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Aerospace Team Online
ATO#133 MAY 18, 2001
Part 1: Upcoming Chats
Part 2: New Contest
Part 3: The 2003 Mars Plane Mission
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UPCOMING CHATS
More information on the Design A Mars Airplane Event
is at
http://quest.nasa.gov/aero/events/marsplane/
Planetary Flight forum - Designs for a Mars Airplane
May 18 - 23, 2001
Ask Peter Gage and Steve Smith questions about the
design of a Mars Airplane.
Read their bio's at http://quest.nasa.gov/aero/team/smith.html
http://quest.nasa.gov/aero/team/gage.html
- - - - - - -
Planetary Flight Webcast - Designs for a Mars Airplane
May 22, 2001 10 AM
Join Andrew Hahn to discuss Mars Airplane Designs.
Read his bio at http://quest.nasa.gov/aero/team/hahn.html
Try designing your Mars airplane at http://quest.nasa.gov/aero/planetary/
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NEW
CONTEST ANNOUNCED
Planetary Flight Newspaper Contest:
May 19 - June 8, 2001
Contest Description: This contest invites students
to create a front page of a newspaper using facts that they have learned
from the Planetary Flight Web Site.
For more information visit: http://quest.nasa.gov/aero/planetary/contest.html
____________________________________________________
[Editor's Note: Andy Hahn is a conceptual airplane designer. He did lots
of design analysis on the 2003 Mars Airplane Designs. Read his bio at
http://quest.nasa.gov/aero/team/hahn.html
]
THE 2003 MARS PLANE MISSION
by Andrew Hahn
November 7, 2000
Most people don't know that NASA is actually made up of
several centers, with varying amounts of overlap in terms of responsibility
and capability. When our Administrator, Daniel Goldin, decided that it
would be neat to send a powered airplane to Mars to commemorate the 100th
anniversary of the Wright brothers' first flight, he asked groups at Langley,
Dryden, Glenn, and Ames for proposals. This journal covers the early efforts
of the Ames proposal. Initially, Dave Kinney and I were tapped to do a
feasibility study for Ames. We were told to start at 4:00 p.m. on Friday,
5 February 1999 and needed "something" to support our management in a
meeting at Headquarters the following Thursday. It was a long weekend.
Dave and I had done many conceptual designs before, but nothing like this.
The deadline was very short, the task wasn't well defined, and the vehicle
operated under conditions that were foreign to us. In short, we weren't
quite sure where to begin. On top of that, all of our design tools pretty
much assumed that airplanes flew on earth. Mars has a different gravitational
constant (g), a very different atmosphere, and no oceans. Really fundamental
questions like how much does it weigh, how much lift or drag does it have
and how high up is it couldn't be answered with our existing design codes.
We had to start from scratch, questioning everything we thought we knew
and we had to do it fast.
Right away, we decided to use the metric system for everything.
Normally, we use the English measure system because a great deal of our
basic design data are in English units and over the years, we have gotten
a feel for the scale of answers we get, which alerts us to really big
errors. Unfortunately, this project is particularly sensitive to keeping
mass and force distinct, which English units are less conducive to doing,
and the scale of the plane meant that our wealth of experience was not
going to be applicable. So, there was a potentially bad outcome if we
stayed with English units and no really good reason to stick with them.
As we found out later, mixing units was definitely bad, causing a probe
to crash, but also one of the other groups had sporadic errors that happened
to be off by the ratio of the Earth's and Mars' gravitational constants,
an indication that mass and force were being confused.
We also decided to prototype a new design code for Extraterrestrial
Flyers in a spreadsheet because we didn't have any time to do really sophisticated
analysis, the task didn't require really sophisticated analysis, we didn't
think we could find all the "g's" in our really sophisticated analysis,
and this problem was so uncharted that we needed the flexibility in calculation
flow that spreadsheets are really good at.
We did get some guidance from the space folks that the maximum
mass (not weight) allowable for the Mars Plane was about 24 kg. and that
it had to fit into a reentry shell of about one meter diameter. They also
told us that the gravity was about 3/8 that of Earth's and that the atmosphere
where we wanted to fly was similar to the Earth's at 100,000 feet altitude.
We then had to make a number of assumption about speed,
airfoils, materials, propulsion, and range to see how easily an airplane
could be made that met even the most basic requirements. What we found
out was that the most important design constraints were the mass and volume
available on the space vehicle that carries the plane to Mars. Early results
indicated that we wanted the biggest plane that we could fit into the
reentry vehicle, which in turn wanted to be the biggest we could fit onto
the launch vehicle, the Ariane 5. Our initial concept looked very much
like a radio control model airplane that folded up into a compact reentry
shell and while it looked feasible, we wanted more. This prompted our
looking at some very strange ideas for fitting a flight vehicle into a
reentry vehicle. We did a qualitative look at a folding wing with only
two hinges, a folding wing with eight hinges, a cable braced roll up wing,
a flexible membrane sailwing (kind of like a bat wing) and a parafoil
(like a square parachute). In the end, we wound up choosing the folding
wing with the fewest hinges for a lot of practical reasons.
Given our assumptions, it appeared that the most attractive
mission from the standpoint of performance feasibility was the relatively
low altitude Canyon Flyer. It turned out that the Mars scientists liked
the same mission because they were very interested in getting a look at
the walls of the huge Valles Marineris over as long of a stretch as they
could. As an added bonus, the primary scientific instrument, a video camera,
would provide really cool pictures for the public as well as document
the really risky deployment from the reentry shell. It was beginning to
look like things were coming together.
In just five days, Dave and I had concluded that the Mars
Plane mission was difficult, but doable. We had given our management enough
information for them to make important, early decisions, and started a
relationship with the space side of NASA. Over the next nine months, many
more people were called in to flesh out the design and make an integrated
proposal. Specialists in aerodynamics, communications, power systems,
structures, missions, science, fabrication, and contracting turned our
simple study into something quite impressive.
We found that our initial assessment was a little optimistic,
but that as we found problems, our people were able to minimize the impact
through clever, detailed solutions. Even so, there were several critical
areas of uncertainty that could only be managed through very sophisticated
analysis and testing. Cost and schedule would have been very tight and,
in the end, might have required either pulling resources from other projects
to "do it right" or taking on too large of a risk of failure and so the
project was killed.
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