Aleusia Inc.

Fifteen years ago, it would have been difficult and in some cases impossible to engineer the buildings in these pages. Now ­powerful computer-assisted design and manufacturing techniques let ­architects build according to wholly new geometries. In this era, the ­rectilinear glass box has become a quaint relic of the predigital past.

Phaeno Science
Wolfsburg, Germany, 2005

Credit: Werner Huthmacher / Zaha Hadid

Most of the Phaeno Science Center's weight rests on a series of scattered concrete cones that seamlessly taper down from the building's underbelly. But the cones are not only structural supports: they also house a bookstore, a theater, and the museum's entrance. Computers configured the exact cone placement necessary for the curvaceous design to work, and a new material called self-compacting concrete filled it out. It is the only concrete capable of sustaining a structure with such sweeping curves and tight angles.

Hearst Tower
New York, NY, 2006

Credit: Chuck Choi / Arcaid / Corbis

The Hearst Tower's triangular frames, known as diagrids, eliminate the need for any vertical steel columns around the building's perimeter. It is the first building in North America to feature this ­gravity-­defying technique. So efficient is Foster's design that the building uses 20 percent less steel tonnage than a conventional building of its size.

Turning Torso
Malmö, Sweden, 2005

From top to bottom, Calatrava's anthropomorphic apartment tower twists 90º. The building was constructed by stacking nine warped cubes, each five stories high, on top of each other; each cube rotates about 11º from the one below it. An external spine buttresses the twist, mimicking a human spinal column, while an exoskeleton sprouts from the spine to provide wind resistance and damp the building's vibrations.

30 St. Mary Axe, "The Gherkin"
London, England, 2004

Credit: Grant Smith / View / Estostock

The pickle-shaped 30 St. Mary Axe owes its bulging and tapering structure to a diagrid steel framework like that of the Hearst Tower, which allows the perimeter to remain column-free. Its aerodynamic profile reduces wind load and creates a difference in air pressure between the inside and outside that draws cooler outdoor air in through panels in the façade. Thanks to this and other features, like abundant natural light, the building consumes as little as half as much energy as other office buildings its size.

Chesa Futura
St. Moritz, Switzerland, 2002

Credit: Foster + Partners

From digital design specs, the timbers for this pumpkinlike apartment building were cut and carved by a fully automated "computer numerical-control" machine called a Lignamatic, which may have been the first timber-processing unit of its kind. Twenty tools descended from racks in a prescribed order to cut, drill, rout, or bore pieces of timber up to 40 meters long, at any angle and with any curvature.

The National Assembly for Wales
Cardiff, Wales, 2005

Credit: Redshift Photography, Rogers Stirk + Partners

Undulating like a shaken carpet, the curvilinear red-cedar underside of the Assembly's roof is so geometrically complex and delicate that it could be realized only with 3-D modeling and visualization techniques. From the front of the building, the roof appears to float upon a single slate plinth, an illusion made possible by thin steel mullions in the façade, minimal steel columns around the perimeter, and tensioned stability ties from the ground to the roof.

Tenerife Opera House
Tenerife, Canary Islands, 2006

Credit: Alan Karchmer / Estostock

Computer-assisted 3-D modeling translated Calatrava's drawings for the 50-meter-high cantilevered wave and perfected the acoustics for the performance space within.

source : Technology Review

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