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Purdue Finds High-Tech Use for Sewing Machine

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Purdue researchers say a traditional sewing machine could play a key role in creating high-tech products with a variety of medical applications. So-called "soft" robotics are wearable electronics and implantable medical systems made of elastic materials that are capable of extreme stretching. These new stretchable technologies could lead to innovations including robots that have humanlike sensory skin and synthetic muscles and flexible garments that people might wear to interact with computers or for therapeutic purposes. There are complicated, expensive ways of doing this, but a Purdue team has come up with a simple, less-costly alternative: Use a standard sewing machine to create ultra-stretchable interconnects out of conventional wire. To see the product and read more about it visit regionnewsteam-dot-com. [Photo one: Researchers have used a standard sewing machine to create this new type of low-cost flexible metal interconnect for "soft" robotics, wearable electronics and implantable medical systems that might be made of elastic materials capable of extreme stretching. Competing approaches require the use of complicated and expensive microfabrication techniques or exotic technologies such as liquid-metal-filled microchannels and ultrathin wires prone to breaking. (Purdue University photo/Babak Ziaie) ]
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[Photo two: The interconnect is capable of stretching 500 percent of its length, which could allow for new applications. Researchers used their technique to demonstrate a stretchable "inductive strain sensor" for monitoring expansion of an inflatable urinary catheter balloon. Such an elastic technology could have applications in stretchable garments that people might wear to interact with computers or for therapeutic purposes. (Purdue University photo/Babak Ziaie) ]
The wire is sewn in a zigzag pattern and embedded in a rubbery, stretchable "elastomer" called Ecoflex, manufactured by Smooth-On Inc.
Other researchers are pursuing approaches that require the use of complicated and expensive microfabrication techniques or exotic technologies such as liquid-metal-filled microchannels and ultrathin wires prone to breaking.
The interconnect is capable of stretching 500 percent of its length, which could allow for new applications. Researchers used their technique to demonstrate a stretchable "inductive strain sensor" for monitoring expansion of an inflatable urinary catheter balloon. Such an elastic technology could have applications in stretchable garments that people might wear to interact with computers or for therapeutic purposes.
The researchers have demonstrated that the interconnect is capable of stretching 500 percent of its length.
"This compares to only a few percent for an ordinary metal connection," said said Babak Ziaie, a Purdue University professor in the School of Electrical and Computer Engineering and Weldon School of Biomedical Engineering.Ziaie, leading the research with doctoral student Rahim Rahimi. "The structures are also highly robust, capable of withstanding thousands of repeated stretch-and-release cycles."
Findings are detailed in a paper being presented during the Solid-State Sensors, Actuators and Microsystems Workshop on June 8-12 in Hilton Head Island, S.C. The paper was authored by Rahimi, Ziaie, and doctoral students Manuel Ochoa and Wuyang Yu.
Since it was not practical to sew the wire directly into the rubbery elastomer because of its squishy nature, the researchers developed a technique to first sew the wire into a sheet of polyethylene terephthalate (PET), the same material used to make transparencies for overheard projectors. The zigzag wire pattern was stitched to the PET sheets with a water-soluble thread. Then the rubbery stretchable polymer was poured over the sheet, encasing the wire as it solidified. Warm water was used to dissolve the thread, and the flexible polymer was separated from the PET sheet with the wire embedded in it.
The researchers used their technique to demonstrate a stretchable "inductive strain sensor" for monitoring expansion of an inflatable urinary catheter balloon. Strain gauges measure how much a material stretches or deforms. Because conventional strain gauges are made of rigid metal film, they can't measure more than a small percentage of the deformation before breaking, whereas a soft strain gauge could continue stretching with the material.
The research has been funded by the National Science Foundation.


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