The New Technology
Planetary science missions using
small spacecraft will be required to perform challenging propulsive
maneuvers—such as achieving planetary escape velocities, orbit capture, and
more—that require a velocity change (delta-v) capability well in excess of typical
commercial needs and the current state-of-the-art. Therefore, the #1 enabling
technology for these small spacecraft missions is an electric propulsion system
that can execute these high-delta-v maneuvers. The propulsion system must
operate using low power (sub-kilowatt) and have high-propellant throughput
(i.e., the capability to use a high total mass of propellant over its lifetime)
to enable the impulse required to execute these maneuvers.
After many years of research and
development, researchers at NASA Glenn Research Center (GRC) have created a
small spacecraft electric propulsion system to meet these needs—the NASA-H71M sub-kilowatt Hall-effect thruster. In addition, the successful
commercialization of this new thruster will soon provide at least one such solution to
enable the next generation of small spacecraft science missions requiring up to
an amazing 8 km/s of delta-v. This technical feat was accomplished by the
miniaturization of many advanced high-power
solar electric propulsion technologies developed over the last decade for applications such as
the Power and Propulsion Element of Gateway, humanity’s first space station around the Moon.
Left: NASA-H71M Hall-effect thruster on the Glenn
Research Center Vacuum Facility 8 thrust stand. Right: Dr. Jonathan Mackey
tuning the thrust stand prior to closing and pumping down the test facility.
Benefits of This Technology for Planetary Exploration
Small spacecraft using the
NASA-H71M electric propulsion technology will be able to independently maneuver
from low-Earth orbit (LEO) to the Moon or even from a geosynchronous transfer
orbit (GTO) to Mars. This capability is especially remarkable because
commercial launch opportunities to LEO and GTO have become routine, and the
excess launch capacity of such missions is often sold at low cost to deploy
secondary spacecraft. The ability to conduct missions that originate from these
near-Earth orbits can greatly increase the cadence and lower the cost of lunar
and Mars science missions.
This propulsion capability will
also increase the reach of secondary spacecraft, which have been historically
limited to scientific targets that align with the primary mission’s launch
trajectory. This new technology will enable secondary missions to substantially
deviate from the primary mission’s trajectory, which will facilitate
exploration of a wider range of scientific targets.
In addition, these secondary
spacecraft science missions would typically have only a short period of time to
collect data during a high-speed flyby of a distant body. This greater
propulsive capability will allow deceleration and orbital insertion at planetoids
for long-term scientific study.
Furthermore, small spacecraft
outfitted with such significant propulsive capability will be better equipped
to manage late-stage changes to the primary mission’s launch trajectory. Such
changes are frequently a top risk for small spacecraft science missions with
limited onboard propulsive capability that depend on the initial launch
trajectory to reach their science target.
Commercial Applications
The megaconstellations of small
spacecraft now forming in low-Earth orbits have made low-power Hall-effect
thrusters the most abundant electric propulsion system used in space today. These systems use
propellant very efficiently, which allows for orbit insertion, de-orbiting, and
many years of collision avoidance and re-phasing. However, the cost-conscious
design of these commercial electric propulsion systems has inevitably limited
their lifetime capability to typically less than a few thousand hours of
operation and these systems can only process about 10% or less of a small
spacecraft’s initial mass in propellant.
By contrast, planetary science
missions benefiting from the NASA-H71M electric propulsion system technology
could operate for 15,000 hours and process over 30% of the small spacecraft’s
initial mass in propellant. This game-changing capability is well beyond the
needs of most commercial LEO missions and comes at a cost premium that makes
commercialization for such applications unlikely. Therefore, NASA sought and
continues to seek partnerships with companies developing innovative commercial
small spacecraft mission concepts with unusually large propellant throughput
requirements.
One partner that will soon use the
licensed NASA electric propulsion technology in a commercial small spacecraft
application is SpaceLogistics, a wholly owned subsidiary of Northrop Grumman.
The Mission Extension Pod (MEP) satellite servicing vehicle is equipped with a
pair of Northrop Grumman NGHT-1X Hall-effect thrusters, whose design is based
on the NASA-H71M. The small spacecraft’s large propulsive capability will allow
it to reach geosynchronous Earth orbit (GEO) where it will be mounted on a far
larger satellite. Once installed, the MEP will serve as a “propulsion jet
pack” to extend the life of its host spacecraft for at least six years.
Northrop Grumman is currently
conducting a long duration wear test (LDWT) of the NGHT-1X in GRC’s Vacuum
Facility 11 to demonstrate its full lifetime operational capability. The LDWT
is funded by Northrop Grumman through a fully reimbursable Space Act Agreement.
The first MEP spacecraft are expected to launch in 2025, where they will extend
the life of three GEO communication satellites.
Collaborating with U.S. industry to
find small spacecraft applications with propulsive requirements similar to
future NASA planetary science missions not only supports U.S. industry in
remaining a global leader in commercial space systems but creates new
commercial opportunities for NASA to acquire these important technologies as
planetary missions require them.
Northrop Grumman NGHT-1X engineering model Hall-effect thruster operating in Glenn Research Center Vacuum Facility 8. The design of the NGHT-1X is based on the NASA-H71M Hall-effect thruster. Credit: Northrop Grumman
NASA continues to mature the H71M
electric propulsion technologies to expand the range of data and documentation
available to U.S. industry for the purpose of developing similarly advanced and
highly capable low-power electric propulsion devices.
Project Lead
Dr. Gabriel F. Benavides, NASA Glenn Research Center (GRC)
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