Building with robots and 3D printers
At the Empa and Eawag NEST building in Dübendorf, eight ETH Zurich professors are collaborating with business partners to build the three-storey DFAB HOUSE. It is the first house in the world to be designed, planned and built using predominantly digital processes.
Robots that build walls, and 3D printers that print entire formworks for ceiling slabs – digital fabrication in architecture has developed rapidly in recent years. As part of the National Centre of Competence in Research (NCCR) Digital Fab-rication, architects, robotics specialists, materials scientists, structural engineers and sustainability experts from ETH Zurich have teamed up with business partners to bring several new digital building technologies from the laboratory into practice. Construction is taking place at NEST, the modular research and innovation building that Empa and Ea-wag built on their campus in Dübendorf to test new building and energy technologies under real-life conditions. NEST offers a central support structure with three open platforms, where individual construction projects – known as innova-tion units – can be installed. Construction recently began on the DFAB HOUSE.
Digitally designed, planned and built
The DFAB HOUSE is distinctive in that it was not only digitally designed and planned, but is also built using predomi-nantly digital processes. With this pilot project, the ETH professors want to examine how digital technologies can make construction more sustainable and efficient, and increase the design potential. The design and planning of individual components were digitally coordinated, and these are now manufactured directly on site according to this data. As a result, the conventional planning phase is no longer needed. As of summer 2018, the three-storey building, with a floor space of 200 m2, will serve as a residential and working space for Empa and Eawag guest researchers and part-ners of NEST.
Four new building methods put to the test
At the DFAB HOUSE, four construction methods are for the first time being transferred from research to architectural applications. Construction work began with the Mesh Mould technology, which received the Swiss Technology Award at the end of 2016; it was developed by an interdisciplinary team and could fundamentally alter future construction with concrete. Here, the two-metre high construction robot In situ Fabricator plays a central role; it moves autonomous-ly on caterpillar tracks even in a constantly changing environment. A steel wire mesh fabricated by the robot serves both as formwork and as reinforcement for the concrete. Thanks to the dense structure of the steel wire mesh and the special composition of the concrete mix, the concrete stays inside the grid and does not pour out.
The result is a double-curved, load-bearing wall that will characterise the architecture of the open-plan living and work-ing area on the ground floor. A Smart Slab will then be installed – a statically optimised and functionally integrated ceiling slab, the formwork of which was manufactured using a large-scale 3D sand printer.
Smart Dynamic Casting technology is being used for the fa?ade on the ground floor: the automated robotic slip-forming process can produce bespoke concrete fa?ade mullions. The two upper floors, with individual rooms, are being prefabricated at ETH Zurich’s Robotic Fabrication Laboratory using Spatial Timber Assemblies; cooperating robots will assemble the timber construction elements.
Comprehensive collaboration is the key to success
For ETH professor Matthias Kohler, founding director of the NCCR Digital Fabrication and the initiator of the DFAB HOUSE, it is also the variety of new construction technologies that makes it a flagship project for digital construction. “Unlike construction projects that use only a single digital building technology, such as 3D printed houses, the DFAB HOUSE brings a range of new digital building technologies together. This allows us to use the advantages of each individual method as well as their synergies, and express them architecturally,” says Kohler.
All the construction methods used in the DFAB HOUSE have been developed in recent years by the researchers of the ETH professorships involved, as part of the NCCR Digital Fabrication. The fact that these technologies have so quickly found their way to the construction site is the result of both intensive collaboration between the different scientific dis-ciplines and successful partnerships between research and industry. “We are convinced that this collaboration is worthwhile for both sides. An increasing number of Swiss companies, such as Erne AG Holzbau, which is the general contractor for the DFAB HOUSE and was previously involved in building the Arch_Tec_Lab at ETH Zurich, want to proactively use the opportunities of digital technologies – something that gives us great pleasure,” says Kohler.
From digital building to digital living
Digital technologies will also be used when the DFAB HOUSE is inhabited from summer 2018. Under the lead of digitalSTROM AG and in collaboration with several other Swiss companies, innovative smart home solutions and in-ternet of things technologies will be tested. This includes devices and systems that communicate intelligently with one another and are capable of learning, and which control the building in a way that improves both energy efficiency and comfort.
ETH professorships involved with the DFAB HOUSE
- Prof Matthias Kohler, Chair of Architecture and Digital Fabrication
- Prof Fabio Gramazio, Chair of Architecture and Digital Fabrication
- Prof Benjamin Dillenburger, Chair for Digital Building Technologies
- Prof Joseph Schwartz, Chair of Structural Design
- Prof Robert Flatt, Institute for Building Materials
- Prof Walter Kaufmann, Institute of Structural Engineering
- Prof Guillaume Habert, Institute of Construction & Infrastructure Management
- Prof Jonas Buchli, Institute of Robotics and Intelligent Systems
ETH Zurich at NEST
In addition to the DFAB HOUSE, ETH Zurich is also playing a leading role in another NEST unit: Professor Philippe Block and Professor Arno Schlüter’s groups at the Institute of Technology in Ar-chitecture are currently developing the HiLo unit, which combines ultra-light construction tech-niques for the floor and roof with an adaptive solar fa?ade. HiLo is designed to be an energy-plus building and is intended to produce 50 percent more power than it uses. Construc-tion is expected to begin early 2018. The external page Vision Wood unit, which explores future-oriented applications of wood as a natural resource for the construction sector, was also created with the participation of ETH re-searchers.