Origami structures offer a number of benefits that could be useful to a range of applications from biomedical devices to equipment used in space exploration. Some of these benefits are low weight, expandability, and high strength.
Until recently, though, no technology was available to make origami structures. Multiple steps are needed to build these structures, which often need more than one material and assembly from smaller parts. Additive manufacturing, however, can be used to make such structures.
Professor Glaucio H. Paulino, at the School of Civil and Environmental Engineering at the Georgia Institute of Technology, and his researchers proved that 3D printing can be used to manufacture complex origami. Last fall Georgia Tech became the first university in the country to offer a course on origami engineering, which Paulino taught.
The researchers used Digital Light Processing (DLP) to create groundbreaking origami structures that are not only capable of holding significant weight but can also be folded and refolded repeatedly in an action similar to the slow push and pull of an accordion. When Paulino first reported these structures, or “zippered tubes,” in 2015, they were made of paper and required gluing. In the current work, the zippered tubes – and complex structures made out of them – are composed of one plastic (a polymer) and do not require assembly.
The work, 3D printing of complex origami assemblages for reconfigurable structures, by Zeang Zhao, was reported in a recent issue of Soft Matter, a journal published by the Royal Society of Chemistry. The primary authors are Paulino; H. Jerry Qi, a professor in Georgia Tech’s George W. Woodruff School of Mechanical Engineering; and Daining Fang of Peking University and the Beijing Institute of Technology. Other authors are Zeang Zhao, a visiting student at Georgia Tech now at Peking University; Qiang Zhang of Peking University; and Xiao Kuang and Jiangtao Wu of Georgia Tech.
Until now, it has been difficult to create 3D-printed structures with the intricate hollow features associated with complex origami because removing the supporting materials necessary to print these structures is challenging. Further, unlike paper, the 3D-printed materials could not be folded numerous times without breaking.
For the current work, the researchers first developed a new resin that, when cured, is very strong. “We wanted a material that is not only soft, but can also be folded hundreds of times without breaking,” said Qi. The resin, in turn, is key to an equally important element of the work: tiny hinges. These hinges, which occur along the creases where the origami structure folds, allow folding because they are made of a thinner layer of resin than the larger panels of which they are part. (The panels make up the bulk of the structure.)
Together the new resin and hinges worked. The team used DLP to create several origami structures ranging from the individual origami cells that the zippered tubes are composed of to a complex bridge composed of many zippered tubes. All were subjected to tests that showed they were not only capable of carrying about 100 times the weight of the origami structure, but also could be repeatedly folded and unfolded without breaking. “I have a piece that I printed about six months ago that I demonstrate for people all the time, and it’s still fine,” said Qi.
Qi is working to make the printing even easier while also exploring ways to print materials with different properties. Meanwhile, Paulino’s team recently created a new origami pattern on the computer that he is excited about but that he has been unable to physically make because it is so complex. “I think the new system could bring it to life,” he said.
The principal funders of the work were the Air Force Office of Scientific Research (FA9550-16-1-0169), the National Science Foundation (CMMI-1462894, CMMI-1462895, and CMMI-1538830), the Raymond Allen Jones Chair at Georgia Tech, the National Natural Science Foundation of China, and the National Materials Genome Project of China.
Georgia Institute of Technology
www.gatech.edu