URBEE is a return to fundamentals, a rethink of traditional automotive design and manufacturing. As a species endangered by our own actions, we must quickly learn to stop burning fossil fuels. Surely, the ultimate goal of Design is to serve the ‘public good’. Therefore, corporations and individual designers have a responsibility to offer products that are not only useful, but in balance with the environment.

URBEE is now crowd-funded to create the greenest car on Earth. A first prototype was completed in 2013. It became the first car to have its body 3D printed. The team recently initiated a second prototype, called URBEE 2. They are embracing Digital Manufacturing as essential to the design of an environmental car. Engineered to safely mingle with traffic, the two passenger vehicle will have its entire exterior and interior 3D printed.

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SunnyBot is about the size of a large desk lamp and is equipped with an on-board mirror that continuously adjusts to reflect the sun’s rays on a chosen area. It is integrated with a dual-axis microcomputer that’s powered by a row of solar cells and comes with an optional feedback system. The device redirects 7,000 lumens (equal to a single 500 watt halogen lamp) with a range at just over 656 feet.

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The Optical Cavity Furnace is a relatively new type of furnace that uses light and optics rather than other sources to create silicon-based photovoltaic (PV) cells. The new process uses only half the amount of energy to make conventional PVs.
The recent innovation uses a series of lamps in a reflective chamber to create temperature uniformity at high-heat levels throughout the chamber. It’s so uniform that, when heated up to 1,000 degrees Celsius, the entire furnace interior only varies by a few degrees. The heat is used to convert silicon wafers into fully functional photovoltaic cells.
Light Has Multiple Advantages in Furnaces. Photons have special qualities that prove useful in creating solar cells. When light is shined on silicon atoms that are bonded electronically to each other it changes their potential.
The Optical Cavity Furnace shines visible and near-infrared light to heat the solar cell, and also shines ultraviolet light to take advantage of photonic effects that occur deep within the atomic structure of the cell material. This combination offers unique capabilities that lead to improved device quality and efficiency.
Iron and other impurities can degrade the silicon quality quickly. But shining the right light on it can remove that impurity from the silicon. Optics can also make a lot of things happen at the interfaces in a cell, where, for example, metal can reflect the light and speed the diffusion of impurities. The lamps in the furnace help fool the impurities in the silicon into moving out of the way, by creating vacancies.
Bhushan Sopori, NREL Principal Engineer said “We call it injecting vacancies.” A vacancy refers to the lack of a silicon atom. “If the atom is missing, you have a vacancy here, an empty space.” Those spaces prompt the impurities such as iron to feel much more like moving – and they do so at a much lower temperature than would otherwise be required. The iron moves in with the aluminum, creating an aluminum-iron mix that, happily, is needed anyway as a contact point.
Removing impurities can change a cell’s efficiency from 13 percent to 17 percent. What that means is that 17 percent of the photons that hit the improved cell are converted into usable electricity.
The absence of cooling water and confinement of energy in the OCF proves to be a big advantage for lowering the energy payback time of solar cells.
Other advantages of the photonic approach:
Silicon cells often have silver contacts in front and aluminum contacts in back. They usually are fired simultaneously as the cell is being formed. The OCF by selectively heating the interfaces of silicon and metal can better control the process, and thus create stronger field surfaces and improved cell performance.
The Optical Cavity Furnace uses photons of light to remove weak, cracked wafers from the processing line. Photons can more easily produce a thermal stress in a wafer and screen out bad wafers. The photon process tests the wafers’ integrity right after they are cut. The conventional method requires physical twisting and bending of the wafers to test for weakness.
“Its main purpose is to process the wafers into solar cells. We have developed the furnace configurations for major steps used in silicon solar cell fabrication, junction formation, oxidation, and metallization firing,” Sopori said.
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One of the green concept homes showcased at the Department of Energy’s 2011 Solar Decathlon now has a permanent address in Washington, DC. The design is based on several net-zero energy systems that reach peak efficiency when they are joined together.
A rainwater harvesting system captures water from the roof and adjacent land, minimizing the water that drains into public sewers. It features a roof garden and vegetable window boxes. The design won the Solar Decathlon’s first Affordability contest.
Empowerhouse was designed and constructed by a team of more than 200 graduate and undergraduate students from The New School and Stevens Institute of Technology. They worked with Habitat for Humanity of Washington, D.C. (DC Habitat), and the DC Department of Housing and Community Development to move the original design to Washington’s Deanwood neighborhood and expand it into a two-family home.
Deanwood is a primarily working-class, African-American community that is known as one of the greenest areas in Washington, DC. The community recently participated in CarbonFree DC’s “Extreme Green Neighborhood Makeover,” which retrofitted low and moderate-income homes.
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A social entrepreneur of the Philippines has come up with an ingenious solution for lighting problems in the low income areas. He uses plastic bottles to lighten up the dark homes of poor. The solution is green and cheap.

