ETH Zürich’s high-tech showhome opened its doors this past week. The three-story DFAB HOUSE has been built on the NEST modular building platform, an Empa– and Eawag–led site of cutting-edge research and experimentation in architecture, engineering, and construction located in Dübendorf, Switzerland. The 2,150-square-foot house, a collaboration with university researchers and industry leaders, is designed to showcase robotics, 3-D printing, computational modeling, and other technologies and grapple with the interconnected issues of ecology, economy, and architecture. One of the central innovations is using robots that build onsite, rather than create prefabricated pieces in a factory. This In Situ Fabricator (IF) technology, an autonomous “context-aware mobile construction robot,” helps minimize waste and maximize safety during the construction process. To generate concrete geometries not permitted by conventional construction techniques, such as curvilinear shapes that minimize material use, researchers devised a Mesh Mould technology that was built with the aid of vision system–equipped robots. The robots fabricated a structure that acts as both formwork and structural support, a curved steel rebar mesh. The mesh is then filled with concrete, which it acts as a support to. In the DFAB HOUSE, the Mesh Mould is realized as a 39-foot wall, a main load-bearing component of the house, which is able to carry around 100 tons. Despite its complexity—it has 335 layers with over 20,000 welding points—the robot took just 125 hours to construct the mesh. https://youtu.be/ZeLEeY8yK2Y Cantilevered over the Mesh Mould is the so-called Smart Slab, a 3-D printed concrete formwork that supports the timber structure above. Many of the concrete forms in the home are built with what the researchers are calling Smart Dynamic Casting, an automated prefabrication technology. Robotic prefabrication is also used to make the Spatial Timber Assemblies that comprise the upper two levels of the home. The timber structure was devised as part of a collaboration between the university, Gramazio Kohler Research, and ERNE AG Holzbau, who used computational design to generate timber arrangements to fit into the larger structure. The timber assemblies also permit the creation of stiff structures that don’t require additional reinforcement. Applied onto the structure, the hyper-efficient facade is made of membranes of cables, translucent insulating Aerogel, and aluminum. In addition to all the new technology that went into building the DFAB HOUSE, it will also be a “smart home,” using what the researchers are calling the “digitalSTROM platform,” which includes “intelligent, multi-stage burglar protection, automated glare, and shading options, and the latest generation of networked, intelligent household appliances.” It also includes voice control for many of the home’s operations from turning on a kettle to operating blinds. Energy management is also a centerpiece of the home, with rooftop photovoltaic panels featuring a smart control system. Additionally, heat exchangers in the shower trays recover the warmth of shower water, and hot water from faucets is fed back into the boiler when it’s not in use. Not only does it conserve energy and water, it also prevents bacterial growth in the pipes. The radical use of technology in the DFAB HOUSE is also about optimization and efficiency: the home, with all its undulating formwork and translucent geometries, has been designed to demonstrate how new technology can develop and advance its own aesthetic language to make truly pleasing, compelling spaces. It will also be put to the test. Soon academic guests will be moving in and give life in the DFAB HOUSE a shot. For those who can’t make it to Switzerland, the project will also be presented during Swissnex in San Francisco.
Posts tagged with "ETH Zurich University":
Global construction continues to steam ahead, even while seemingly mundane building materials (like sand) become rarer and more precious, and construction industry's carbon dioxide emissions contribute to global climate change. The building industry seems to be demanding new solutions, but scalable alternatives remain scarce. Enter the Block Research Group at ETH Zurich. The group, which is based out of the Institute of Technology in Architecture at the Swiss school and is led by Philippe Block and Tom Van Mele, takes a “geometry-based approach” to assessing and attacking engineering problems using technology like algorithmic design and 3-D printing. Most recently, at ETH’s pavilion at the World Economic Forum, which took place earlier this winter in Davos, the group unveiled its solution to building in an age of tightening resources: a "functionally integrated funicular floor." The flooring solution builds on the group's rib-stiffened funicular slab system, which was inspired by tile vaulting and was on display at the Beyond Bending exhibition at the 2016 Venice Architecture Biennale. It relies on doubly-curved shells to bear loads and uses up to 70 percent less concrete than typical construction methods. The structure also minimizes stress even in the thinnest areas, making it possible to build with weaker materials, like recycled concrete, which the lab is currently using. It also permits space to embed pipes, wires, and mechanical systems in space created in the floor. Currently, the lab is collaborating with the Architecture and Building Systems lab at the university to see if HVAC systems can be placed within the flooring. https://vimeo.com/312082531 However, despite its significantly decreased use of concrete, the complex geometry could make for expensive and wasteful formworks, which themselves require intensive labor to build and remove. The Block Research Group is also collaborating with the Digital Buildings Technology lab to investigate the use of 3-D printing to mitigate these challenges. This year, the research group is gearing up to use its new floor system and other technologies in the ongoing experimental NEST HiLo (high performance, low energy) project, a prototype two-bedroom apartment for ETH visiting faculty that features an array of cutting-edge construction and environmentally conscious technologies, being constructed in Dübendorf, Switzerland.
