WINGING IT
Aircraft engineers take inspiration from owls
Birds have been a huge inspiration for many technologies in the aviation industry, but human aircraft cannot yet match their ability to fly straight and steady through storms. However, a team of scientists from the University of Bristol and the Royal
Veterinary College have uncovered bird so secret to combatting wind speeds as fast as their own flight.
"We've been flying for over 100 years, ever since the Wright brothers [who built and flew the first powered plane?.
They knew that getting enough lift to fly was a challenge, but that was easier when compared with stabilising and controlling the flight," said Prof Richard Bomphrey, one of the study’s authors from the Royal Veterinary College.
“They had a method for controlling the Wright Flyer that worked reasonably well – a series of cables which twisted the wing. But ever since then, we’ve built a rigid winged aircraft, mainly because the maths is a bit easier. It’s easier to create wings which are stiff, and then they behave in a more predictable manner.”
This worms for certain flying conditions, where a rigid wing shape is optimal. But to improve flight performance in strong winds, a different, bio-inspired design for the wings of an aircraft would be better, said Bomphrey.
To find out how birds cope with wind, the team observed the flight of a goshawk, a tawny eagle, a tawny owl and a barn owl. The latter, who was named Lily, is the star of the team’s publication in Proceedings Of The Royal Society B.
“We built a gust generator so we could set the speed and direction of the wind, and then encouraged Lily to glide just where we wanted her to go,” said Bomphrey. “We had high-speed cameras and some motion capture cameras set on her, with which we could do a process called stereo photo gram me try–away of getting three-dimensional shapes from a pair of cameras.”
Watching Lily through these cameras, the team discovered that during flight her wings acted as a suspension system, stabilising the trajectory of the head and the torso in strong winds.
"[The wing] does this in a rather elegant way, which should be quite familiar to people who play any batand-ball games or racquet sports. That’s the concept of the sweet spot,” said Bomphrey. “So if you are playing cricket and as the heavy ball comes down you hit it with the very end of the bat, the handle will jump out of your hands forward. Whereas if you hit the ball right up close to the handle, then the handle gets shoved backwards. That tells you that there’s a point between those two areas where you might hit the ball and the handle doesn’t get jarred forwards or backwards. If you’re lucky enough to hit a ball as well as that, then it feels effortless.”
Bomphrey says the bird’s wing can be thought of as the bat, and the gust of wind as the ball. In changing weather conditions, the bird pivots her wings around the shoulder, so the gust hits in that sweet spot, all the forces and torques cancel at the hinge of the shoulder joint. The wing moves, but the body doesn’t.
The team say this knowledge could inspire new designs for the aviation industry, initially starting with small scale and non-manned aircraft but eventually influencing passenger planes.
"[The technology] is totally ready to go, because it’s a phenomenon that we’ve observed in birds. The key part is that you must have the hinge, and you must have the right alignment. That can be done just by moving where the [mass is]," said Bomphrey.
"We've actually done a bit of prototyping ourselves already with some toy gliders, demonstrating the same principle that we’ve seen in birds, rejecting about 40 per cent of exactly the same gust, in the lab, with no onboard computer whatsoever.”