Researchers have developed artificial muscles for robot motion.

Their solution offers several advantages over previous technologies: it can be used wherever robots need to be soft rather than rigid or where they need more sensitivity when interacting with their environment.

Many roboticists dream of building robots that are not just a combination of metal or other hard materials and motors but also softer and more adaptable. Soft robots could interact with their environment in a completely different way; for example, they could cushion impacts the way human limbs do, or grasp an object delicately.

This would also offer benefits regarding energy consumption: robot motion today usually requires a lot of energy to maintain a position, whereas soft systems could store energy well, too. So, what could be more obvious than to take the human muscle as a model and attempt to recreate it?

Biological inspiration

The functioning of artificial muscles is based on biology. Like their natural counterparts, artificial muscles contract in response to an electrical impulse. However, the artificial muscles consist not of cells and fibers but of a pouch filled with a liquid (usually oil), the shell of which is partially covered in electrodes.

When these electrodes receive an electrical voltage, they draw together and push the liquid into the rest of the pouch, which flexes and is thus capable of lifting a weight. A single pouch is analogous to a short bundle of muscle fibers; several of these can be connected to form a complete propulsion element, which is also referred to as an actuator or simply as an artificial muscle.

The idea of developing artificial muscles is not new, but until now, there has been a major obstacle to realizing it: electrostatic actuators worked only with extremely high voltages of around 6,000 to 10,000 volts. This requirement had several ramifications: for instance, the muscles had to be connected to large, heavy voltage amplifiers; they did not work in water; and they weren’t entirely safe for humans.

Robert Katzschmann, a robotics professor at ETH Zurich, together with Stephan-Daniel Gravert, Elia Varini, and other colleagues have now developed a new solution.

The HALVE of it

Gravert, who works as a scientific assistant in Katzschmann’s lab, has designed a shell for the pouch. The researchers call the new artificial muscles HALVE actuators, where HALVE stands for “hydraulically amplified low-voltage electrostatic”.

“In other actuators, the electrodes are on the outside of the shell. In ours, the shell consists of different layers,” says Gravert.

“We took a high-permittivity ferroelectric material, i.e., one that can store relatively large amounts of electrical energy, and combined it with a layer of electrodes. Next, we coated it with a polymer shell that has excellent mechanical properties and makes the pouch more stable,” Gravert explains.

This meant the researchers could reduce the required voltage, because the much higher permittivity of the ferroelectric material allows large forces despite low voltage. Not only did Gravert and Varini develop the shell for the HALVE actuators together, but they also built the actuators themselves in the lab to use in two robots.

One of these robotic examples is an 11-centimeter-tall gripper (about 4.3 inches tall) with two fingers. Each finger is moved by three series-connected pouches of the HALVE actuator. A small battery-operated power supply provides the robot with 900 volts. Together, the battery and power supply weigh just 15 grams (about 0.5 ounces). The entire gripper, including the power and control electronics, weighs 45 grams (about 1.58 ounces). The gripper can grip a smooth plastic object firmly enough to support its own weight when the object is lifted into the air with a cord.

“This example excellently demonstrates how small, light and efficient the HALVE actuators are. It also means that we’ve taken a huge step closer to our goal of creating integrated muscle-operated systems,” Katzschmann says with satisfaction.

Diving into the future

The second object is a fish-like swimmer, almost 30 centimeters long (about 11.8 inches), that can move smoothly through the water. It consists of a “head” containing the electronics and a flexible “body” to which the HALVE actuators are attached. These actuators move alternately in a rhythm that produces the swimming motion. The autonomous fish can go from a standstill to a speed of three centimeters per second in 14 seconds—and that’s in normal tap water.

This second example is important because it demonstrates another new feature of the HALVE actuators: as the electrodes no longer sit unprotected outside the shell, the artificial muscles are now waterproof and can also be used in conductive liquids.

