杏吧原创

Flying ‘paddleboat’ may finally take off

Could a bizarre-looking aircraft design dating from the late 19th century be the ideal way for small, agile flying robots to get around?

Video: A bizarre aircraft design dating from the late 19th century could provide the perfect lift for small, agile flying robots (Video courtesy of Hu Yu/Singapore National University)

A small robotic aircraft powered by rotating 鈥減addle-wheel鈥 wings could yet rule the skies, if renewed interest in an antique design bears fruit.

Several international research groups are working on prototype 鈥渃yclogyros鈥, a design first proposed more than 100 years ago.

A flies using 鈥渃ycloidal propellers鈥 鈥 several wings positioned around the edge of a rotating cylindrical framework, a bit like a paddle-wheel. As each wing rotates, its blades move through the air generating lift and thrust.

And, since each wing rotates through a full circle, altering the angle of the individual blades can pull the aircraft forwards, backwards and down as well up. The manoeuvrability that cycloidal propellers could offer provides benefits over more established flying methods.

Although no cyclogyro has yet flown without being tethered, its proponents say the design could prove more efficient and manoeuvrable than helicopters at small scales. A team of Singapore researchers is leading the race to construct a working cyclogyro with a prototype that hovers on the end of a line.

Quieter ride

at the National University of Singapore have built a small cyclogyro that hovers and turns on the end of a tether, which delivers power to its electric motors (see video, top right).

The researchers heard about the cyclogyro鈥檚 design while working on miniature aircraft with flapping wings. They performed simulations confirming that cycloidal propellers can be more efficient than those used on aeroplanes and helicopters. 鈥淭hey will also be potentially much quieter than screw rotors,鈥 they add.

After studying the performance of different cycloidal designs, the pair modified a toy helicopter, giving it two cycloidal propellers with three blades each, and a small tail rotor for stability.

鈥淥n the tether, the aircraft can spin, move directly up and down or fly forward and backward,鈥 says Hu. 鈥淭his is perhaps the first recorded flight for a cyclogyro,鈥 he adds. 鈥淭here were some people claiming successful flights, but no video or proof for that.鈥

Unstable aerobatics

For now, the aircraft still lacks stability. Its tether is needed to restrain it from spinning on the spot or performing loops in the air. But the team hopes to add a tail rotor to make it more stable, and to build the power supply into the craft.

鈥淚鈥檓 full of admiration that they got it to fly,鈥 says , an aerospace engineer interested in cyclogyros at the Technion Israel Institute of Technology (TIIT), Haifa, 鈥渂ut it does still rely on the tether.鈥 Using four cycloidal propellers instead of two might remove the need for a tail rotor, he suggests.

Weihs and colleagues Gil Iosilevskii and Yuval Levy have also been working on simulated and real-life cyclogyro experiments. 鈥淲e built models and proved that it can work, but tried to go directly from that to a self-contained flyer carrying its own power,鈥 Weihs told New 杏吧原创. 鈥淲e tried to leapfrog the tethered stage.鈥

Reaching for the skies

Other research groups hoping to resurrect the exotic design include one at . The team there has built a craft that can lift off by a few centimetres attached to several short tethers.

, have their own designs. (mpg format) shows one of their cycloidal propellers with five pairs of stacked wings lifting its own weight. shows four propellers working together (wmv format).

After a break from cyclogyro development, Weihs now plans further experiments, saying the recent resurgence in interest in the design is encouraging. 鈥淚t has shown us there are different ways to make them work, and we can try and bring that together,鈥 he says.

Weihs discovered that a cyclogyro was first patented by a German inventor in 1893. The idea was most thoroughly investigated in the early 20th century, with popular magazines suggesting were on the horizon. Unfortunately prototypes struggled. 鈥淭hey broke themselves apart,鈥 says Weihs.

Part of the problem was size. The biggest challenge for cyclogyro builders is making strong but light structures able to handle the strong forces generated inside a cycloidal propeller when it spins, says Weihs. At larger sizes that becomes more difficult.

Small is beautiful

鈥淐yclogyros are more relevant now because people want to build small, agile UAVs [uncrewed aerial vehicles],鈥 says Weihs. At such sizes they have greater advantages over helicopters, he says.

The parts of a helicopter blade nearest and furthest from the hub are moving too slowly and too fast, respectively, to generate thrust. 鈥淲ith a cyclogyro every bit moves at the same speed, so there is no 鈥榙ead space鈥,鈥 says Weihs.

Cyclogyros can also be more manoeuvrable, says Weihs. Helicopters must tilt to travel laterally. But cycloidal propellers can generate thrust in any direction so the craft can remain level, or adopt any other position and still fly in any direction.

These advantages are greatest at small sizes. 鈥淭hey are probably not practical above half a metre across,鈥 says Weihs. 鈥淵ou won鈥檛 see one carry a passenger.鈥