Located in Mexico City’s Museo Universitario Arte Contemporaneo, KnitCandela is a 13-foot-tall curved concrete shell formed with a 3-D-knitted framework. The sculptural project is a collaboration between Zaha Hadid Architects' Computation and Design Group (ZHCODE), ETH Zurich’s Block Research Group (BRG) led by Philippe Block and Tom Van Mele with PhD student Mariana Popescu, and Mexico’s Architecture Extrapolated who managed the on-site execution of the project. Named in homage to the concrete-bending designs of architect and structural engineer Félix Candela, the pavilion rests on three parabolic arches, with interior threadwork fashioned to resemble traditional garb found in the federal state of Jalisco, 340 miles northwest of the country’s capital. The pavilion is an outdoor feature of the museum's new exhibition, Design as Second Nature, featuring four decades of Zaha Hadid Architects' (ZHA) research into construction technology and design innovation. The project builds upon ETH Zurich's numerous recent forays into lightweight concrete structures based on curved geometries and digitally designed formwork. Currently, the university is leading KnitCrete, a partnership with the Swiss National Centre for Competence in Research in Digital Fabrication, to boost the technological expertise and production of hybrid and ultra-lightweight concrete structures. Past projects include an experimental concrete roof cast on 3-D printed sand formwork and an ultralight roof cap composed of a polymer textile and a network of steel cables. According to ETH Zurich, Block and Van Mele’s research group plugged a digitally generated pattern into an industrial knitting machine to produce the formwork. Over the course of 36 hours, the flat-bedded mechanism knitted over 200 miles of polyester yarn into four 3-D double-layered strips. To suspend the canopy, the upper layer of the textile bears a series of sleeves for the insertion of supporting cables. Additionally, the woven formwork integrated 1,000 inflatable modeling balloons that were transformed into waffle shell-like voids following the initial coating of concrete. The entire woven assembly, weighing a meager 55 pounds, was transported to the location via two suitcases stowed as normal checked baggage. Once onsite, the double-layered textile was tensioned between a steel-and-wood boundary frame and subjected to an initial millimeters-thick concrete coating. After hardening and the creation of a lightweight mold, the team poured five tons of fiber-reinforced concrete over the original 120-pound polyester-and-cable framework. The pavilion will remain in place until March 3, 2019.
The Center for Architecture is collaborating with the Swiss Consulate in New York City, ETH Zurich, and ETH's Singapore outpost to put on a two-day Responsive Cities conference. The first day will focus on “citizen engagement,” that is, how smart cities can be developed with input from their inhabitants from the very beginning of the planning process. Speakers based in New York and Singapore, including Fabien Clavier, Kubi Ackerman, and Mike Aziz, will speak on how technology, data science, and fields like cognitive psychology can be leveraged in making future cities that adapt to the demands of individuals and communities. The second day will be dedicated to the increasingly important problem of rising urban temperatures being brought on by densification, population growth, and global climate change, among other factors. Speakers with backgrounds in everything from urban ecology to policy and law will discuss ways to cool warming cities for a livable future. The conference is free and begins tonight at the Center for Architecture and will continue tomorrow evening at the New School’s John L. Tishman Auditorium.
