Tuesday, August 5, 2014

Awesome buildings

During semester  break, I had seen some awesome and amazing building through websites and also magazine.

Nine Bridges Country Club-Clubhouse
The Nine Bridges Country Club-Clubhouse is a 16,000-square meter facility that serves a golf course. It has an underground level and three floors above grade. There is a main building, VIP lobby building, and a structure with private suites. The atrium and the upper portion of the main building include timber columns and a glass curtain wall, while the base is made of stone (random rubble masonry typical of Korea). The timber area includes the reception zone, a member’s lounge, and a party room. The stone podium houses locker rooms, bathrooms, and service areas. The roof over the main building measures 36 x 72 meters. The unusual tree-like timber columns in the atrium reach to a height of three stories. The partial-timber structure was used to conform to Korean regulations that do not allow timber buildings to exceed 6 000 square meters in size. The first floor of the atrium has 4.5-meter-wide glass shutters that open fully." - Shigeru Ban




Pompidou Center 
This annex for the Pompidou Center in Paris, is to be built in Metz as a complex including an art museum and theater. By locating a large roof in the park, and by opening the glass shutter façade around the perimeter, a continuous transition of the interior and exterior space is created. The roof is made from laminated wood in a hexagonal woven pattern composed in the form of a Chinese bamboo-woven hat. This large wooden roof is covered in a Teflon-coated fiberglass membrane and allows soft natural light to filter into the interior. The main galleries are a series of 90mx15m cantilevering rectilinear tubes that float above the ground, and their glass window ends direction of the cathedral and other monuments of the city."



Japan Pavilion EXPO 2000 HANNOVER 

Despite construction problems, the abrupt replacement of the engineer, months long construction delays, and the necessary addition of a PVC membrane over the paper membrane for FIRE SAFETY issues, the Pavilions has been a great leap forward in the field of paper architecture. The main theme of the Hanover Expo was the environment and the basic concept behind the Japan Pavilion was to create a structure that would produce as little industrial waste as possible when it was dismantled. The goal was either to recycle or reuse almost all of the materials that went into the building. The first structural idea was for a tunnel arch of paper tubes, similar to the Paper Dome. However, the Paper Dome was limited by the high cost of wooden joints. I proposed a grid shell using lengthy paper tubing and without joints to my collaborator, Frei Otto. The tunnel arch would be about 73.8m long, 25m wide, and 15.9m high. The most critical factor was lateral strain along the long side, so instead of a simple arch I chose a grid shell of three-dimensional curved lines with indentations in the height and width directions, which are stronger when it comes to lateral strain.
Another goal was to construct the pavilion using methods that were as low-tech as possible, so they argued for simple joints of fabric or metal tape. As the intersection between two paper tubes was pushed up to form the three-dimensional grid, an angle would open and a suitable amount of tension would be applied. Further, since the paper tubes themselves would rotate to draw a gentle S curve, the joint would allow for three-dimensional movement. Tape was an appropriate solution. Otto also proposed a fixed timber frame of ladder arches and intersecting rafters which would lend strength to the paper-tube grid shell and allow a roof membrane to be attached, and which could also be used during construction and for maintenance. The Buro Happold, who supervised construction, proposed metal joints into which bracing cables would be inserted at a diagonal to tension the paper-tube grid while allowing the paper tubes to move in three dimensions. However, the PVC used in conventional membranes cannot be recycled and gives off dioxins when burned. Then we discovered by chance a waterproof bag used by a delivery service. We talked to the manufacturer of the bag, who told us it might be possible to develop something like what we needed. The two semicircular end walls needed planar strength as diaphragms. For these we used timber arches that clamped the ends of the paper-tube grid shell, and then achieved the required planar strength by pulling cables in a 60-degree from the foundation, as in a tennis racquet. On this surface we attached a grid of paper honey-combs in the shape of equilateral triangles, to which were attached louvers for ventilation and the membrane. Instead of relying on concrete the foundation consists of boxes made of a steel framework and footing boards, which were filled with sand for easy reuse after dismantling.


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