Sportswear maker Puma North America has installed a 1.9 megawatt solar power system at its warehouse and distribution facilities in Carson and Torrance, one of the largest solar projects in Los Angeles County.
The system was installed by Premier Power Renewable Energy Inc., using more than 8,500 high-efficiency solar photovoltaic, or PV, panels — equal to about 380 residential solar systems – covering nearly 340,000 square feet of roof-top area.

The installation features a light-gauge steel racking system designed to optimize roof space while using fewer ballast blocks than a traditional system. “Given the optimal design of the roof-mounted solar system, Puma will receive the advantageous electricity production, which will allow them to stabilize long-term electricity rates, ultimately benefiting its customers, employees and the local communities,” the companies said.

Premier Power designed and engineered the solar systems to produce 2.2 million kilowatt-hours of electricity a year, enough to offset the annual carbon monoxide emission of 243 California homes or avoiding the annual carbon monoxide emission from using 4,662 barrels of oil or 225,501 gallons of gasoline, the companies said. The companies didn’t disclose cost of the solar power installations. Puma’s facilities in Carson and Torrance are operated by Brookvale International, a sister company of California Cartage Co. The two automated warehouses encompass 180,000 square feet for apparel and 300,000 square feet for footwear.

PUMA

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Photovoltaic (PV) efficiency is a significant problem for today’s commercial solar panels, which can collect only a theoretical maximum of about 30 percent of available light. Now, a team that includes a University of Missouri engineer is developing a flexible solar film that can theoretically capture more than 90 percent of available light. Prototypes could be produced within the next five years.

Patrick Pinhero, an associate professor in the MU Chemical Engineering Department, says energy generated using traditional photovoltaic methods of solar collection is inefficient and neglects much of the available solar electromagnetic (sunlight) spectrum. The device the team is developing — essentially a thin, moldable sheet of small antennas called nantenna — is designed to harvest industrial waste heat and convert it into usable electricity. Their ambition is to extend this concept to direct solar facing nantenna devices capable of collecting energy broadly from the near infrared to the optical regions of the solar spectrum. Working with colleagues at Idaho National Laboratory, and Garret Moddel, an electrical engineering professor at the University of Colorado, Pinhero and the team are now developing a way to extract electricity from the collected heat and sunlight using special high-speed electrical circuitry. This team also includes Dennis Slafer of MicroContinuum, Inc., in Cambridge, Mass., which is developing a manufacturing process that can inexpensively produce high volumes of the novel energy-harvesting film.

“Our overall goal is to collect and utilize as much solar energy as is theoretically possible and bring it to the commercial market in an inexpensive package that is accessible to everyone,” Pinhero said. “If successful, this product will put us orders of magnitudes ahead of the current solar energy technologies we have available to us today.”
The team, which is seeking funding from the U.S. Department of Energy and private investors, also envisions an energy-harvesting device for existing industrial infrastructure, including solar farms and factories that generate waste heat. Within five years, the research team believes they will have a product that complements conventional PV solar panels by capturing currently unused infrared energy. Because it’s a flexible film, Pinhero believes it could be incorporated into building materials and infrastructure.

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At an elegant, port-side venue in Valencia, Spain, in September, Christian Reimann received heady honors for a young scientist: the SolarWorld Junior Einstein Award, a cash prize and a standing ovation from a room full of leading scientists and industrialists working on solar photovoltaic technology.“The award was the pinnacle of my career so far,” said Reimann, now manager of a group researching silicon crystallization at the prestigious Fraunhofer Institute for Integrated Systems and Building Element Technology in Erlangen, Germany. Reimann won the award for his work developing a process to reduce impurities in silicon melted for crystallization and thereby elevate the efficiency of resulting solar cells and lower the costs of solar power. The process later was patented.

Young scientists in fields related to solar photovoltaics – systems technology, nanotechnology, general energy technology, crystallography and engineering subjects – have about a month left to submit their research in this year’s sixth annual staging of the competition for a chance to win the award trophy, 5,000 euros and professional recognition. Their final scientific paper in English or German must have been evaluated between June 2010 and June 2011. The deadline for application submissions is June 15.

Ethan Good, SolarWorld’s U.S. head of research and development and a doctoral graduate of the Colorado School of Mines, hopes young scientists will enter the competition to spread recognition for photovoltaic research into the Americas, where the company has been the largest solar manufacturer for more than 35 years. “European researchers have made well-recognized discoveries in the scientific fields that underlie solar technology,” Good said. “It’s time for researchers in the Americas to compete for recognition of their own advances.”Award namesake Albert Einstein not only founded modern physics but also explained the photoelectric effect.

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