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Purdue Start-Up Targets Defense Applications

Purdue researchers use ultrasonic vibrations to improve printing with viscous materials.

Purdue Start-Up Targets Defense Applications
Source: Image courtesy Purdue University
Researchers at Purdue are using ultrasonic vibrations to provide better control and accuracy when printing with thick, viscous materials.

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By Brian Albright  

December 18, 2018

Researchers at Purdue University have come up with a method to more efficiently print with thick, viscous materials while also improving safety and reduce environmental damage. Jeffrey Rhoads, a professor in Purdue’s School of Mechanical Engineering, and Emre Gunduz, a former research assistant professor at the school have launched a new startup (Next Offset Solutions Inc.) to make printers and energetic materials based on the research. The energetic materials include solid rocket fuels, propellants and pyrotechnics.

The process allows for the printing of thick materials with high levels of precision by applying ultrasonic vibrations to the nozzle to reduce friction and allow for smooth materials flow. It also allows for more precise flow control. “It's like the Play-Doh press of the 21st century,” Rhoads said.

“We have shown that we can print these energetic materials without voids, which is key,” Rhoads said. “Voids are bad in energetic materials because they typically lead to inconsistent, sometimes catastrophic, burns.”

The team also used the method to print biomedical implants, personalized drugs and other products. Next Offset Solutions will focus on energetic materials, but is exploring other potential applications.

The process doesn’t rely on solvents, which makes the printers more environmentally friendly, and the printers can be operated remotely. When dealing with propellants and other materials, that can increase operator safety.

“You don't have to have a person there interfacing with the system. That's a big advantage from the safety standpoint,” Rhoads said.

Eliminating solvents also means that the process is less expensive and faster than traditional approaches. 

Next Offset hopes to provide these printers and their products to the Department of Defense, Department of Energy, and contractors that serve both of them. Because the company already uses materials that are qualified by those government agencies, the resultant products can be more quickly adopted.

Source: Purdue University

 
 

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