Soft robots controlled by magnets, light in new research

Researchers from North Carolina State University and Elon University have developed a technique that allows them to remotely control the movement of soft robots, lock them into position for as long as needed, and later reconfigure the robots into new shapes. The technique relies on light and magnetic fields.

“We’re particularly excited about the reconfigurability,” said Joe Tracy, a professor of materials science and engineering at NC State and corresponding author of a paper on the work. “By engineering the properties of the material, we can control the soft robot’s movement remotely; we can get it to hold a given shape; we can then return the robot to its original shape or further modify its movement; and we can do this repeatedly. All of those things are valuable, in terms of this technology’s utility in biomedical or aerospace applications.”

LEDs make soft robots pliable

For this work, the researchers used soft robots made of a polymer embedded with magnetic iron microparticles. Under normal conditions, the material is relatively stiff and holds its shape.

However, researchers can heat up the material using light from a light-emitting diode (LED), which makes the polymer pliable. Once pliable, researchers demonstrated that they could control the shape of the robot remotely by applying a magnetic field. After forming the desired shape, researchers could remove the LED light, allowing the robot to resume its original stiffness — effectively locking the shape in place.

By applying the light a second time and removing the magnetic field, the researchers could get the soft robots to return to their original shapes. Or they could apply the light again and manipulate the magnetic field to move the robots or get them to assume new shapes.

In experimental testing, the researchers demonstrated that the soft robots could be used to form “grabbers” for lifting and transporting objects. The soft robots could also be used as cantilevers, or folded into “flowers” with petals that bend in different directions.

“We are not limited to binary configurations, such as a grabber being either open or closed,” said Jessica Liu, first author of the paper and a Ph.D. student at NC State. “We can control the light to ensure that a robot will hold its shape at any point.”

Soft robots controlled by magnets, light in new research

Iron microparticles can be used to make soft robots move. Source: North Carolina State University

Streamlining robot design

In addition, the researchers developed a computational model that can be used to streamline the soft robot design process. The model allows them to fine-tune a robot’s shape, polymer thickness, the abundance of iron microparticles in the polymer, and the size and direction of the required magnetic field before constructing a prototype to accomplish a specific task.

“Next steps include optimizing the polymer for different applications,” Tracy said. “For example, engineering polymers that respond at different temperatures in order to meet the needs of specific applications.”

Authors and support

The paper, “Photothermally and Magnetically Controlled Reconfiguration of Polymer Composites for Soft Robotics,” appears in the journal Science Advances. In addition Liu as first author, the paper was co-authored by Jonathan Gillen, a former undergraduate at NC State; Sumeet Mishra, a former Ph.D. student at NC State; and Benjamin Evans, an associate professor of physics at Elon University.

The work was done with support from the National Science Foundation (NSF) under grants CMMI-1663416 and CMMI-1662641. The work was also supported by the Research Triangle MRSEC, which is funded by NSF under grant DMR-1121107; and by NC State’s Analytical Instrumentation Facility and the Duke University Shared Materials Instrumentation Facility, which are supported by the State of North Carolina and NSF grant ECCS-1542015.

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Wearable device could improve communication between humans, robots

An international team of scientists has developed an ultra-thin, wearable electronic device that facilitates smooth communication between humans and machines. The researchers said the new device is easy to manufacture and imperceptible when worn. It could be applied to human skin to capture various types of physical data for better health monitoring and early disease detection, or it could enable robots to perform specific tasks in response to physical cues from humans.

Wearable human-machine interfaces have had challenges — some are made from rigid electronic chips and sensors that are uncomfortable and restrict the body’s motion, while others consist of softer, more wearable elastic materials but suffer from slow response times.

While researchers have developed thin inorganic materials that wrinkle and bend, the challenge remains to develop wearable devices with multiple functions that enable smooth communication between humans and machines.

The team that wrote the paper included Kyoseung Sim, Zhoulyu Rao; Faheem Ershad; Jianming Lei, Anish Thukral, Jie Chen, and Cunjiang Yu at University of Houston. It also included Zhanan Zou and Jianling Xiao at University of Colorado, Boulder, and Qing-An Huang at Southeast University in Nanjing, China.