Does the growing family have anything to learn from a growing business seeking new accommodations? We think so. This post kicks off the new home case study for Apple Computer.

The company wants to build one building that will hold 12,000 Apple employees. “There’s not a single straight piece of glass in this building,” according to Apple founder and CEO Steve Jobs. The parking will be mostly underground. Each cafe will feed 3,000 people at one sitting. The campus “energy center” would be the primary source of power and the grid would serve as a backup.
“We have a shot at building the best office building in the world,” Jobs told the Council members, “Architecture students will come here to see this.” Apple hopes to move into the campus in 2015. Additional features include:

• The circular design with a courtyard in the middle and curved glass all the way around.
• Transforming an area that’s 20% landscaping to 80% landscaping by putting most of the building’s parking underground.
• There are 3,700 trees in the area at the moment, Jobs has hired an arborist from Stanford to take the tree population up to 6,000.
• The plan is to build a four-story high building and four-story underground parking structure.
• There will be an auditorium, fitness center and some R & D buildings.
• Jobs plans a 40% increase in Apple employees going from 9,500 today to 13, 000 in 2015.
• He wants to increase the campus’ space 20% from 2.6 million to 3.1 million square feet.
• Surface parking will decrease 90% from 9,800 to 1,200 .
• The building footprint will decrease 30% from 1.4 million to 1 million.

We join the show, already in progress, with a presentation to the Cupertino, California City Council by Steve Jobs.

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A private firm announced a $70 million plan Friday to build Maryland’s largest solar energy project on the grounds of a state prison near Hagerstown to generate electricity for the wholesale market.
Maryland Solar LLC of Easton said it is seeking speedy approval by state utility regulators and a long-term lease on 250 state-owned acres surrounding the medium-security Maryland Correctional Institution. The company said it hopes to use inmate labor to tend the grounds and keep the thousands of solar panels clean.
If the 20-megawatt project is built, Maryland would join California in using open space around correctional institutions to commercially generate electricity from the sun. California’s prison agency said May 6 that more than 83,000 solar panels will be installed at five prisons there, with the state and contractor SunEdison splitting profits from electricity sales.
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In the U.S. Department of Energy Solar Decathlon, 20 collegiate teams design and build energy-efficient houses powered exclusively by the sun. These teams spend almost two years creating houses to compete in the 10 contests of the Solar Decathlon. The winning team produces a house that:

• Is affordable, attractive, and easy to live in
• Maintains comfortable and healthy indoor environmental conditions
• Supplies energy to household appliances for cooking, cleaning, and entertainment
• Provides adequate hot water
• Produces as much or more energy than it consumes.

The  Solar Decathlon challenges the collegiate teams to design, build, and operate solar-powered houses that are cost-effective, energy-efficient, and attractive. The winner of the competition is the team that best blends affordability, consumer appeal, and design excellence with optimal energy production and maximum efficiency.
The first Solar Decathlon was held in 2002; the competition has since occurred biennially in 2005, 2007, and 2009. The next event will take place at the National Mall’s West Potomac Park in Washington, D.C., Sept. 23–Oct. 2, 2011. Open to the public free of charge, visitors can tour the houses, gather ideas to use in their own homes, and learn how energy-saving features can help them save money today.
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