Fortunately, researchers at MIT’s Computer Science and Artificial Intelligence Laboratory (CSAIL) have devised a new method for 3D printing soft materials that makes robots safer and more precise in their movements — and that could be used to improve the durability of drones, phones, shoes, helmets and more.
The team’s “programmable viscoelastic material” (PVM) technique allows users to program every single part of a 3D-printed object to the exact levels of stiffness and elasticity they want, depending on the task they need for it.
For example, after 3-D printing a cube robot that moves by bouncing, the researchers outfitted it with shock-absorbing “skins” that use only 1/250 the amount of energy it transfers to the ground.
“That reduction makes all the difference for preventing a rotor from breaking off of a drone or a sensor from cracking when it hits the floor,” said CSAIL Director Daniela Rus, who oversaw the project and co-wrote a related paper. “These materials allow us to 3-D print robots with visco-elastic properties that can be inputted by the user at print-time as part of the fabrication process.”
The skins also allow the robot to land nearly four times more precisely, suggesting that similar shock absorbers could be used to help extend the lifespan of delivery drones like the ones being developed by Amazon and Google.
3D-Printed Dampers
There are many reasons for dampers, from controlling the notes of a piano, to keeping car tires on the ground, to protecting structures like radio towers from storms.
The most common damper materials are “viscoelastics” like rubber and plastic that have both solid and liquid qualities. Viscoelastics are cheap, compact, and easy to find, but are generally only commercially available in specific sizes and at specific damping levels because of how time-consuming it is to customize them.
The solution, the team realized, was 3-D printing. By being able to deposit materials with different mechanical properties into a design, 3-D printing allows users to “program” material to their exact needs for every single part of an object.
Using a standard 3-D printer, the team used a solid, a liquid and a flexible rubber-like material called TangoBlack+ to print both the cube and its skins. The PVM process is related to Rus’ previous 3-D printed robotics work, with an inkjet depositing droplets of different material layer-by-layer and then using UV light to solidify the non-liquids.
The cube robot includes a rigid body, two motors, a microcontroller, battery, and inertial measurement unit sensors. Four layers of looped metal strip serve as the springs that propel the cube.
“By combining multiple materials to achieve properties that are outside the range of the base material, this work pushes the envelope of what’s possible to print,” said Hod Lipson, a professor of engineering at Columbia University and co-author of Fabricated: The New World of 3-D Printing. “On top of that, being able to do this in a single print-job raises the bar for additive manufacturing.”
Rus says that PVMs could have many other protective uses, including shock-absorbing running shoes and headgear. By damping the motion brought about by robots’ motors, for example, PVMs are not only able to protect sensitive parts like cameras and sensors, but can also actually make the robots easier to control.
“Being able to program different regions of an object has important implications for things like helmets,” said co-lead author Robert MacCurdy. “You could have certain parts made of materials that are comfortable for your head to rest on, and other shock-absorbing materials for the sections that are most likely to be impacted in a collision.”
For more 3D printing and robotics news, meet the 3D-printed autonomous Octobot.