Wearable nanomembrane reads human muscle signals

Kyoseung Sim and company have designed a nanomembrane made from indium zinc oxide using a chemical processing approach that allows them to tune the material’s texture and surface properties. The resulting devices were only 3 to 4 micrometers thick, and snake-shaped, properties that allow them to stretch and remain unnoticed by the wearer.

When worn by humans, the devices could collect signals from muscle and use them to directly guide a robot, enabling the user to feel what the robot hand experienced. The devices maintain their function when human skin is stretched or compressed.

Wearable device could improve communication between humans, robots

Soft, unnoticeable, multifunctional, electronics-based, wearable human-machine interface devices. Credit: Cunjiang Yu

The researchers also found that sensors made from this nanomembrane material could be designed to monitor UV exposure (to mitigate skin disease risk) or to detect skin temperature (to provide early medical warnings), while still functioning well under strain.

Editor’s note: This month’s print issue of The Robot Report, which is distributed with Design World, focuses on exoskeletons. It will be available soon.

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Roach-inspired robot shares insect’s speed, toughness

If the sight of a skittering bug makes you squirm, you may want to look away — a new insect-sized robot created by researchers at the University of California, Berkeley, can scurry across the floor at nearly the speed of a darting cockroach. And it’s nearly as hardy as a roach is. Try to squash this robot under your foot, and more than likely, it will just keep going.

“Most of the robots at this particular small scale are very fragile. If you step on them, you pretty much destroy the robot,” said Liwei Lin, a professor of mechanical engineering at UC Berkeley and senior author of a new study that describes the robot. “We found that if we put weight on our robot, it still more or less functions.”

Small-scale robots like these could be advantageous in search-and-rescue missions, squeezing and squishing into places where dogs or humans can’t fit, or where it may be too dangerous for them to go, said Yichuan Wu, first author of the paper, who completed the work as a graduate student in mechanical engineering at UC Berkeley through the Tsinghua-Berkeley Shenzhen Institute partnership.

“For example, if an earthquake happens, it’s very hard for the big machines, or the big dogs, to find life underneath debris, so that’s why we need a small-sized robot that is agile and robust,” said Wu, who is now an assistant professor at the University of Electronic Science and Technology of China.

The study appears this week in the journal Science Robotics.

PVDF provides roach-like characteristics

The robot, which is about the size of a large postage stamp, is made of a thin sheet of a piezoelectric material called polyvinylidene fluoride, or PVDF. Piezoelectric materials are unique, in that applying electric voltage to them causes the materials to expand or contract.

UC Berkeley roach robot

The robot is built of a layered material that bends and straightens when AC voltage is applied, causing it to spring forward in a “leapfrogging” motion. Credit: UC Berkeley video and photo by Stephen McNally

The researchers coated the PVDF in a layer of an elastic polymer, which causes the entire sheet to bend, instead of to expand or contract. They then added a front leg so that, as the material bends and straightens under an electric field, the oscillations propel the device forward in a “leapfrogging” motion.

The resulting robot may be simple to look at, but it has some remarkable abilities. It can sail along the ground at a speed of 20 body lengths per second, a rate comparable to that of a roach and reported to be the fastest pace among insect-scale robots. It can zip through tubes, climb small slopes, and carry small loads, such as a peanut.

Perhaps most impressively, the robot, which weighs less than one tenth of a gram, can withstand a weight of around 60kg [132 lb.] — about the weight of an average human — which is approximately 1 million times the weight of the robot.

“People may have experienced that, if you step on the cockroach, you may have to grind it up a little bit, otherwise the cockroach may still survive and run away,” Lin said. “Somebody stepping on our robot is applying an extraordinarily large weight, but [the robot] still works, it still functions. So, in that particular sense, it’s very similar to a cockroach.”

The robot is currently “tethered” to a thin wire that carries an electric voltage that drives the oscillations. The team is experimenting with adding a battery so the roach robot can roam independently. They are also working to add gas sensors and are improving the design of the robot so it can be steered around obstacles.