“The fish illustrates a general advantage of these actuators—the electrodes are protected from the environment and, conversely, the environment is protected from the electrodes. So, you can operate these electrostatic actuators in water or touch them, for example,” Katzschmann explains.

And the layered structure of the pouches has another advantage: the new actuators are much more robust than other artificial muscles.

Ideally, the pouches should be able to achieve a great deal of motion and do it quickly. However, even the smallest production error, such as a speck of dust between the electrodes, can lead to an electrical breakdown—a kind of mini lightning strike.

“When this happened in earlier models, the electrode would burn, creating a hole in the shell. This allowed the liquid to escape and rendered the actuator useless,” Gravert says. This problem is solved in the HALVE actuators because a single hole essentially closes itself due to the protective plastic outer layer. As a result, the pouch usually remains fully functional even after an electrical breakdown.

The two researchers are clearly delighted to have taken the development of artificial muscles a decisive step forward, but they are also realistic.

As Katzschmann says, “Now we have to ready this technology for larger-scale production, and we can’t do that here in the ETH lab. Without giving too much away, I can say that we’re already registering interest from companies that would like to work with us.”

For example, artificial muscles could one day be used in novel robots, prostheses, or wearables; in other words, in technologies that are worn on the human body.

The research appears in Science Advances.

Source: ETH Zurich

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Team prints robotic hand with bones, ligaments, tendons

Researchers have, for the first time, printed a robotic hand with bones, ligaments, and tendons made of different polymers using a new laser scanning technique.

3D printing is advancing rapidly, and the range of materials that can be used has expanded considerably. While the technology was previously limited to fast-curing plastics, it is now suitable for slow-curing plastics as well. These have decisive advantages as they have enhanced elastic properties and are more durable and robust.

The use of such polymers is made possible by a new technology that allows researchers to 3D print complex, more durable robots from a variety of high-quality materials in one go. This new technology also makes it easy to combine soft, elastic, and rigid materials. The researchers can also use it to create delicate structures and parts with cavities.

“We wouldn’t have been able to make this hand with the fast-curing polyacrylates we’ve been using in 3D printing so far,” says Thomas Buchner, a doctoral student in the group of ETH Zurich robotics professor Robert Katzschmann and first author of the study published in Nature.

“We’re now using slow-curing thiolene polymers. These have very good elastic properties and return to their original state much faster after bending than polyacrylates.”

This makes thiolene polymers ideal for producing the elastic ligaments of the robotic hand. In addition, the stiffness of thiolenes can be fine-tuned very well to meet the requirements of soft robots.

“Robots made of soft materials, such as the hand we developed, have advantages over conventional robots made of metal. Because they’re soft, there is less risk of injury when they work with humans, and they are better suited to handling fragile goods,” Katzschmann says.

3D printers typically produce objects layer by layer: nozzles deposit a given material in viscous form at each point; a UV lamp then cures each layer immediately. Previous methods involved a device that scraped off surface irregularities after each curing step. This works only with fast-curing polyacrylates. Slow-curing polymers such as thiolenes and epoxies would gum up the scraper.

To accommodate the use of slow-curing polymers, the researchers developed 3D printing further by adding a 3D laser scanner that immediately checks each printed layer for any surface irregularities.

“A feedback mechanism compensates for these irregularities when printing the next layer by calculating any necessary adjustments to the amount of material to be printed in real time and with pinpoint accuracy,” says coauthor Wojciech Matusik, a professor at Massachusetts Institute of Technology.

This means that instead of smoothing out uneven layers, the new technology simply takes the unevenness into account when printing the next layer.

Inkbit, an MIT spin-off, was responsible for developing the new printing technology. The ETH Zurich researchers developed several robotic applications and helped optimize the printing technology for use with slow-curing polymers.

At ETH Zurich, Katzschmann’s group will use the technology to explore further possibilities and to design even more sophisticated structures and develop additional applications. Inkbit is planning to use the new technology to offer a 3D printing service to its customers and to sell the new printers.

Source: ETH Zurich

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