鈥淏ING, BONG. This is your captain speaking. We are now coming into land.
Would passengers please put on their oxygen masks and start blowing鈥攁s we
need to inflate the wings.鈥
Implausible, yes鈥攂ut not as impossible as it seems. NASA scientists are
indeed testing inflatable wings. The idea is to give hypersonic aircraft
increased lift on landing, or let large mother ships drop scores of
ultra-lightweight drones whose wings will inflate as they are jettisoned.
Next week, NASA is due to start testing a scaled-down version of the X-24a, a
stumpy 鈥渓ifting-body鈥 aircraft. To reduce drag, the X-24a has no wings. Instead,
its aerofoil shape generates lift
(see it at http://users.dbscorp.net/jmustain/x24a.htm). But NASA wants to give vehicles like this one additional
lift when they need it. 鈥淵ou wouldn鈥檛 inflate the wings until right before
touchdown,鈥 explains Jeff Bauer, a project manager at NASA鈥檚 Dryden Flight
Research Center in California. His colleague, engineer Joe Pahle, says
lifting-body designs have always involved a difficult trade-off between drag
reduction for fast flight and giving the planes enough lift for them to land
safely.
Advertisement
NASA reckons the ideal solution is for the aircraft to 鈥済row鈥 a pair of wings
when it needs them the most. 鈥淭here are multiple applications for the technology
if it can be matured,鈥 says Bauer. Besides reusable launch vehicles they could
also be incorporated into the design of the International Space Station鈥檚
鈥渓ifeboat鈥濃攐therwise known as the X-38 crew return vehicle.
Uninhabited aerial vehicles (UAVs) that earth scientists use for remote
sensing could also have inflatable wings. Bauer envisages long-endurance planes
with large wingspans鈥攕uch as the solar/fuel-cell powered Helios craft
(快猫短视频, 22 July 2000, p 30)鈥攃arrying many smaller
vehicles under their wings. The carrier vehicle would conduct large area
surveillance, he says. 鈥淏ut it could release one of these small aircraft to do
more precise localised monitoring.鈥
A carrier could stash away a lot more UAVs like this because their inflatable
wings would take up less room than fixed-wing planes. Once released, the
aircraft would inflate their wings and go about their business, controlled
entirely by elevators and rudders in their tail.
Before being inflated, the wings will probably be stored folded, concertina
fashion, within the fuselage. For the test flights, however, they are simply
strapped to the side of the craft. 鈥淥ur research is not currently looking at how
best to stow the wings, but what happens once they are released,鈥 explains
Pahle.
A single canister of nitrogen gas at a pressure of nearly 3.5 megapascals
(about 35 atmospheres) will inflate the wings. Once inflated, the wings are kept
at a pressure of about 1.3 megapascals by a regulator the team borrowed from a
paintball gun. Bauer says it鈥檚 vital to get the pressure right during inflation.
鈥淵ou don鈥檛 want to put in too much in case you cause a blowout,鈥 he says.
Similarly you don鈥檛 want it to go too slowly in case it folds. In all,
deployment take less than a third of a second and doesn鈥檛 seem to disrupt the
aerodynamics of the vehicle.
Bauer is also interested in using inflatable wings for vehicles being sent to
other planets. 鈥淏eing able to efficiently package that aircraft would have an
obvious advantage in terms of limiting the payload,鈥 he explains. Last week,
NASA said it would fund a six-month University of Nevada study that will look
into sending three gliders to Mars in 2007.

- For a Quicktime movie of the inflatable wings in action see:
www.dfrc.nasa.gov/PAO/X-Press/movies/I-2000.mov