Photo: Dr Tim HelpsA new drive system for ‘flapping wing autonomous robots’ has been developed by a
University of Bristol team, using a new method of ‘electromechanical zipping’ that does away with the need for conventional motors and gears and could pave the way for smaller, lighter and more effective micro flying robots for environmental monitoring, search and rescue, and deployment in hazardous environments. Details of this development were recently published in the journal
Science Robotics.
Until now, typical micro flying robots have used motors, gears and other complex transmission systems to achieve the up-and-down motion of the wings — adding complexity, weight and ‘undesired dynamic effects’.
However, taking inspiration from bees and other flying insects, researchers from Bristol’s Faculty of Engineering — led by Professor of Robotics Jonathan Rossiter — have successfully demonstrated a direct-drive artificial muscle system, called the ‘Liquid-amplified Zipping Actuator’ (LAZA), that achieves wing motion using no rotating parts or gears, greatly simplifying the flapping mechanism and enabling the ‘future miniaturisation of flapping robots down to the size of insects’.
In the paper, the team show how a pair of LAZA-powered flapping wings can provide more power compared with insect muscle of the same weight, enough to fly a robot across a room at 18 body lengths per sec. They also demonstrated how the LAZA can deliver consistent flapping over more than one million cycles, important for making flapping robots that can undertake long-haul flights. Moreover, the team expect LAZA to be adopted as a fundamental building block for a range of autonomous insect-like flying robots.
Tim Helps, lead author and developer of the LAZA system, said “With the LAZA, we apply electrostatic forces directly on the wing, rather than through a complex, inefficient transmission system. This leads to better performance, simpler design, and will unlock a new class of low-cost, lightweight flapping micro-air vehicles for future applications, like autonomous inspection of offshore wind turbines.”
Professor Rossiter added: “Making smaller and better performing flapping wing micro robots is a huge challenge. LAZA is an important step toward autonomous flying robots that could be as small as insects and perform environmentally critical tasks such as plant pollination and exciting emerging roles such as finding people in collapsed buildings.”