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Transforming roofs from wasted space to energy source

PNNL, Vitex developing process to help protect flexible solar power shingles

News Release

June 03, 2009 Share This!

Issued by Battelle

  • PNNL, Vitex Systems and Battelle are working to adapt a film encapsulation process that would enable flexible solar panels like this. The flexible solar panels could be placed on rooftops like shingles and could replace today's boxy solar panels that are made with rigid glass or silicon and mounted on thick metal frames.
    Photo courtesy of Vitex Systems, Inc.

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RICHLAND, Wash. — A transparent thin film barrier used to protect flat panel TVs from moisture could become the basis for flexible solar panels that would be installed on roofs like shingles.

The flexible rooftop solar panels – called building-integrated photovoltaics, or BIPVs – could replace today’s boxy solar panels that are made with rigid glass or silicon and mounted on thick metal frames. The flexible solar shingles would be less expensive to install than current panels and made to last 25 years.

“There’s a lot of wasted space on rooftops that could actually be used to generate power,” said Mark Gross, a senior scientist at the Department of Energy’s Pacific Northwest National Laboratory. “Flexible solar panels could easily become integrated into the architecture of commercial buildings and homes. Solar panels have had limited success because they’ve been difficult and expensive to install.”

Researchers at PNNL will create these flexible panels by adapting a film encapsulation process currently used to coat flat panel displays that use organic light-emitting diodes, or OLEDs. The work is made possible by a Cooperative Research and Development Agreement recently penned between Vitex Systems and Battelle, which operates PNNL for the federal government.

PNNL researchers developed the thin film technology in the 1990s. At the time, the lab’s team investigated 15 possible applications, including solar power. Vitex licensed the technology from Battelle in 2000 and focused its initial efforts on developing the ultra-barrier films for flat-panel displays. Now PNNL and Vitex are taking a hard second look at solar power.

The encapsulation process and the ultra-barrier film – called Barix™ Encapsulation and Barix™ Barrier Film, respectively – are already proven and effective moisture barriers. But researchers need to find a way to apply the technology to solar panels that are made with copper indium gallium selenide, called CIGS, or cadmium telluride, called CdTe.

Under the agreement, researchers will create low-cost flexible barrier films and evaluate substrate materials for solar panels, which are also called photovoltaics, or PVs. Both the film and substrate must be able to survive harsh ultraviolet rays and natural elements like rain and hail for 25 years.

The agreement also calls for researchers to develop a manufacturing process for the flexible panels that can be readily adapted to large-scale production. If successful, this process will reduce solar panel manufacturing costs to less than $1 per watt of power, which would be competitive with the 10 cents per kilowatt-hour that a utility would charge.

“Vitex is proud to continue its long, successful relationship with PNNL,” said Martin Rosenblum, Vitex’s vice president of operations and engineering. “Vitex is excited to further its Barix™ technology’s proven barrier performance for photovoltaics toward mass manufacturing. Together, we look forward to creating a product that will help alleviate America’s dependence on foreign oil and increase America’s access to an abundant renewable energy source – the sun.”

Battelle, which is the majority shareholder of Vitex, is optimistic that this research agreement will contribute to a new way of generating solar power. Battelle recently increased its investment in Vitex for new state-of-the-art thin film encapsulation equipment and expanded its intellectual property portfolio.

“We’re confident that Vitex will be uniquely positioned to help meet the demand for flexible solar panels, OLED displays and lighting that should rise along with the economy,” said Martin Inglis, Battelle’s chief financial officer.

PNNL’s research efforts will be paid for with up to $350,000 from the DOE’s Energy Efficiency and Renewable Energy Technology Commercialization Fund. Last year, DOE announced that up to $1.5 million from the fund would be available to PNNL for projects that help commercialize technologies that reduce energy use or tap renewable energy sources. Because the fund requires commercial partners to match funding, Vitex will provide up to $350,900 of in-kind labor, equipment and materials for this project.

Tags: Energy, Technology Transfer and Commercialization, Energy Efficiency, Renewable Energy, Solar Power

Vitex Systems Inc., headquartered in San Jose, Calif., licenses a proprietary encapsulation solution, BarixTM, as well as deposition systems and next-generation flexible barrier substrates, that enable the cost-effective production of organic light-emitting diode (OLED) displays that are lighter and thinner than any other commercially available displays. Vitex's technology can also be used to address a wide array of photovoltaic and optoelectronic applications. The company was incubated at Battelle, the world's largest independent private non-profit research foundation, and was spun off as an independent company.

Battelle LogoEvery day, the people of Battelle apply science and technology to solving what matters most. At major technology centers and national laboratories around the world, Battelle conducts research and development, designs and manufactures products, and delivers critical services for government and commercial customers. Headquartered in Columbus, Ohio since its founding in 1929, Battelle serves the national security, health and life sciences, and energy and environmental industries. Battelle has managed and operated the U.S. Department of Energy's Pacific Northwest National Laboratory in Richland, Wash., since the laboratory's inception in 1965.

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