New origami-inspired system turns flat-pack tubes into strong building materials

RMIT

Engineers at RMIT University have designed an innovative tubular structural system that can be packed flat for easier transport and pop up into strong building materials.

This breakthrough is made possible by a self-locking system inspired by curved-crease origami – a technique that uses curved crease lines in paper folding.

Lead researchers, Dr Jeff (Ting-Uei) Lee and Distinguished Professor Mike (Yi Min) Xie, said bamboo, which has internal structures providing natural reinforcement, inspired the tube design.

“This self-locking system is the result of an intelligent geometric design,” said Lee from RMIT’s School of Engineering.

“Our invention is suitable for large-scale use – a panel, weighing just 1.3 kg, made from multiple tubes can easily support a 75 kg person.”

Distinguished Professor Mike Xie (left) and Dr Jeff Lee. Credit: Will Wright, RMIT

Distinguished Professor Mike Xie (left) and Dr Jeff Lee. Credit: Will Wright, RMIT

Flat-pack tubes are already widely used in engineering and scientific applications, such as in biomedical devices, aerospace structures, robotics and civil construction, including pop-up buildings as part of disaster recovery efforts.

The new system makes these tubes quicker and easier to assemble, with the capability to automatically transform into a strong, self-locked state.

“Our research not only opens up new possibilities for innovative and multifunctional structural designs, but it can also significantly improve existing deployable systems,” said Xie from the School of Engineering.

Dr Jeff Lee with a flat-pack tube. Credit: Will Wright, RMIT

Dr Jeff Lee with a flat-pack tube. Credit: Will Wright, RMIT

“When NASA deploys solar arrays, for example, the booms used are tubes that were packed flat before being unfurled in space,” Lee said.

“These tubes are hollow though, so they could potentially deform under certain forces in space. With our new design, these booms could be a stronger structure.”

The research is published in the prestigious journal Proceedings of the National Academy of Sciences (PNAS). Other contributors to this work include Drs Hongjia Lu, Jiaming Ma and Ngoc San Ha from RMIT’s School of Engineering and Associate Professor Joseph Gattas from the University of Queensland.

A tube in the self-locked position. Credit: Will Wright, RMIT

A tube in the self-locked position. Credit: Will Wright, RMIT

Xie said their smart algorithm enabled control over how the structure behaved under forces by changing the tube orientations.

“With our origami-inspired innovation, flat-pack tubes are not only easy to transport, but they also become strong enough to withstand external forces when in use,” Xie said.

“The tube is also self-locking, meaning its strong shape is securely locked in place without the need for extra mechanisms or human intervention.”

Members of the research team, (left to right) Ngoc San Ha, Jiaming Ma, Mike Xie, Jeff Lee and Hongjia Lu at RMIT University's Bundoora East campus. Credit: Will Wright, RMIT

Members of the research team, (left to right) Ngoc San Ha, Jiaming Ma, Mike Xie, Jeff Lee and Hongjia Lu at RMIT University’s Bundoora East campus. Credit: Will Wright, RMIT

Next steps

The team will continue to improve the design and explore new possibilities for its development.

“We aim to extend the self-locking feature to different tube shapes and test how the tubes perform under various forces, such as bending and twisting,” Lee said.

“We are also exploring new materials and manufacturing methods to create smaller, more precise tubes.”

Associate Professor Joseph Gattas from the University of Queensland collaborated with the RMIT team. Credit: Supplied

Associate Professor Joseph Gattas from the University of Queensland collaborated with the RMIT team. Credit: Supplied

The team is developing tubes that can deploy themselves for a range of applications without needing much manual effort.

“We plan to improve our smart algorithm to make the tubes even more adaptable and efficient for different real-world situations,” Xie said.

Self-locking and stiffening deployable tubular structures‘ is published in the PNAS journal (DOI: 10.1073/pnas.2409062121).

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