flexiblefullpage
billboard
interstitial1
catfish1
Currently Reading

How to make a ‘pure’ glass sphere

Energy-Efficient Design

How to make a ‘pure’ glass sphere

Creating a 25-story energy-generating globe for Expo 2017 in Kazakhstan put Adrian Smith + Gordon Gill Architecture to the test.


By Robert Cassidy, Executive Editor | February 18, 2016

The Kazakhstan Pavilion, designed by Adrian Smith + Gordon Gill Architecture, shows the wind-turbine cutout at the top of the sphere. Rendering courtesy AS+GG.

Take a sheet of copy paper and grip it flat in your hands. Next, gently push down evenly on both sides to form a smooth curve. Now, twist your left thumb up and your right thumb down. Ta-da! You have created a double-curved surface.

What seems easy to do with paper is not easy to do with glass, especially if you want to integrate photovoltaics into the assembly.

That was the problem that a team from Adrian Smith + Gordon Gill Architecture faced in designing the main exhibition hall for Expo 2017 in Astana, the capital of Kazakhstan. Nursultan Nazerbayev, the country’s president (since 1990), wanted a monumental glass sphere at the center of the 430-acre exhibit grounds to symbolize to the world that his country, while rich in oil (30 billion bbl in reserves) and uranium (it’s the world’s top producer), was leading the way to a post-carbon future. The sphere would live on as a science and technology museum, a reminder to generations to come that this was the site where “Future Energy”—the Expo’s theme—originated.

In the 2013 competition for Expo 2017, other firms submitted proposals for temporary exhibit buildings that would be demolished after the fair. The AS+GG team (led by partners Adrian Smith, FAIA, Gordon Gill, FAIA, and Robert Forest, FAIA, LEED AP, and Director Alejandro Stochetti, AIA, LEED AP) saw the Expo as a catalyst for a new way of thinking about urban life and sustainable environment in this former Soviet bloc country.

 

A construction photo shows the progress on the sphere as of mid-January. Photo: Kiril Petrovsky.

 

Houston on the Steppes

Founded in 1830, Astana became the capital of Kazakhstan in 1997. Replete with government buildings (Parliament House, the Supreme Court, Ak Orda Presidential Palace), Nazerbayev University, and a modernist downtown marked by the 100-meter Kazakh Eli (“golden bird”) tower, Kazakhstan’s second-largest city (population 875,000) is “monumental but not very well planned for people, walkability, or human scale,” said AS+GG Project Manager Matt Dumich, AIA.

In their proposal, AS+GG emphasized the long-term potential of the three-month-long Expo. Phase 1 delineated the Expo’s site plan and buildings: the 3,000-person Congress Center; the hotel, amphitheatre, and central utility plant; four thematic pavilions, each devoted to a specific aspect of “Future Energy”; and art and performance spaces. Phase 2 encompassed their “legacy” as a “Third Industrial Revolution City,” borrowing Jeremy Rifkin’s term. The entire infrastructure would have new life after the Expo.

Parking and service areas would be converted to vibrant residential neighborhoods housing 4,000 families. The new community would be linked to downtown via buffered walkways. (Astana is the second-coldest capital city in the world, after Ulaanbaatar, Mongolia. The temperature can dip to -40˚C in winter.)

Exposition halls would be engineered to allow for an interstitial floor to be inserted post-Expo. This would make them functional as office spaces for high-tech companies and as science/R&D labs for the adjacent university. “The dean told us that having this technology hub would make it much easier for them to recruit students from Russia and the region,” said Stochetti.

The team took “Future Energy” to heart. As Senior Designer Anthony Viola, LEED AP, put it, “How could we reduce energy use in the buildings as much as possible, using the buildings themselves to contribute to passive strategies, before applying renewable systems to generate energy?”

The Minister of Environment Protection, Nurlan Kapparov, championed the AS+GG entry. “He saw this project as a prototype for the rest of the city,” said Dumich.

In October 2014, AS+GG beat out such heavy hitters as Coop Himmelb(l)au, HOK, Snøhetta, UNStudio, and Zaha Hadid Architects. As he accompanied the winning team to the airport for their flight, Kapparov mentioned that President Nazerbayev loved their proposal—but the Kazakhstan Pavilion would have to be a sphere.

 

Forming a single-curved piece of glass with integrated PVs (above left) proved feasible, but bending glass containing integrated PVs to form a double curve (above right) turned out to be impractical.

 

Making a ‘Smooth’ Sphere

In their submission, the AS+GG team proposed a main pavilion that resembled a giant yurt—the traditional nomadic tent of the region. Now they had to figure out how to build a sphere that conformed to the principles that had won them the competition.

