{"id":561293,"date":"2021-12-28T11:38:51","date_gmt":"2021-12-28T16:38:51","guid":{"rendered":"https:\/\/www.therobotreport.com\/?p=561293"},"modified":"2021-12-28T11:38:51","modified_gmt":"2021-12-28T16:38:51","slug":"soft-actuators-help-mit-power-nano-drones","status":"publish","type":"post","link":"https:\/\/www.therobotreport.com\/soft-actuators-help-mit-power-nano-drones\/","title":{"rendered":"Soft actuators help MIT power nano drones"},"content":{"rendered":"
\"Tiny

These nano drones use soft actuators to fly through the air. | Source: MIT<\/p><\/div>\n

Researchers at MIT have created a tiny robot, weighing less than 1 gram, that can zip around with insect-like agility and resilience. The research team isn\u2019t the first to take on the challenge of making tiny flying robots. After all, they do have a number of real-world applications such as pollinating a field of crops or searching for survivors in disaster areas.<\/p>\n

Typically, these kinds of robots are made with rigid actuators<\/a> built from piezoelectric ceramic materials. The rigid materials help the robot to fly, but they also make it fragile. These types of robots are unlikely to survive the number of collisions it would face in the real world.<\/p>\n

Soft actuators can be much more resilient than rigid ones, but they present a different problem for tiny robots. They require higher voltages than rigid actuators, and more voltage means bigger power electronics that the robot isn\u2019t capable of lifting.<\/p>\n

Kevin Chen, an assistant professor in the department of electrical engineering and computer science, and senior author of the study, worked with his team to create a new fabrication technique for soft<\/a> actuators. The produced actuators operate with 75% lower voltage than current versions and can carry 80% more payload.<\/p>\n

The team\u2019s rectangular robot has four sets of wings, each driven by an actuator, that beat nearly 500 times per second. The actuators work like artificial muscles, and are made up of layers of elastomer placed between two very thin electrodes and rolled into a squishy cylinder.<\/p>\n

The wings flap by applying voltage to the actuator, which makes the electrodes squeeze the elastomer.<\/p>\n

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