Co-authors of the paper include Justin K. Yim, Zhichun Shao, Mingjing Qi, Junwen Zhong, Zihao Luo, Ronald S. Fearing and Robert J. Full of UC Berkeley, Xiaojun Yan of Beihang University and Jiaming Liang, Min Zhang and Xiaohao Wang of Tsinghua University.

This work is supported in part by the Berkeley Sensor and Actuator Center, an Industry-University Cooperation Research Center.

Editor’s note: This article republished from the University of California, Berkeley.

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Neural Analytics partners with NGK Spark Plug to scale up medical robots

Neural Analytics partners with NGL Spark Plug to scale up medical robots

The Lucid Robotic System has received FDA clearance. Source: Neural Analytics

LOS ANGELES — Neural Analytics Inc., a medical robotics company developing and commercializing technologies to measure and track brain health, has announced a strategic partnership with NGK Spark Plug Co., a Japan-based company that specializes in comprehensive ceramics processing. Neural Analytics said the partnership will allow it to expand its manufacturing capabilities and global footprint.

Neural Analytics’ Lucid Robotic System (LRS) includes the Lucid M1 Transcranial Doppler Ultrasound System and NeuralBot system. The resulting autonomous robotic transcranial doppler (rTCD) platform is designed to non-invasively search, measure, and display objective brain blood-flow information in real time.

The Los Angeles-based company’s technology integrates ultrasound and robotics to empower clinicians with critical information about brain health to make clinical decisions. Through its algorithm, analytics, and autonomous robotics, Neural Analytics provides valuable information that can identify pathologies such as Patent Foramen Ovale (PFO), a form of right-to-left shunt.

Nagoya, Japan-based NGK Spark Plug claims to be the world’s leading manufacturer of spark plugs and automotive sensors, as well as a broad lineup of packaging, cutting tools, bio ceramics, and industrial ceramics. The company has more than 15,000 employees and develops products related to the environment, energy, next-generation vehicles, and the medical device and diagnostic industries.

Neural Analytics and NGK to provide high-quality parts, global access

“This strategic partnership between Neural Analytics and NGK Spark Plug is built on a shared vision for the future of global healthcare and a foundation of common values,” said Leo Petrossian, Ph.D., co-founder and CEO of Neural Analytics. “We are honored with this opportunity and look forward to learning from our new partners how they have built a great global enterprise,”

NGK Spark Plug has vast manufacturing expertise in ultra-high precision ceramics. With this partnership, both companies said they are committed in working together to build high-quality products at a reasonable cost to allow greater access to technologies like the Lucid Robotic System.

“I am very pleased with this strategic partnership with Neural Analytics,” said Toru Matsui, executive vice president of NGK Spark Plug. “This, combined with a shared vision, is an exciting opportunity for both companies. This alliance enables the acceleration of their great technology to the greater market.”

This follows Neural Analytics’ May announcement of its Series C round close, led by Alpha Edison. In total, the company has raised approximately $70 million in funding to date.

Neural Analytics said it remains “committed to advancing brain healthcare through transformative technology to empower clinicians with the critical information needed to make clinical decisions and improve patient outcomes.”

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Microrobots activated by laser pulses could deliver medicine to tumors

Targeting medical treatment to an ailing body part is a practice as old as medicine itself. Drops go into itchy eyes. A broken arm goes into a cast. But often what ails us is inside the body and is not so easy to reach. In such cases, a treatment like surgery or chemotherapy might be called for. A pair of researchers in Caltech’s Division of Engineering and Applied Science are working on an entirely new form of treatment — microrobots that can deliver drugs to specific spots inside the body while being monitored and controlled from outside the body.

“The microrobot concept is really cool because you can get micromachinery right to where you need it,” said Lihong Wang, Bren Professor of Medical Engineering and Electrical Engineering at the California Institute of Technology. “It could be drug delivery, or a predesigned microsurgery.”

The microrobots are a joint research project of Wang and Wei Gao, assistant professor of medical engineering, and are intended for treating tumors in the digestive tract.