A research team led by Jamin Dillenburger, an assistant professor at ETH Zurich, has recently produced and installed a concrete ceiling shaped by 3D-printed sand formwork. Dubbed the “Smart Slab,” the 1000 square-foot ceiling is significantly lighter and thinner than comparable concrete ceilings. The concrete slab is a component of ETH Zurich’s ongoing DFAB House project. The DFAB House is a load-bearing timber module prefabricated by robots. According to ETH Zurich, Dillenburger’s research group “developed a new software to fabricate the formwork elements, which is able to record and coordinate all parameters relevant to production.” In effect, the design of the ceiling is the product of the team-created software rather than analog design or planning. Following the design and digital testing phase of structural elements, the fabrication data was exported for the creation of 11 pallet-sized, 3D-printed sand formworks. After fabrication, each segment was cleared of sand particles and prepared for concrete spraying. The spray consisted of several layers of glass-fiber reinforced concrete. At its thinnest point, the concrete shell is less than one inch thick. After hardening for two weeks, the 11 concrete segments were joined to create the approximately 15-ton floor plate. While the underbelly’s contours were formed by 3D-printed sand casts, the ribbed grid above was shaped by CNC laser-cut timber formwork. The load-bearing ribs, resulting from timber formwork, were outfitted with a series of tubes for the insertion of steel cables both horizontally and vertically. These post-tensioned ribs carry the principal load of the “Smart Slab.” In placing the principal load above the concrete shell, the research team was able to insert complex geometric features below. The “Smart Slab” is not ETH Zurich’s first execution of an ultrathin concrete unit. Earlier this year, the university fabricated an undulating, two-inch thick roofing unit for a new live-work space in Zurich.
Researchers at the Swiss Federal Institute of Technology (ETH) in Zurich, Switzerland, are giving timber construction a mechanical leg up with the introduction of prefabricated, robotically-assembled timber frame housing. Together with Erne AG Holzbau, a contracting firm that specializes in timber, researchers at the institute’s Chair of Architecture and Digital Fabrication have developed Spatial Timber Assemblies, a system for digitally fabricating and constructing complex forms from timber. After a model of the structure has been laid out, robotic arms mounted in the ceiling of the assembly chamber are capable of building the required parts as well as putting them together. First, one arm picks up a beam and holds it while a human trims the piece into the proper size and shape. Then, a second robot arm pre-drills the holes needed for attaching the beam to the structure; finally, both robot arms work together to precisely place the beam as a human attaches it. Thanks to algorithms developed by the researchers, the arms are able to constantly recalculate their location in space and how to move forward without bumping into each other (or humans on the job site). A major advantage of Spatial Timber Assemblies is that the structures built this way carry their load-bearing capacity structurally, and don’t require reinforcing plates or any additional steel. If the overall design changes during construction, researchers are able to calculate a new, optimized framing solution using load-distribution algorithms. The system is more than theoretical. ETH researchers are currently using it to assemble six unique modules, which will join to frame the top two floors of the experimental DFAB HOUSE in Dübendorf, a suburb of Zurich. Once installed on site, both floors will have distinct rooms across 328 square feet of floor space. The final design, which uses 487 individual beams, will be wrapped in a clear plastic facade so that the underlying timber structure can remain exposed. Advancements in robotic construction are advancing rapidly, and ETH researchers have been developing robots that weld, spray concrete, and stack bricks to create forms that would have been difficult to build previously. And if the ETH needs help decorating the interior of their research house, robots can now assemble IKEA furniture, too.
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A full-scale prototype of the design was the culmination of a four-year research project by ETH Zürich, and now the thin-shell integrated system's concrete roof is under construction. The razor-thin assembly, built over the course of six months, tapers to an impressive one-inch thickness at the perimeter, averaging two inches thick across its more than 1,700 square feet of surface area. The ongoing project, sponsored by ETH Zürich, NCCR Digital Fabrication, and Holcim Schweiz, will lead to the completion of a rooftop apartment unit called HiLo, which will offer live-work space for guest faculty of Empa, the Swiss Federal Laboratories for Materials Science and Technology. The rooftop structure rises about 24 feet high, encompassing 1,300 square feet. Innovations in thin-shell building techniques were explored by the Block Research Group, led by Professor Block and senior researcher Dr. Tom Van Mele, together with the architecture office supermanoeuvre. The team purposefully avoided wasteful non-reusable formwork, opting instead to develop a net of steel cables stretched into a reusable scaffolding structure. The cable net supported a polymer textile that forms the shell surface. According to ETH Zurich press release, “this not only enabled the researchers to save a great deal on material for construction, they were also able to provide a solution to efficiently realise completely new kinds of design.” The construction technique leaves the interior floor area below the roof relatively unobstructed, allowing interior construction work to proceed concurrently. Altogether, this method