The components are snapped together, Lego-like, onsite, then concreted into place. No metal is required. "This prevents corrosion, decreases the weight and simplifies the work time required," says Xavier Mas, from the Institute for Heritage Restoration (IRP) of the Polytechnic University of Valencia. And the finished beams weigh up to 80% less than standard reinforced concrete beams.
As for how they manage to get the requisite rigidity from plastic, the researchers looked to human bones for inspiration.
"It is an alveolar structure, which makes it possible to decrease the amount of plastic used – and therefore its weight – while maintaining structural rigidity," says José Ramón Albiol, lecturer at the Higher Technical School of Construction Engineering (ETSIE) of the UPV.
This alveolar structure was inspired by human bones around the epiphysis, where there is a layer of cancellous bone with a trabecular disposition – the alveolar structure – and a thicker external layer of compact bone. "This is what we have transferred to these revolutionary beams, specifically to their profiles. It is a very intelligent natural system and its reproduction in these beams awards them, with the low structural weight, very high mechanical capabilities," adds Albiol.
3D printing makes it possible to manufacture customised pieces very near the area of implementation, which also simplifies transportation, saves costs and facilitates customisation. "To be able to customise the beams in situ makes it possible to adapt the characteristics of each of them to the structural needs at each point of construction. The possibility to recycle polymeric materials to produce the beams significantly decreases their carbon footprint," concludes Miguel Sánchez, from the Department of Systems and Computer Science (DISCA) of the UPV.