Developing jet-powered microrobots

The microrobots consist of microscopic spheres of magnesium metal coated with thin layers of gold and parylene, a polymer that resists digestion. The layers leave a circular portion of the sphere uncovered, kind of like a porthole. The uncovered portion of the magnesium reacts with the fluids in the digestive tract, generating small bubbles. The stream of bubbles acts like a jet and propels the sphere forward until it collides with nearby tissue.

On their own, magnesium spherical microrobots that can zoom around might be interesting, but they are not especially useful. To turn them from a novelty into a vehicle for delivering medication, Wang and Gao made some modifications to them.

First, a layer of medication is sandwiched between an individual microsphere and its parylene coat. Then, to protect the microrobots from the harsh environment of the stomach, they are enveloped in microcapsules made of paraffin wax.

Laser-guided delivery

At this stage, the spheres are capable of carrying drugs, but still lack the crucial ability to deliver them to a desired location. For that, Wang and Gao use photoacoustic computed tomography (PACT), a technique developed by Wang that uses pulses of infrared laser light.

The infrared laser light diffuses through tissues and is absorbed by oxygen-carrying hemoglobin molecules in red blood cells, causing the molecules to vibrate ultrasonically. Those ultrasonic vibrations are picked up by sensors pressed against the skin. The data from those sensors is used to create images of the internal structures of the body.

Previously, Wang has shown that variations of PACT can be used to identify breast tumors, or even individual cancer cells. With respect to the microrobots, the technique has two jobs. The first is imaging. By using PACT, the researchers can find tumors in the digestive tract and also track the location of the microrobots, which show up strongly in the PACT images.

Microrobots activated by laser pulses could deliver medicine to tumors

Microrobots activated by lasers and powered by magnesium jets could deliver medicine within the human body. Source: Caltech

Once the microrobots arrive in the vicinity of the tumor, a high-power continuous-wave near-infrared laser beam is used to activate them. Because the microrobots absorb the infrared light so strongly, they briefly heat up, melting the wax capsule surrounding them, and exposing them to digestive fluids.

At that point, the microrobots’ bubble jets activate, and the microrobots begin swarming. The jets are not steerable, so the technique is sort of a shotgun approach — the microrobots will not all hit the targeted area, but many will. When they do, they stick to the surface and begin releasing their medication payload.

“These micromotors can penetrate the mucus of the digestive tract and stay there for a long time. This improves medicine delivery,” Gao says. “But because they’re made of magnesium, they’re biocompatible and biodegradable.”

Pushing the concept

Tests in animal models show that the microrobots perform as intended, but Gao and Wang say they are planning to continue pushing the research forward.

“We demonstrated the concept that you can reach the diseased area and activate the microrobots,” Gao says. “The next step is evaluating the therapeutic effect of them.”

Gao also says he would like to develop variations of the microrobots that can operate in other parts of the body, and with different types of propulsion systems.

Wang says his goal is to improve how his PACT system interacts with the microrobots. The infrared laser light it uses has some difficulty reaching into deeper parts of the body, but he says it should be possible to develop a system that can penetrate further.

The paper describing the microrobot research, titled, “A microrobotic system guided by photoacoustic tomography for targeted navigation in intestines in vivo,” appears in the July 24 issue of Science Robotics. Other co-authors include Zhiguang Wu, Lei Li, Yiran Yang (MS ’18), Yang Li, and So-Yoon Yang of Caltech; and Peng Hu of Washington University in St. Louis. Funding for the research was provided by the National Institutes of Health and Caltech’s Donna and Benjamin M. Rosen Bioengineering Center.

Editor’s note: This article republished from the California Institute of Technology.

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Artificial muscles based on MIT fibers could make robots more responsive

Artificial muscles from MIT achieve powerful pulling force

Artificial muscles based on powerful fiber contractions could advance robotics and prosthetics. Credit: Felice Frankel

CAMBRIDGE, Mass. — As a cucumber plant grows, it sprouts tightly coiled tendrils that seek out supports in order to pull the plant upward. This ensures the plant receives as much sunlight exposure as possible. Now, researchers at the Massachusetts Institute of Technology have found a way to imitate this coiling-and-pulling mechanism to produce contracting fibers that could be used as artificial muscles for robots, prosthetic limbs, or other mechanical and biomedical applications.

