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Topic Name: Satellites to take off with less fuel : Developed By Georgia Tech researchers
Category: Aeronautical
Research persons: Mitchell Walker
Assistant Professor, Ph.D.
University of Michigan, 2004
Email: mitchell.walker@ae.gatech.edu Address: 449 Guggenheim
Phone: (404) 385-2
Location: School of Aerospace Engineering
Georgia Institute of Technology270 Ferst Drive
Atlanta, GA 30332, United States
Details
Georgia Tech researchers have developed a new protoype engine that allows
satellites to take off with less fuel, opening the door for deep space missions,
lower launch costs and more payload in orbit.
The efficient satellite engine uses up to 40 percent less fuel by running on
solar power while in space and by fine-tuning exhaust velocity. Satellites using
the Georgia Tech engine to blast off can carry more payload thanks to the mass
freed up by the smaller amount of fuel needed for the trip into orbit. Or, if
engineers wanted to use the reduced fuel load another way, the satellite could
be launched more cheaply by using a smaller launch vehicle.
The fuel-efficiency improvements could also give satellites expanded
capabilities, such as more maneuverability once in orbit or the ability to serve
as a refueling or towing vehicle.
The Georgia Tech project, lead by Dr. Mitchell Walker, an assistant professor in
the Daniel Guggenheim School of Aerospace Engineering, was funded by a grant
from the U.S. Air Force. The project team made significant experimental
modifications to one of five donated satellite engines from aircraft engine
manufacturer Pratt & Whitney to create the final prototype.
The key to the engine improvements, said Walker, is the ability to optimize the
use of available power, very similar to the transmission in a car. A traditional
chemical rocket engine (attached to a satellite ready for launch) runs at
maximum exhaust velocity until it reaches orbit, i.e. first gear.
The new Georgia Tech engine allows ground control units to adjust the
engine’s operating gear based on the immediate propulsive need of the satellite.
The engine operates in first gear to maximize acceleration during orbit
transfers and then shifts to fifth gear once in the desired orbit. This allows
the engine to burn at full capacity only during key moments and conserve fuel.
“You can really tailor the exhaust velocity to what you need from the ground,”
Walker said.
The Georgia Tech engine operates with an efficient ion propulsion system. Xenon
(a noble gas) atoms are injected into the discharge chamber. The atoms are
ionized, (electrons are stripped from their outer shell), which forms xenon
ions. The light electrons are constrained by the magnetic field while the heavy
ions are accelerated out into space by an electric field, propelling the
satellite to high speeds.
Tech’s significant improvement to existing xenon propulsion systems is a new
electric and magnetic field design that helps better control the exhaust
particles, Walker said. Ground control units can then exercise this control
remotely to conserve fuel.
The satellite engine is almost ready for military applications, but may be
several years away from commercial use, Walker added.
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