Increasing Bug-Like Bots: New Synthetic Muscle Tissues Enhancing The Efficiency Of Flying Microrobots

An entirely new fabrication method creates energy-dense, low-voltage synthetic muscle groups to improve the efficiency of flying microrobots.

With regards to robots, a larger value is not always higher. Occasionally, a swarm of insect-sized robots can pollinate an area of ​​crops or search for survivors among the rubble of a collapsed structure.

MIT Researchers have demonstrated tiny drones that can spin around with bug-like agility and resilience, which could eventually carry out these missions. The smooth actuators to propel these microrobots are sturdy, however they require far more voltage than similarly sized inflexible actuators. Light robots cannot carry the necessary power electronics that would allow them to fly on their own.

Now, these researchers have pioneered a fabrication method that allows them to build smooth actuators that operate with 75% less voltage than current variants while under 80 more loads. %. These smooth actuators resemble synthetic muscle groups that rapidly flap the robot’s wings.

This new manufacturing method creates synthetic muscle groups with fewer defects, which will significantly extend the life of the parts and will increase the robot’s efficiency and payload.

“This will sooner or later open up many alternatives for us to switch to placing energy electronics on microrobots. Many people are likely to assume that smooth robots will not be as successful as inflexible ones. We show that this robot, weighing less than a gram, flies for the longest time with minimal error during hovering flight. The take-home message is that smooth robots can exceed the efficiency of inflexible robots,” said Kevin Chen, who is with D. Reid Weedon, Jr.’s assistant professor. ’41 in the Department of Electrical Engineering and Notebook Science, said Mushy, and the Micro Robotics Lab in the Analytical Electronics Laboratory (RLE), and senior author of the paper. newspaper.

Chen’s co-authors include Zhijian Ren and Suhan Kim, co-authors and EECS undergraduate students; Xiang Ji, an analytical scientist at EECS; Weikun Zhu, a chemical engineering graduate; Farnaz Niroui, an assistant professor at EECS; and Jing Kong, a professor in the EECS and principal investigator of the RLE. The analysis has been accepted for publication in Premium Supplies and is included in the jounal’s Rising Stars series, which recognizes outstanding work from novice researchers.

Create muscle groups

The elongated microrobot, which weighs less than a quarter cent, has 4 wing units that can propel every wing with a smooth actuator. These muscle-like actuators are made from layers of elastomer that can be sandwiched between two very thin electrodes, then rolled right up into a small cylinder. When voltage is applied to the actuator, the electrodes squeeze the elastomer and that mechanical pressure is used to flap the wings.

The larger the cascade space that the actuator has, the much less voltage required. So Chen and his team build these synthetic muscle groups by alternating between as many ultrathin layers of elastomer and electrode as they like. As the elastic layers get thinner, they become less stable.

For the first time, the researchers tried to create an actuator with 20 layers, each 10 micrometers thick (related to the diameter of a purple blood cell). However, they need to reinvent the components of the manufacturing process to get there.

A major barrier has come here from the rotary coating process. During the spin coating, an elastomer is poured onto the flat floor and rotates rapidly, while centrifugal force pulls the film out to make it thinner.

“During this process, air re-enters the elastomer and creates many microscopic air bubbles. The diameter of those air bubbles is only 1 micrometer, so before that we simply ignored them. However, once you get thinner and thinner layers, the effects of the air bubbles will become stronger and stronger. That is the historical reason why people are not qualified to make these very thin layers,” explains Chen.

He and his colleagues discovered that in the case that they performed the vacuum process immediately after spinning the coating, while the elastomer was still moist, it removed air bubbles. Then they bake the elastomer to dry.

Eliminating these defects will increase the actuator’s base output by more than 300% and dramatically improve its lifespan, Chen said.

The researchers have also optimized thin electrodes, which are made up of carbon nanotubes, ultra-strong carbon coils that can be about 1/500th the diameter of a human hair. A higher concentration of carbon nanotubes improves the actuator output power and cuts back voltage, however the dense layers also include additional defects.

For example, carbon nanotubes have sharp tips and can pierce elastomers, which causes the machine to short, Chen explained. After a lot of trial and error, the researchers discovered the optimal focal point.

Another downside comes from the curing phase – as extra layers are added, the actuator takes longer and longer to dry.

“The first time I asked my student to make a multi-layer actuator, as soon as he bought 12 layers, he needed to wait two days for processing. That’s completely unsustainable, especially if you want to scale as much as additional layers,” says Chen.

They found that baking each layer for a few minutes immediately after the carbon nanotubes were transferred to the elastomer reduced the curing time as additional layers were added.

Best performance in class

After using this method to create a 20-layer synthetic muscle, they tested it against the previous six-layer model and modern, inflexible actuators.

During the take-off tests, the 20-layer actuator, which requires less than 500 volts to operate, used enough power to give the robot a lift-to-weight ratio of 3.7 to 1, since so it can carry gadgets that can be almost three times its weight.

In addition, they demonstrated a 20-second hovering flight, which Chen says is the longest flight ever recorded by a robot smaller than the gram. Their hovering robot keeps its position extremely stable than any other robot. However, the 20-layer actuator still operates easily after being pushed for more than 2 million cycles, far exceeding the lifespan of various actuators.

“Two years ago, we basically built the most powerful actuator, and it can be difficult to fly. We begin to wonder, can smooth robots compete with inflexible robots? We noticed one defect after another, so we kept working and we worked through one manufacturing defect after another, and now the actuator efficiency is smooth. are catching up. They are even slightly taller than modern inflexible ones. And anyway there are countless fabrication processes in materials science that we are not aware of. So I’m excited to go back to trigger voltage regulation,” he said.

Chen appeared first to collaborate with Niroui to build actuators in a well-ventilated room at MIT.nano and take advantage of nanofabrication methods. Now, his team is limited in how thin they will be creating the layers because of the mud in the air and the rotational speed of the mantle being greatest. Working in a clear room eliminates this drawback and allows them to use strategies that, like a doctor’s polish, can be more precise than with rotary coatings.

While Chen is excited about producing 10-micrometer layers of actuators, his hope is to reduce the thickness to just one micrometer, which could open up a variety of functions for robots this size. like this insect.

Reference: “Over-lifting for airborne micro-robots powered by low-voltage elastomeric and long-lasting voltage actuators” by Zhijian Ren, Suhan Kim, Xiang Ji, Weikun Zhu, Farnaz Niroui, Jing Kong and Yufeng Chen, November 28, 2021, Premium Supplies.
DOI: 10.1002 / adma.202106757

This work was supported in part by the MIT Electron Analytical Laboratory and the Mathworks Graduate Fellowship.