While many different approaches have been used for creating artificial muscles, including hydraulic systems, servo motors, shape-memory metals, and polymers that respond to stimuli, they all have limitations, including high weight or slow response times. The new fiber-based system, by contrast, is extremely lightweight and can respond very quickly, the researchers say. The findings are being reported today in the journal Science.

The new fibers were developed by MIT postdoc Mehmet Kanik and graduate student Sirma Örgüç, working with professors Polina Anikeeva, Yoel Fink, Anantha Chandrakasan, and C. Cem Taşan. The team also included MIT graduate student Georgios Varnavides, postdoc Jinwoo Kim, and undergraduate students Thomas Benavides, Dani Gonzalez, and Timothy Akintlio. They have used a fiber-drawing technique to combine two dissimilar polymers into a single strand of fiber.

artificial muscle fiber at MIT

Credit: Courtesy of the researchers, MIT

The key to the process is mating together two materials that have very different thermal expansion coefficients — meaning they have different rates of expansion when they are heated. This is the same principle used in many thermostats, for example, using a bimetallic strip as a way of measuring temperature. As the joined material heats up, the side that wants to expand faster is held back by the other material. As a result, the bonded material curls up, bending toward the side that is expanding more slowly.

Using two different polymers bonded together, a very stretchable cyclic copolymer elastomer and a much stiffer thermoplastic polyethylene, Kanik, Örgüç and colleagues produced a fiber that, when stretched out to several times its original length, naturally forms itself into a tight coil, very similar to the tendrils that cucumbers produce.

Artificial muscles surprise

But what happened next actually came as a surprise when the researchers first experienced it. “There was a lot of serendipity in this,” Anikeeva recalled.

As soon as Kanik picked up the coiled fiber for the first time, the warmth of his hand alone caused the fiber to curl up more tightly. Following up on that observation, he found that even a small increase in temperature could make the coil tighten up, producing a surprisingly strong pulling force. Then, as soon as the temperature went back down, the fiber returned to its original length.

In later testing, the team showed that this process of contracting and expanding could be repeated 10,000 times “and it was still going strong,” Anikeeva said.

One of the reasons for that longevity, she said, is that “everything is operating under very moderate conditions,” including low activation temperatures. Just a 1-degree Celsius increase can be enough to start the fiber contraction.

The fibers can span a wide range of sizes, from a few micrometers (millionths of a meter) to a few millimeters (thousandths of a meter) in width, and can easily be manufactured in batches up to hundreds of meters long. Tests have shown that a single fiber is capable of lifting loads of up to 650 times its own weight. For these experiments on individual fibers, Örgüç and Kanik have developed dedicated, miniaturized testing setups.

artificial muscle fiber test

Credit: Courtesy of the researchers, MIT

The degree of tightening that occurs when the fiber is heated can be “programmed” by determining how much of an initial stretch to give the fiber. This allows the material to be tuned to exactly the amount of force needed and the amount of temperature change needed to trigger that force.

The fibers are made using a fiber-drawing system, which makes it possible to incorporate other components into the fiber itself. Fiber drawing is done by creating an oversized version of the material, called a preform, which is then heated to a specific temperature at which the material becomes viscous. It can then be pulled, much like pulling taffy, to create a fiber that retains its internal structure but is a small fraction of the width of the preform.

For testing purposes, the researchers coated the fibers with meshes of conductive nanowires. These meshes can be used as sensors to reveal the exact tension experienced or exerted by the fiber. In the future, these fibers could also include heating elements such as optical fibers or electrodes, providing a way of heating it internally without having to rely on any outside heat source to activate the contraction of the “muscle.”

Potential applications

Such artificial muscle fibers could find uses as actuators in robotic arms, legs, or grippers, and in prosthetic limbs, where their slight weight and fast response times could provide a significant advantage.

Some prosthetic limbs today can weigh as much as 30 pounds, with much of the weight coming from actuators, which are often pneumatic or hydraulic; lighter-weight actuators could thus make life much easier for those who use prosthetics.

