"Rock Print" at the forefront of architectural innovation
Inspired to take 3D printing technology to new heights, ETH Zurich and MIT researchers create "Rock Print" a full-scale architectural installation for the Chicago Architecture Biennial.
Standing over 13 feet (4 metres) high in the Chicago Cultural Center, the monolithic Rock Print installation with its rough, yet elegant contours confirms that collaboration inspires "State of the Art Architecture" – the theme of the inaugural external pageChicago Architecture Biennial. Born out of a 2012 University of Chicago conference that brought architects, engineers, material scientists, and physicists together, Rock Print demonstrates a principle called, "jamming." Jamming refers to aggregate granular materials, like gravel that are quite literally crammed together in such a way that they hold their form and shape like a solid even though their molecular properties are closer, in terms of behaviour, to a liquid substance. "Jamming" together, researchers from Gramazio Kohler Research, ETH Zurich and external pageSkylar Tibbits' Self-Assembly Lab at the Massachusetts Institute of Technology (MIT) produced, Rock Print – a zero waste and fully reversible architectural installation for the inauguration of the Chicago Architecture Biennial that opened on 3 October 2015.
Inspired by 3D print technology
"Rock Print is a proof of concept that takes current robotic fabrication technology and applies it to a full-scale architectural project," said Andreas Thoma, ETH Zurich. Petrus Aejmelaeus-Lindstroem, lead researcher for the project at ETH Zurich added, "The project shows the capacity of a 3D printing process to create a geometrically-complex construction using two simple components found in everyday life - string and rocks." The environmentally conscious ETH and MIT installation team used a custom robotic fabrication setup to lay down nearly 5 miles (9.1 km) of a recycled textile string in a complex pattern guided by a specifically designed algorithm. Like making lasagne, the string is alternated with layers of a loose standard concrete aggregate (rocks) from the Swiss company, external pageMisapor. The company makes self-insulating concrete using crushed glass, additives, and a heating process that expands the glass into a foam-like aggregate of mostly air. While the foam glass is a fraction of the weight of conventional gravel aggregate, Rock Print weighs in at slightly less than one tonne (970 kg to be exact). The weight is a delicate balance – a lighter weight material is necessary for an indoor installation, but the structure of the installation depends on weight to provide strength to the compressional forces that maintain its shape and to compensate for the relatively weak tensional forces.
New possibilities for the future of architecture
Matthias Kohler, who also serves as the Director of the National Competence Centre in Research (NCCR) Digital Fabrication, commented on how 3D printing technology may influence architecture in the future stating, "3D printing technology is an inspiration for the future of architecture as it brings together resource efficient additive building principles with new possibilities for design. Such technology enables production of complex forms and intricate details of building elements at a minimal cost. Today's commercially available 3D printing technologies are not yet suitable for the scale needed for architecture or its economic and structural demands."
The Rock Print installation challenges and expands the scope of 3D printing to an architectural scale by introducing robotic fabrication and the use of inexpensive, reconfigurable bulk construction materials. This radical approach attempts to open new possibilities for future architecture – using advanced digital fabrication technology to build with sustainable and locally available materials. Kohler says, "There is still a lot of interdisciplinary research needed to fully understand and leverage future digital fabrication principles at a full building scale, but after ten intensive years of research in the field, I am positive that such new principles will not only lead to exciting architecture projects, but also to a new digital building culture - possibly to a socially relevant transformation of our built environment."
Gramazio Kohler Research, ETH Zurich
The research group headed by Professors Fabio Gramazio and Matthias Kohler at ETH Zurich examines the changes in architectural production that result from the introduction of digital manufacturing techniques. The main focus is ground-breaking research into computational design, constructive systems and their synthesis through the use of novel robotic fabrication technologies. Lindstroem and Thoma indicated that Rock Print was made possible through the collaborative knowledge of architects, engineers, and computational physicists. Prof. Dr. Hans J. Herrmann and Dr. Falk Wittel from ETH Zurich's Institute for Building Materials and Prof. Dr. Heinrich Jaeger from the University of Chicago consulted on the project.
Rock Print project team and access to the media kit
Gramazio Kohler Research - Rock Print project page
Chicago Architecture Biennial 2015
Rock Print is on display throughout the biennial that runs through 3 January 2016 in the Chicago Cultural Center – the former public library across from the stunning Millennium Park in the heart of the city. Famous for its contemporary architecture and landmark skyscrapers, the external pageChicago Architecture Biennial celebrates with the theme, "State of the Art in Architecture" providing a platform for ground-breaking architectural projects and spatial experiments that demonstrate how creativity and innovation can radically transform our lived experience. It offers an opportunity to take stock of more than 70 architectural projects and experiments from 30 countries around the world. Rock Print represents the Swiss-US collaboration at the forefront of innovation in architecture.