One thing they didn’t want to do was design another flat-panel, geodesic dome. “We wanted a pure sphere, a smooth sphere—not faceted. It had to be fully curved,” said Stochetti. Each glass panel would have to be gently twisted and shaped in three dimensions. The sphere would also have to produce energy, which meant photovoltaics would have to be integrated into the glass.

AS+GG had used PV-integrated flat glass for the Federation of Korean Industries headquarters, in Seoul, and double-curved annealed glass—minus the PVs—for FKI’s adjacent conference center. But no one had integrated PVs into double-curved glass.

Over the course of a whirlwind 10-day tour of glass fabricators in 10 cities across Europe, the team got a crash course in why it is so difficult to do so.

One fabricator showed them a process in which PVs can be installed along with a polyvinyl butyral interlayer between two sheets of single-curved glass. Heat and pressure are applied to the materials to form a laminated unit. But because PVs are essentially black, they get hot when exposed to the sun and need to be installed in tempered glass. Otherwise, said Stochetti, “the heat differential between the glass in the PV area and the transparent area can shatter the glass.” Several fabricators were capable of producing single–curved tempered glass, but double–curved tempered glass has to be chemically strengthened.

Another fabricator said they could curve the tempered glass in one direction and force the second curvature through cold bending. “This would have been an easier option, but it would require the edges to be held by a continuous metal cap,” said Stochetti. “If you do that, you won’t see a smooth sphere.” Scratch that idea.

Two fabricators—Barcelona-based Cricursa, fabricator of the double-curved glass for the FKI convention center, and Sunglass srl, Padua, Italy—could make double-curved glass. The glass is heated in special ovens until the material is soft enough to take the form of a mold laying in the oven. Then the glass is cooled very slowly. The procedure, which can take 13-20 hours, yields double–curved annealed glass. But if you want to integrate PVs in annealed glass, you have to subject the assembly to a highly specialized chemical strengthening process that tempers it. Not an option.

Cricursa introduced them to a new technology that uses PV “beads” to form a frit-like surface on the glass. They determined that this method, while potentially reducing thermal stress, was still experimental. “We couldn’t wait for the technology to be commercially available at the scale we needed and still be on time,” said Stochetti.

 

A crew from general contractor Sembol Construction, Ankara, Turkey, at work on the Kazakhstan Pavilion. Temperatures in Astana, the second-coldest capital city in the world, can reach -40˚C. Photo: Kiril Petrovsky.

 

Seeking Another Option

Their choices were starting to narrow. Should they ditch the dream of a “smooth” sphere and compromise on flat or single-curved glass with integrated PVs? That would look like Epcot Center redux. Should they forget about integrated PVs? How, then, would they meet the renewable energy goals for the pavilion? If not PVs, then what?

Well, what about wind? Could Astana’s steady, if brutal, southwest winds be turned into an asset? The AS+GG team turned once again to old friends at RWDI Consulting Engineers, Guelph, Ont., for their expertise in wind engineering and asked: Could the Kazakhstan Pavilion be transfigured into a giant wind-energy machine?

Maybe, replied the RWDI experts. The combined design team decided to test the idea of performing a kind of lobotomy on the sphere: By scooping out a gouge at the very top, wind could enter a channel on the interior skin, where it would be directed to energy-generating turbines.

“The wind studies were directed at finding out how much energy we could generate while balancing overall energy usage over a 40-year period,” said Viola. There were
tradeoffs. “If you add the cutout, you increase the surface area. In a place like Kazakhstan, every square meter you add to the exposed surface has the potential for a lot of thermal loss that can increase energy demand.” The cutout would also add to the cost of materials, total embodied energy, and construction time—all factors that had to be weighed in the modeling.

After numerous studies—a grinning Stochetti told me it seemed like “15 million” of them—AS+GG and RWDI optimized the shape for the cutout on the 25-story globe. They were even able to integrate PVs on the portion of the wind cutout with direct solar radiation, where flat or single-curved glass panels (with PVs) could be employed.

AS+GG delivered final documents to the general contractor, Sembol Construction, Ankara, Turkey, last March. As of mid-January, the structural steel frame was nearly topped out. The Expo buildings are all but fully clad in building integrated PVs.

Meanwhile, Sunglass srl is busily churning out 2,675 double-curved panels, totaling 18,225 sm. Because there are no PVs in the panels, Sunglass is fritting them to provide interior shading for visitors to the pavilion.