Credit: Courtesy of the researchers, MIT

“Such fibers might also find uses in tiny biomedical devices, such as a medical robot that works by going into an artery and then being activated,” Anikeeva said. “We have activation times on the order of tens of milliseconds to seconds,” depending on the dimensions.

To provide greater strength for lifting heavier loads, the fibers can be bundled together, much as muscle fibers are bundled in the body. The team successfully tested bundles of 100 fibers.

Through the fiber-drawing process, sensors could also be incorporated in the fibers to provide feedback on conditions they encounter, such as in a prosthetic limb. Örgüç said bundled muscle fibers with a closed-loop feedback mechanism could find applications in robotic systems where automated and precise control are required.

Kanik said that the possibilities for materials of this type are virtually limitless, because almost any combination of two materials with different thermal expansion rates could work, leaving a vast realm of possible combinations to explore. He added that this new finding was like opening a new window, only to see “a bunch of other windows” waiting to be opened.

“The strength of this work is coming from its simplicity,” he said.

The work was supported by the National Institute of Neurological Disorders and Stroke and the National Science Foundation.

Editor’s note: This article republished with permission from MIT News. 

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4 Overheating solutions for commercial robotics

4 Overheating solutions for commercial robotics

Stanford University researchers have developed a lithium-ion battery that shuts down before overheating. Source: Stanford University

Overheating can become a severe problem for robots. Excessive temperatures can damage internal systems or, in the most extreme cases, cause fires. Commercial robots that regularly get too hot can also cost precious time, as operators are forced to shut down and restart the machines during a given shift.

Fortunately, robotics designers have several options for keeping industrial robots cool and enabling workflows to progress smoothly. Here are four examples of technologies that could keep robots at the right temperature.

1. Lithium-ion batteries that automatically shut off and restart

Many robots, especially mobile platforms for factories or warehouses, have lithium-ion battery packs. Such batteries are popular and widely available, but they’re also prone to overheating and potentially exploding.

Researchers at Stanford University engineered a battery with a special coating that stops it from conducting electricity if it gets too hot. As the heat level climbed, the layer expanded, causing a functional change that made the battery itself no longer conducive. However, once cool, it starts providing power as usual.

The research team did not specifically test their battery coating in robots powered by lithium-ion batteries. However, it noted that the work has practical merit for a variety of use cases due to how it’s possible to change the heat level that causes the battery to shut down.

For example, if a robot has extremely sensitive internal parts, users would likely want it to shut down at a lower temperature than when using it in a more tolerant machine.

2. Sensors that measure a robot’s ‘health’ to avoid overheating

Commercial robots often allow corporations to achieve higher, more consistent performance levels than would be possible with human effort alone. Industrial-grade robots don’t need rest breaks, but unlike humans who might speak up if they feel unwell and can’t complete a shift, robots can’t necessarily notify operators that something’s wrong.

However, University of Saarland researchers have devised a method that subjects industrial machines to the equivalent of a continuous medical checkup. Similar to how consumer health trackers measure things like a person’s heart rate and activity levels and give them opportunities to share these metrics with a physician, a team aims to do the same with industrial machinery.

Continual robot monitoring

A research team at Saarland University has developed an early warning system for industrial assembly, handling, and packaging processes. Research assistants Nikolai Helwig (left) and Tizian Schneider test the smart condition monitoring system on an electromechanical cylinder. Credit: Oliver Dietze, Saarland University

It should be possible to see numerous warning signs before a robot gets too hot. The scientists explained that they use special sensors that fit inside the machines and can interact with one another as well as a robot’s existing process sensors. The sensors collect baseline data. They can also recognize patterns that could indicate a failing part — such as that the machine gets hot after only a few minutes of operating.

That means the sensors could warn plant operators of immediate issues, like when a robot requires an emergency shutdown because of overheating. It could also help managers understand if certain processes make the robots more likely to overheat than others. Thanks to the constant data these sensors provide, human workers overseeing the robots should have the knowledge they need to intervene before a catastrophe occurs.

