From IEEE Spectrum:
Until recently, a defining characteristic of robots has been their rigid mechanical nature. Most of them are made up of hard structural elements, motors and actuators, electronics, sensors, and batteries, none of which are compliant. The future, though, promises to be softer, and we’ve seen lots of different robots that are either partially or completely soft. Soft robots have the potential to be much more adaptable, portable, and durable than rigid robots do, so ideally you’d want them for field applications where there might be a lot of crashing involved. Like UAVs. That would be a good idea, wouldn’t it?
Landing is hard for UAVs. It’s hard for the winged variety especially, since they can’t zero out their horizontal velocity before they hit the ground. Small UAVs can be made out of foam, with mostly integrated components, but they’ve still got fragile external bits that are vulnerable to damage. Namely, the elevons that the wings use for pitch and roll control. The Laboratory of Intelligent Systems at EPFL has developed a UAV that uses dielectric elastomer actuators (DEAs) as elevons: it can fly perfectly well, but the actuators are so compliant that you can literally bend them in half:
Here’s what the researchers have to say about the approach:
We have flown the MAV numerous times and found the DEA actuators allow for excellent controllability of the aircraft, as well as being very resistant to harsh handling.
In case you missed the brief “let’s bend this actuator completely in half” clip in the video, here’s a picture of the entire actuator being bent completely in half:
One advantage of this actuator is the near imperviousness it confers to theaircraft thanks to its inherent softness and stretchability. Or at least, to the elevons. What’s potentially more exciting (I think) is the potential to make an aircraft that can be folded up and stuffed into a bag, or even into a pocket, and then pulled out and tossed into the air whenever you need it.
DEAs aren’t a new thing, even if this particular implementation is a novel one. EPFL has also adapted them for other robotic applications, like this adorable little gripper:
“A Foldable Antagonistic Actuator,” by Jun Shintake, Samuel Rosset, Bryan Schubert, Dario Floreano, and Herbert Shea from EPFL, will be published in a forthcoming issue of IEEE Transactions on Mechatronics.
[ EPFL ]
Comments
Piezoelectric polymer films have been around for a long time, on the one hand if you bend them mechanically you can generate a voltage or if you apply a voltage you can cause them to bend.
The ones I have seen at least are not good for doing very much actual work, require high voltages and would probably work best on ultra micro UAVs.
In that realm you could probably even apply them for flapping wings of a fly or mosquito .sized UAV although I am unsure of the efficiency.
In fact, aside from the relatively high voltages required, I would say that how efficiently you can drive these is the really important question and I didn't see much mention of that here.
Best Regards,
Gary
Elastomeric morphing of a lifting body is a very interesting proposition at this scale.
Folks are removing surfaces altogether FLAVIIR flew back in 2010, you won't be able to fold it up though.
Electroactivepolymers have been around a while. I wonder when they'll show up in aircraft as a way to change the airfoil shape for control and efficiency, like wing warping but more capable.