Not every detail of AS+GG’s master plan made the final cut. A pedestrian bridge over the highway between the site and the university will become a tunnel—not such a bad thing, considering the climate. The PV-clad residential buildings, rather than being oriented toward the southwest per AS+GG’s plan, have been sited on a rectilinear grid that reduces their ability to catch the sun’s rays.

So far, 60 countries (but not the U.S.) have pledged to exhibit. The doors open June 10, 2017, for three months.

Look for the sphere. You can’t miss it: it’s over 80 meters high.

 

Astana Expo City 2017, site of the “Future Energy” world’s fair in the capital of Kazakhstan. Rendering courtesy AS+GG.

Related Stories

| Oct 12, 2010

University of Toledo, Memorial Field House

27th Annual Reconstruction Awards—Silver Award. Memorial Field House, once the lovely Collegiate Gothic (ca. 1933) centerpiece (along with neighboring University Hall) of the University of Toledo campus, took its share of abuse after a new athletic arena made it redundant, in 1976. The ultimate insult occurred when the ROTC used it as a paintball venue.

| Oct 12, 2010

Owen Hall, Michigan State University, East Lansing, Mich.

27th Annual Reconstruction Awards—Silver Award. Officials at Michigan State University’s East Lansing Campus were concerned that Owen Hall, a mid-20th-century residence facility, was no longer attracting much interest from its target audience, graduate and international students.

| Oct 12, 2010

Cell and Genome Sciences Building, Farmington, Conn.

27th Annual Reconstruction Awards—Silver Award. Administrators at the University of Connecticut Health Center in Farmington didn’t think much of the 1970s building they planned to turn into the school’s Cell and Genome Sciences Building. It’s not that the former toxicology research facility was in such terrible shape, but the 117,800-sf structure had almost no windows and its interior was dark and chopped up.

| Oct 12, 2010

The Watch Factory, Waltham, Mass.

27th Annual Reconstruction Awards — Gold Award. When the Boston Watch Company opened its factory in 1854 on the banks of the Charles River in Waltham, Mass., the area was far enough away from the dust, dirt, and grime of Boston to safely assemble delicate watch parts.

| Oct 12, 2010

Building 13 Naval Station, Great Lakes, Ill.

27th Annual Reconstruction Awards—Gold Award. Designed by Chicago architect Jarvis Hunt and constructed in 1903, Building 13 is one of 39 structures within the Great Lakes Historic District at Naval Station Great Lakes, Ill.

| Oct 12, 2010

Full Steam Ahead for Sustainable Power Plant

An innovative restoration turns a historic but inoperable coal-burning steam plant into a modern, energy-efficient marvel at Duke University.

| Oct 12, 2010

From ‘Plain Box’ to Community Asset

The Mid-Ohio Foodbank helps provide 55,000 meals a day to the hungry. Who would guess that it was once a nondescript mattress factory?

| Oct 11, 2010

HGA wins 25-Year Award from AIA Minnesota

HGA Architects and Engineers won a 25-Year Award from AIA Minnesota for the Willow Lake Laboratory.

| Oct 11, 2010

Rhode Island is the first state to adopt IGCC

Rhode Island is the first state to adopt the International Green Construction Code (IGCC). The Rhode Island Green Buildings Act identifies the IGCC as an equivalent standard in compliance with requirements that all public agency major facility projects be designed and constructed as green buildings. The Rules and Regulations to implement the Act take effect in October 2010.

| Oct 8, 2010

Union Bank’S San Diego HQ awarded LEED Gold

Union Bank’s San Diego headquarters building located at 530 B Street has been awarded LEED Gold certification from the Green Building Certification Institute under the standards established by the U.S. Green Building Council.  Gold status was awarded to six buildings across the United States in the most recent certification and Union Bank’s San Diego headquarters building is one of only two in California.

boombox1
boombox2
native1

More In Category


Sustainable Design and Construction

Northglenn, a Denver suburb, opens a net zero, all-electric city hall with a mass timber structure

Northglenn, Colo., a Denver suburb, has opened the new Northglenn City Hall—a net zero, fully electric building with a mass timber structure. The 32,600-sf, $33.7 million building houses 60 city staffers. Designed by Anderson Mason Dale Architects, Northglenn City Hall is set to become the first municipal building in Colorado, and one of the first in the country, to achieve the Core certification: a green building rating system overseen by the International Living Future Institute.



halfpage1

Most Popular Content

  1. 2021 Giants 400 Report
  2. Top 150 Architecture Firms for 2019
  3. 13 projects that represent the future of affordable housing
  4. Sagrada Familia completion date pushed back due to coronavirus
  5. Top 160 Architecture Firms 2021