Manufacturers already use predictive analytics to determine when to perform maintenance. This approach could provide even more benefits because it goes beyond maintenance alerts and warns if robots stray from their usual operating conditions due because of overheating or other reasons that need further investigation.

3. Thermally conductive rubber

When engineers design robots or work in the power electronics sector, heat dissipation technologies are almost always among the things to consider before the product becomes functional. For example, even in a device that’s 95% efficient, the remaining 5% gets converted into heat that needs to escape.

Power electronics overheating roadmap

Source: Advanced Cooling Technologies

Pumped liquid, extruded heatsinks, and vapor chambers are some of the available methods for keeping power electronics cool. Returning to commercial robotics specifically, Carnegie Mellon University scientists have developed a material that aids in heat management for soft robots. They said their creation — nicknamed “thubber” — combines elasticity with high heat conductivity.

CMU thubber for overheating

A nano-CT scan of “thubber” showing the liquid-metal microdroplets inside the rubber material. Source: Carnegie Mellon University

The material stretches to more than six times its initial length, and that’s impressive in itself. However, the CMIU researchers also mentioned that the blend of high heat conductivity and the flexibility of the material are crucial for facilitating dissipation. They pointed out that past technologies required attaching high-powered devices to inflexible mounts, but they now envision creating these from the thubber.

Then, the respective devices, whether bendable robots or folding electronics, could be more versatile and stay cool as they function.

4. Liquid cooling and fan systems

Many of the cooling technologies used in industrial robots happen internally, so users don’t see them working, but they know everything is functioning as it should since the machine stays at a desirable temperature. Plus, there are some robots for which heat reduction is exceptionally important due to the tasks they assume. Firefighting robots are prime examples.

One of them, called Colossus, recently helped put out the Notre Dame fire in Paris. It has an onboard smoke ventilation system that likely has a heat-management component, too. Purchasers can also pay more to get a smoke-extracting fan. It’s an example of a mobile robot that uses lithium-ion batteries, making it a potential candidate for the first technology on the list.

There’s another firefighting robot called the Thermite, and it uses both water and fans to stay cool. For example, the robot can pump out 500 gallons of water per minute to control a blaze, but a portion of that liquid goes through the machine’s internal “veins” first to keep it from overheating.

In addition, part of Thermite converts into a sprinkler system, and onboard fans help recycle the associated mist and cool the machine’s components.

An array of overheating options

Robots are increasingly tackling jobs that are too dangerous for humans. As these examples show, they’re up to the task as long as the engineers working to develop those robots remain aware of internal cooling needs during the design phase.

This list shows that engineers aren’t afraid to pursue creative solutions as they look for ways to avoid overheating. Although many of the technologies described here are not yet available for people to purchase, it’s worthwhile for developers to stay abreast of the ongoing work. The attempts seem promising, and even cooling efforts that aren’t ready for mainstream use could lead to overall progress.

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Programmable soft actuators show potential of soft robotics at TU Delft

Researchers at the Delft University of Technology in the Netherlands have developed highly programmable soft actuators that, similar to the human hand, combine soft and hard materials to perform complex movements. These materials have great potential for soft robots that can safely and effectively interact with humans and other delicate objects, said the TU Delft scientists.

“Robots are usually big and heavy. But you also want robots that can act delicately, for instance, when handling soft tissue inside the human body. The field that studies this issue, soft robotics, is now really taking off,” said Prof. Amir Zadpoor, who supervised the research presented the July 8 issue of Materials Horizons.

“What you really want is something resembling the features of the human hand including soft touch, quick yet accurate movements, and power,” he said. “And that’s what our soft 3D-printed programmable materials strive to achieve.”

Tunability

Owing to their soft touch, soft robotics can safely and effectively interact with humans and other delicate objects. Soft programmable mechanisms are required to power this new generation of robots. Flexible mechanical metamaterials, working on the basis of mechanical instability, offer unprecedented functionalities programmed into their architected fabric that make them potentially very promising as soft mechanisms, said the TU Delft researchers.

“However, the tunability of the mechanical metamaterials proposed so far have been very limited,” said first author Shahram Janbaz.

