Robots utilise insect traits

Miniature insect-like robots that incorporate a solid-state muscle design for microid legs could improve the dexterity of future microscale robotic systems.

According to its developers, the concept is the first to show realistic insect-like characteristics at this scale and could pave the way for smaller and more robust designs.

Currently, microscale robots are largely formed from complex moving parts that are subject to wear from friction and jamming as a result of dust particles.

‘The complex moving parts ultimately limit their lifetime and confine their use to a controlled laboratory environment,’ said Jason Clark, an assistant professor of electrical, computer and mechanical engineering at Purdue University.

Clark has developed a concept using a solid-state muscle for microid legs and mandibles that allows the robots to move over environments such as sand or water.

This is done using a ‘tripod gait’ for walking – a technique used by most insects that enables them to remain stable over uneven terrain.

‘Because the microids are solid state without any discrete parts such as gears that wear due to frictional contact, they are likely to be long lasting and robust. If a microid were stepped on, it would probably just get up and walk away,’ said Clark.

Each leg comprises a bundled triad of slender beams made of piezoelectric material, which generates electricity when compressed. This could allow them to have the ability to ‘scavenge vibrational energy’ from the environment to recharge their power supply. There is also the possibility of hordes of microids working in unison and communicating with each other to perform a complex task.

Microids
This concept depicts a new approach in the design of miniature, insectlike microids the size of ants that would move their tiny legs and mandibles using solid-state “muscles.” Advanced computer simulations indicate the synthetic bugs would have significantly better dexterity than previous microscale robots, while having the ability to “scavenge vibrational energy” from the environment to recharge their power supply. (Purdue University image/Jason Clark)

Clark said: ‘The microids would be able to walk, run and jump, plus pick up and move objects many times their own weight. A microid can also do what no insect or other microrobot can do, which is continue walking if flipped on its back. Who knows, maybe flight is next.’

‘You can’t underestimate the power of having thousands of microids working together, much like ant colonies,’ he added.

Currently, the researchers are working on fabricating a simplified proof of concept of a microid at the Birck Nanotechnology Center in the university’s Discovery Park. Purdue has also filed a patent application on the concept and hopes that in the future the system can be mass produced.