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The
Prius of Space
Thursday, September 13, 2007
Some
spacecraft achieve greatness, And some have greatness thrust from
them.
If you drive a car - and
you know who you are - you have invariably come upon the dreaded
dilemma of refueling. When the needle on your gas gauge wavers
over the unseemly 'E,' you have to ask yourself one question - Do
I stop at the next gas station or press on, hoping for a fuel
oasis somewhere down the road? But what if you need to motor
somewhere three billion-plus miles off the beaten path -
somewhere where neither regular nor premium unleaded have so far
feared to tread?
Such is the case for NASA's latest deep
space explorer, Dawn. The 2,600 pound spacecraft's mission is to
reconnoiter the asteroid belt's two biggest occupants - the
massive asteroid Vesta and the even more massive dwarf planet
Ceres. To do so, Dawn will not just scream past its prey snapping
off a flurry of images as it zooms by. No, not this spacecraft.
"Dawn will be history's first mission to go out into
the solar system, orbit and explore a distant body, and then go
on to a totally different celestial body and explore that one,"
said Dawn project manager Keyur Patel of NASA's Jet Propulsion
Laboratory, Pasadena, Calif. "To do all that you need a
spacecraft with a lot under the hood."
What Patel
considers a lot under the hood is definitely not the
exo-atmospheric equivalent of a muscle car's 426 Hemi engine.
After all, it is about a different type of performance up there -
the kind where smooth, reliable operation and gas mileage count
more than the capability to burn rubber. What it takes up there
is a deep-space qualified engine, a whole bunch of juice and the
same kind of gas used in photographic flash bulbs and some car
headlights.
The engine is called NASA Solar Electric
Propulsion Technology Applications Readiness. Most people in the
deep space exploration business just refer to it as "ion
propulsion." The juice is, of course, electricity, courtesy
of 54 feet of electricity-producing solar array. The gas is
xenon, an inert, colorless gas that is four times heavier than
air and is the propellant of choice for asteroid explorers
everywhere.
"Each of our three ion engines weighs in
at 20 pounds and is about the size of a basketball," said
Patel. "From such a little engine you can get this blue beam
of rocket exhaust that shoots out at 89,000 miles per hour. The
fuel efficiency of an ion engine is an order of a magnitude
higher than chemical rockets and can reduce the mass of fuel
onboard a spacecraft up to 90 percent. It is a remarkable
system."
Praise like that does raise an important
question. If ion engines are so hyper-efficient, how come NASA
does not use them for all their rockets and spacecraft?
"For
the same reason a drag racer would not use a fuel efficient Prius
to compete in the quarter mile," said John Brophy, Dawn's
ion propulsion systems manager. "Not enough get up and go."
The kind of get up and go Brophy is talking about is
power - horsepower to hurtle a top fuel dragster down the track,
or the massive amounts of thrust to give a rocket enough get up
and go to go - out there.
"We have a powerful rocket
to cover those initial 175 miles," added Brophy. "Our
Delta II Heavy will give the Dawn spacecraft enough energy to
leave Earth's atmosphere and its gravitational sphere of
influence. But getting into space is just the beginning. There
will still be a lot of motoring ahead."
A lot of
motoring is right. Over the course of its eight year mission,
first to Vesta and then off to Ceres, Dawn's three ion engines
will accumulate 2,000 days of operation - that is 5.5 years of
happy motoring!
Why so much engine time? It is as simple
as a plain piece of paper.
"Hold a piece of notebook
paper in your hand. The weight of that paper pushing against your
hand is the same as the thrust provided by one of Dawn's ion
engines -- at full throttle I might add," said Brophy. "If
you had an ion engine firing here on Earth, it would not be able
to push a skateboard across a sidewalk!"
Lucky for
Dawn there are no sidewalks in space - and as far as we know no
skateboards. What there is up there is plenty of space, so soon
after the spacecraft escapes Earth's gravity, one of its ion
engines can kick in and begin the long, efficient chase of its
first asteroid belt target, Vesta.
At first glance,
Dawn's full throttle, pedal-to-the-metal, performance is a
not-so-inspiring 0-to-60 mph in 4 days. But consider this -
because of its incredible efficiency, it expends only 40 ounces
of xenon propellant during that time. And then take into
consideration that after those four days of full-throttle
thrusting, it will do another four days - and then another four.
By the end of 12 days the spacecraft will have increased its
velocity by over 180 miles per hour, with more days and weeks and
months of continuous thrusting to come. After a year Dawn's ion
propulsion system will have increased the spacecraft's speed by
5,500 mph while consuming the equivalent of only 15 gallons of
fuel. By the end of its mission Dawn will have accumulated more
than 5 years of total thrust time, giving it an effective change
in speed of about 23,000 mph.
"In the end it is
about the science," added Patel. "What we find when
Dawn gets to Vesta and Ceres will re-write the history books on
the beginning of our solar system. But how we get there is almost
as remarkable, 1.8 billion miles to Vesta, months flying around
it performing science adjusting our orbits as we go. Then we
travel another billion miles to Ceres where we do it all over
again. That is a lot to ask of a beam of blue light."
Those space aficionados who want to keep their "ion"
the mission should note the launch period for Dawn's voyage to
Vesta and Ceres opens September 26 from Cape Canaveral Air Force
Station's Pad 17-B.
Source:
NASA / JPL
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