
water. The technology bounces a stream of solar energy
particles called photons off giant, reflective sails made
of lightweight material 40 to 100 times thinner than a
piece of writing paper. The continuous pressure provides
sufficient thrust to perform maneuvers, such as hovering
at a point in space and rotating the space vehicle's plane
of orbit, which would require too much propellant for conventional
rocket systems. Because the Sun provides the necessary
propulsive energy, solar sails also require no onboard
propellant, thus reducing payload mass. |
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+ Solar
Sail Image Gallery
+ Solar
Sail Video Gallery |
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Advanced Chemical |
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Chemical
propulsion systems have historically been the primary
means for transportation of payloads
in space because they generate the very
large amounts of thrust required to overcome
the effect of Earth's gravity.
Many advanced chemical propellants are being analyzed
and tested to determine their performance and applicability
to in-space propulsion. Chemical rocket systems include
solid, cryogenic liquid, and storable liquid propellants,
as well as hybrid and cold gas rockets. |
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+ Advanced
Chemical Fact Sheet |
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Aerocapture |
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Aerocapture
is another form of propellantless propulsion. This
technology uses the atmosphere of a destination to achieve
a velocity change necessary to be captured into orbit. |
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+ Aerocapture
Fact Sheet |
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Mission and Systems
Analysis and ISPT Tool Development |
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Mission
and systems analysis looks at NASA missions to optimize
trajectories, trip times and payload
delivered. These studies help
determine what technologies are needed to achieve the desired
Science objectives. These studies also compare technologies,
spacecraft concepts and designs to most efficiently goals. The
ISPT project also develops tools for the user community to
assess the applicability of In-Space Technologies.
The Tools can be found here.
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+ Mission
and Systems Analysis Fact Sheet |
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Emerging Technologies |
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NASA's
In-Space Propulsion Technologies Program is developing
experiments to demonstrate tether-based propulsion - which
draws power from the Sun and uses the magnetic field surrounding
the Earth to propel spacecraft without the use of on-board
propellant. The innovative technology could dramatically
reduce the cost of raising the orbits of other spacecraft,
including those destined for deep-space missions. |
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+ Click
here to view the In-Space Propulsion Image Gallery |
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The Glenn Research Center's In-Space
Propulsion program is teamed up with the Marshall
Space Flight Center (MSFC), Langley Research Center (LaRC),
Ames Research Center (ARC), Jet Propulsion Laboratory (JPL)
Jet Propulsion Laboratory (JPL), Goddard Space Flight Center
(GSFC), Johnson Space Center (JSC), and Dryden Flight Research
Center (DFRC). |
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In-Space Propulsion Technologies Program News
