This technique and materials combination was used to fabricate a valve which actuates in response to the temperature of any water surrounding it.
“The cool thing about it is, it’s a working, functioning device that you just pick up from the printer,” says ACES Professor Marc in het Panhuis. “There’s no other assembly required.”
The valve, a 3D printed structure, includes the actuators, and they’re activated solely by the introduction of water.
The “smart valve” is created by the 4D printing of hydrogels that are both mechanically robust and thermally actuating, and they’re made of an interpenetrating network of alginate and poly N-isopropylacrylamide. These ‘4D’ structures are created by printing the “dynamic” hydrogel ink alongside other static materials used to fabricate the device.
“It’s an autonomous valve,” Panhuis says. “There’s no input necessary other than water; it closes itself when it detects hot water.”
As the ACES Chief Investigator, Panhuis says his group was the first to combine the printing a 4D device with four different cartridges at once. The process uses the tough hydrogels – fiber reinforced in a single-step process – and these composite materials were fabricated using a combination of a alginate-acrylamide gel precursor solution and an epoxy based UV-curable adhesive known as Emax 904 Gel-SC.
Panhuis says his main research focus is to combine bio and synthetic polymers with carbon nanostructures, and or conducting polymers via processing techniques such as additive fabrication into soft (wet and tough) materials for water treatment, soft robotics, bionics and tissue engineering applications.
The authors of the paper that the team published on the research, 4D Printing with Mechanically Robust, Thermally Actuating Hydrogels, were Shannon Bakarich, Doctor Robert Gorkin III, Panhuis and Professor Geoff Spinks.