is expected to condense construction to eight to ten weeks. Block Research Group and NCCR Digital Fabrication were able to digitally model dynamic forces wet concrete applies to the lightweight cable net and textile formwork, so that the overall geometry and structuring of the surface can be calibrated to produce an accurate result. This level of optimization is perhaps most evident in the capacity of the reusable formwork system to hold around 25 times its own weight (20 tons of wet concrete will eventually load onto the formwork).Experts from Bürgin Creations and Marti sprayed the concrete using a method developed specifically for this purpose, ensuring that the textile could withstand the pressure at all times. Together with Holcim Schweiz, the scientists determined the correct concrete mix, which had to be fluid enough to be sprayed and vibrated yet viscous enough to not flow off the fabric shuttering, even in the vertical spots. The innovative concrete structure offers more than a new method for constructing concrete shell structures: it’s aim is to be an intelligent, lightweight energy-producing system. This is achieved by careful assembly of multiple layers of building systems. Two layers of concrete sandwich together insulation, heating and cooling coils, while thin-film photovoltaic cells wrap the exterior surface. The residential unit, enclosed by this roof system, and an adaptive solar-shaded facade, is expected to generate more energy than it consumes. “We’ve shown that it’s possible to build an exciting thin concrete shell structure using a lightweight, flexible formwork, thus demonstrating that complex concrete structures can be formed without wasting large amounts of material for their construction” said Block in a press release. Because we developed the system and built the prototype step by step with our partners from industry, we now know that our approach will work at the NEST construction site.” You can view progress at the Dübendorf, Switzerland construction site via live webcam, accessed here.
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A research project explores techniques from the past to learn about building stronger structures in the futureSometimes research involves destruction in the name of creation. Architects and engineers from Zurich-based BLOCK Research Group at science and technology university ETH Zurich recently teamed up to build, and destroy, a vaulted masonry structure that was designed with advanced digital fabrication methods but constructed with traditional timbrel, or Catalan, thin-tile vaulting techniques. Through its research of freeform shells, tiling patterns, building sequences, and formwork, the group hopes to construct increasingly radical forms without sacrificing efficiency. Now rarely used, centuries-old timbrel vaulting methods were commonly employed in Spanish architecture and in many Beaux Arts landmarks. The form is known in the United States as a Guastavino vault after the Spanish architect Rafael Guastavino, who patented a version of the system in 1885. Traditionally, the vaults’ structural form followed a lightweight wooden structure that would guide the mason as he placed tiles. Using Thrust Network Analysis (TNA), a new form-finding method, the BLOCK group has created new possibilities for freeform vaulted shapes that can be constructed using a continuous cardboard formwork system. After creating irregular geometries with TNA, the researchers establish the shape of edge arches, close in the adjacent surfaces, breaking the pattern with a groin vault to begin another arch section. The group also aims to show that recyclable and reusable cardboard formwork could dramatically reduce the material and labor costs of construction while making complex vaults possible. Fabricated with a 2-D CAD-CAM cutting and gluing process and assembled on site, the formwork for the group’s Catalan prototype was supported by a system of stacked shipping pallets. These reduced the amount of cardboard used and allowed the unrolled cardboard pattern to fit the CNC equipment’s size requirements. The team implemented custom RhinoScripts to translate the self-supporting vault surface into machine code to produce 200 cardboard boxes. The group also discusses techniques for cutting tiles to be used in the prototype vault in its research paper, available here: “The most ideal cutting logic for the high double-curvature of the prototype vault would be a two-cut system, employing a combination of oblique and bevel cuts to ‘bend’ a surface in space.” Because of the tool constraints on this project, the team developed a simplified version of the cutting system that allowed for curvature in one axis of the tile while relying on hinging and the mortar joint to achieve a double curvature. Removing the formwork from the surface of the shell, also called de-centering, was another critical step. The supporting structure had to be removed all at once to avoid asymmetrical loading from below, which could cause the vault to bend and crack. In order to allow the formwork to lower slowly from the masonry surface, the frame sat on a series of sealed plastic tubes containing cardboard spacers consisting of a folded stack of cardboard sheets taped together. The team calculated the dry compressive strength of the spacers to carry the load of the shell, the pallet and box framework, and the masons. But once the vault was complete, the tubes were filled with water, which saturated the cardboard and caused it to compress under the load of shipping pallets. After successfully de-centering the structure, the team tested its strength, adding more than three pallets of sandbags to its surface before it finally collapsed. BLOCK’s future work will seek to streamline the TNA form-finding process as well as improve the efficiency of its construction techniques, ultimately working to identify design criteria like maximum vault curvatures with a range of tile sizes and patterns.