Dec.
13, 2012 — Ever since the Wright brothers, engineers have been working to
develop bigger and better flying machines that maximize lift while minimizing
drag.
There
has always been a need to efficiently carry more people and more cargo. And so
the science and engineering of getting large aircraft off the ground is very
well understood.
But
what about flight at a small scale? Say the scale of a dragonfly, a bird or a
bat?
Hui
Hu, an Iowa State University associate professor of aerospace engineering, said
there hasn't been a need to understand the airflow, the eddies and the spinning
vortices created by flapping wings and so there haven't been many engineering
studies of small-scale flight. But that's changing.
The
U.S. Air Force, for example, is interested in insect-sized nano-air vehicles or
bird-sized micro-air vehicles. The vehicles could fly microphones, cameras,
sensors, transmitters and even tiny weapons right through a terrorist's
doorway.
So
how do you design a little flier that's fast and agile as a house fly?
Hu
says a good place to start is nature itself.
And
so for a few years he's been using wind tunnel tests and imaging technologies
to learn why dragonflies and bats are such effective fliers. How, for example,
do flapping frequency, flight speed and wing angle affect the lift and thrust
of a flapping wing?
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