New silicone 3D printing opens up applications for robotics, medicine, wearables

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The fabrication of soft devices is evolving further, with the completion of recent research performed by US scientists. With the results published in “3D printable tough silicone double networks,” the authors explain how soft materials can be fabricated with micron resolution for complex systems like robotics, as well as new types of wearables.

Soft materials are produced industrially for many applications, with soft matter deployed for shock absorption, conformal requirements, energy recapture and robotics, where devices must be able to deform. Cross-linked materials like silicone rubbers (more formally known as poly(dimethylsiloxanes)) are popular for use due to strong mechanical properties, and temperature and chemical resistance. Most methods for using such materials with traditional techniques like injection molding are extremely limited though, and only suitable for creating basic geometries.

Previous research has shown success with liquid silicone rubber material for 3D printing ink, yielding more complex shapes. Challenges have been noted, however, in terms of structures being printed with overhangs, as well as those with a “high aspect ratio structure,” due to lack of stability like “slumping” before curing. Other experimental techniques have resulted in a lack of resolution, inferior mechanical properties, or slower printing speed.

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Artificial skin could help rehabilitation and enhance virtual reality

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Artificial skin could help rehabilitation and enhance virtual reality

EPFL scientists have developed a soft artificial skin that provides haptic feedback and—thanks to a sophisticated self-sensing mechanism—has the potential to instantaneously adapt to a wearer’s movements. Applications for the new technology range from medical rehabilitation to virtual reality. Artificial skin could help rehabilitation and enhance virtual reality.

Just like our senses of hearing and vision, our sense of touch plays an important role in how we perceive and interact with the world around us. And technology capable of replicating our sense of touch—also known as haptic feedback—can greatly enhance human-computer and human-robot interfaces for applications such as medical rehabilitation and virtual reality.

Scientists at EPFL’s Reconfigurable Robotics Lab (RRL), headed by Jamie Paik, and Laboratory for Soft Bioelectronic Interfaces (LSBI), headed by Stéphanie Lacour at the School of Engineering, have teamed up to develop a soft, flexible artificial skin made of silicone and electrodes. Both labs are part of the NCCR Robotics program.

The skin’s system of soft sensors and actuators enable the artificial skin to conform to the exact shape of a wearer’s wrist, for example, and provide haptic feedback in the form of pressure and vibration. Strain sensors continuously measure the skin’s deformation so that the haptic feedback can be adjusted in real time to produce a sense of touch that’s as realistic as possible. The scientists’ work has just been published in Soft Robotics.

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Fake blood pumps life into this robotic fish

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Autonomous robots may soon be an ever-present force in our lives, but they are going nowhere fast — or rather, a short distance quickly — without better batteries. You’ve surely seen modern robots scamper through woods or vacuum your floors, but they can only do it for short periods before their energy runs out. Many carry a large battery, which increases a robot’s weight, and in a vicious cycle, requires more power to move.

But a new development in robotic technology that borrows from biology may lead to longer lasting batteries.

The fish “blood” that runs through it serves as both the robot’s power source and controls its movement.

Researchers have engineered a robotic lionfish with synthetic arteries, similar to those found in a human’s circulatory system. The fish “blood” that runs through it serves as both the robot’s power source and controls its movement. The findings, published Wednesday in Nature, may propel the new wave of soft robots, in which inventors seek to improve lifelike automated machines for human connection.

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Artificial muscles give soft robots superpowers

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Soft robotics has made leaps and bounds over the last decade as researchers around the world have experimented with different materials and designs to allow once rigid, jerky machines to bend and flex in ways that mimic and can interact more naturally with living organisms. However, increased flexibility and dexterity has a trade-off of reduced strength, as softer materials are generally not as strong or resilient as inflexible ones, which limits their use.

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