Programmable soft actuators

“We now present some new designs of ultra-programmable mechanical metamaterials, where not only the actuation force and amplitude, but also the actuation mode could be selected and tuned within a very wide range,” explained Janbaz. “We also demonstrate some examples of how these soft actuators could be used in robotics, for instance as a force switch, kinematic controllers, and a pick-and-place end-effector.”

Soft actuators from TU Delft

A conventional robotic arm is modified using the developed soft actuators to provide soft touch during pick-and-place tasks. Source: TU Delft

Buckling

“The function is already incorporated in the material,” Zadpoor explained. “Therefore, we had to look deeper at the phenomenon of buckling. This was once considered the epitome of design failure, but has been harnessed during the last few years to develop mechanical metamaterials with advanced functionalities.”

“Soft robotics in general and soft actuators in particular could greatly benefit from such designer materials,” he added. “Unlocking the great potential of buckling-driven materials is, however, contingent on resolving the main limitation of the designs presented to date, namely the limited range of their programmability. We were able to calculate and predict higher modes of buckling and make the material predisposed to these higher modes.”

3D printing

“So, we present multi-material buckling-driven metamaterials with high levels of programmability,” said Janbaz. “We combined rational design approaches based on predictive computational models with advanced multi-material additive manufacturing techniques to 3D print cellular materials with arbitrary distributions of soft and hard materials in the central and corner parts of their unit cells.”

“Using the geometry and spatial distribution of material properties as the main design parameters, we developed soft mechanical metamaterials behaving as mechanisms whose actuation force and actuation amplitude could be adjusted,” he said.

Editor’s note: This article republished from TU Delft.

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Snake-inspired robot uses kirigami for swifter slithering

Bad news for ophiophobes: Researchers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) have developed a new and improved snake-inspired soft robot that is faster and more precise than its predecessor.

The robot is made using kirigami — a Japanese paper craft that relies on cuts to change the properties of a material. As the robot stretches, the kirigami surface “pops up” into a 3-D-textured surface, which grips the ground just like snake skin.

The first-generation robot used a flat kirigami sheet, which transformed uniformly when stretched. The new robot has a programmable shell, so the kirigami cuts can pop up as desired, improving the robot’s speed and accuracy.

The research was published in the Proceedings of the National Academy of Sciences.

“This is a first example of a kirigami structure with non-uniform pop-up deformations,” said Ahmad Rafsanjani, a postdoctoral fellow at SEAS and first author of the paper. “In flat kirigami, the pop-up is continuous, meaning everything pops at once. But in the kirigami shell, pop up is discontinuous. This kind of control of the shape transformation could be used to design responsive surfaces and smart skins with on-demand changes in their texture and morphology.”

The new research combined two properties of the material — the size of the cuts and the curvature of the sheet. By controlling these features, the researchers were able to program dynamic propagation of pop ups from one end to another, or control localized pop-ups.

Snake-inspired robot slithers even better than predecessor

This programmable kirigami metamaterial enables responsive surfaces and smart skins. Source: Harvard SEAS

In previous research, a flat kirigami sheet was wrapped around an elastomer actuator. In this research, the kirigami surface is rolled into a cylinder, with an actuator applying force at two ends. If the cuts are a consistent size, the deformation propagates from one end of the cylinder to the other. However, if the size of the cuts are chosen carefully, the skin can be programmed to deform at desired sequences.

“By borrowing ideas from phase-transforming materials and applying them to kirigami-inspired architected materials, we demonstrated that both popped and unpopped phases can coexists at the same time on the cylinder,” said Katia Bertoldi, the William and Ami Kuan Danoff Professor of Applied Mechanics at SEAS and senior author of the paper. “By simply combining cuts and curvature, we can program remarkably different behavior.”

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Next, the researchers aim to develop an inverse design model for more complex deformations.

“The idea is, if you know how you’d like the skin to transform, you can just cut, roll, and go,” said Lishuai Jin, a graduate student at SEAS and co-author of the article.

This research was supported in part by the National Science Foundation. It was co-authored by Bolei Deng.

Editor’s note: This article was republished from the Harvard John A. Paulson School of Engineering and Applied Sciences.

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