Radian Generation Will Showcase LENS™, Its Leading-Edge Asset Management Software Solution, At Solar Power International 2016

SAN FRANCISCO, CA August 30, 2016 – Radian Generation (RadianGEN), a leading independent asset management and operations and maintenance (O&M) firm providing comprehensive software and services to solar project owners, will showcase its LENS asset management software solution at Solar Power International 2016 (SPI). RadianGEN will be presenting on-demand demos in their exhibition area of booth #1171.

RadianGEN’s proprietary LENS software helps asset managers work smarter and delivers higher returns on their renewable energy investments. Project owners can learn from their portfolios, reduce risk and enhance continuity planning with a single, centralized platform that consolidates key project information, data feeds, ticketing, performance analytics and administrative processes. The LENS software empowers teams to work more productively and make better decisions by putting the right data at their fingertips when they need it. LENS is available as a stand-alone Software as a Service (SaaS) or in combination with RadianGEN’s solar asset management services.

Chad Sachs, CEO of RadianGEN, said, “RadianGEN’s success is built on our proven track record of solar asset management, project development, and field work. Our team actively manages over 500MW of solar and wind projects. We have channeled our operating experience and best practices into the LENS software tool. This direct experience differentiates our software from competitors and delivers better value to our customers.”

Radian Generation staff and executives will be available throughout SPI 2016 held Tuesday, Sept. 13^th through Thursday, Sept. 15^th at the Las Vegas Convention Center’s North Hall. Ask for the LENS demo at SPI, or for more information, visit http://radiangen.com/technology/.

Solar Power International brings together the entire solar industry — from innovative start-ups to well-established solar providers — and more than 15,000 attendees to share insights, innovations, and information. Registration for SPI 2016 is now open.

About Radian Generation:

Radian Generation is a leading independent full service asset management firm providing best-in-class software, services and O&M. RadianGEN is a growing team of solar industry veterans, with proprietary technology and processes that deliver best-in-class solar asset management and field services. RadianGEN provides project investors, lenders, and operators with comprehensive management services and software necessary to ensure their projects perform contractually, technically and financially.  The team works with leading infrastructure funds, national utilities, developers, IPPs, and O&M providers to generate higher ROI on solar assets. RadianGEN currently provides asset management services to over 520MW of solar and wind assets under management across the Americas, Canada, and the Caribbean. To learn more, please visit www.radiangen.com

Solar, Wind Power Used to Grow Greenhouse Crops

By growing food in environmentally sensitive ways with electricity and heat from the wind and sun, Barry Adler combines two things he loves into one business: horticulture and renewable energy.


“It’s a good feeling to know I’m not polluting in the process of using energy,” said Adler, owner of RainFresh Harvests, which grows herbs, greens and other vegetables for local restaurants and stores.

RainFresh, located near Plain City, is one of more than 170 sites on this year’s weeklong Green Energy Ohio Tour that wraps up today. The tour features businesses, homes, schools, other buildings and parks that have incorporated solar panels, wind turbines and other devices that reduce energy consumption.

“I wanted to create a model to be as sustainable as possible and have the least impact on natural resources,” said Adler.

He showed about 50 visitors yesterday how a wind turbine and solar panels create electricity and heat to run his two greenhouses even when power is out elsewhere.

He also pointed out how construction materials used in the greenhouses make them more energy-efficient and help him grow food year-round.

Adler, 60, has about $40,000 invested in his renewable operations, but he said the cost of the panels and turbines has fallen since he installed them several years ago, and the equipment has improved.

The bigger greenhouse, which has nearly 1,500 square feet, has panels on the roof that generate electricity and heat, and batteries inside the building to store power.

Adler’s business is not new to the tour, but plenty of others are this year as interest continues to grow, said William Spratley, Green Energy Ohio’s CEO.

The tour includes drugstores and a stable with solar panels. Churches are part of the event, as are homes with solar panels that create electricity for electric cars, Spratley said.

Among those touring Adler’s business was Yang Xing, 31, of Wooster, who is doing postgraduate work in environmental science at Ohio State University.

“I’m trying to see if there is an opportunity to get some hands-on experience,” said Xing, who was particularly interested in methods Adler uses to grow food.

Kevin Malhame, a founder of Northstar Cafe in Columbus, has been buying arugula, basil, oregano, mint, specialty vegetables and other food from Adler for eight years.

“The greens and herbs are fantastic,” he said.

That Adler uses renewable energy to power his operations is a plus for Northstar, Malhame said. “ That makes it more valuable to us,” he said.

Adler’s interest in food and energy date to the 1970s, when the organic-food movement took hold in California, followed by the Arab oil embargo that drove up fuel prices.

Adler said his goal is to show visitors that it’s possible in Ohio to use sunshine and wind to grow crops in a sustainable way and make a few bucks along the way.

“It allows me to share my experiences with what I’ve done,” he said.

Source: http://www.dispatch.com/content/stories/local/2012/10/07/solar-wind-power-used-to-grow-greenhouse-crops.html

Gadling Gear Review: Solar Chargers For Travel

Keeping all of our electronic gadgets charged while traveling can be a real challenge, particularly if you're visiting a remote part of the world where electricity is at a premium. But just as the gizmos we carry with us have gotten more sophisticated so have the options for keeping them powered. One of those options is taking a solar charger with us when we hit the road. A solar cell provides clean, efficient and, in theory, limitless power for our tech toys.

Here are two distinctly different solar chargers aimed at very different types of travelers. Both are excellent for what they do, and while they each use light from the sun to create electricity, their similarity pretty much ends there.

Solio Classic2

The Classic2 is Solio's second-generation, travel solar charger, replacing their older Classic model, which was one of the earliest compact chargers on the market. The Classic2 improves on its predecessor in some key areas making it a much more efficient option to have in your pack when you travel. Those improvements include doubling the battery capacity and adding a full-size USB port integrated into the device. The previous version came with a number of special adapters, which were incredibly inconvenient to carry along on a trip. Since most devices, including smartphones and cameras, now charge via USB, this was an evolutionary, but very welcome, change.

The Classic2 features three small solar cells, each embedded in its own arm. When collapsed the device is small, lightweight and compact. It weighs just 10.1 ounces and easily slips into a backpack, carry-on bag or luggage. When ready to collect energy from the sun, it opens up like a flower, exposing all three cells for maximum efficiency. The energy is then stored in a 3200-mAh internal battery, which in turn is used to charge our devices via the built-in USB port.
Solio says that it should take 8-10 hours to charge the Classic2's internal battery from the sun, but in my testing it was definitely closer to the high side of that estimate, if not longer. Cloudy days and the amount of exposure to direct sunlight can impact that charging time dramatically. Fortunately, the internal battery can also be topped off from a wall socket or from a USB port on a computer. In both cases, it takes roughly six hours to charge the battery.

The built-in USB port on this charger provides up to 1 Amp of power, which puts it on par with a typical wall charger. That means it can charge a smartphone or MP3 player in fairly short order. Solio claims charging an iPhone takes about 90 minutes, although again I found it took a bit longer. It was closer to 2 hours in my testing, although the internal battery did provide nearly three full recharges on an iPhone 4S. It should be noted that the Classic2 is also capable of charging an iPad, although it is a slow process and it will drain the entire charge.

The Solio Classic2 is perfect for travelers who enjoy traveling light and may need to juice up their gadgets a few times while on the road. It's compact, easy to pack and works as advertised. I'd recommend using it for cellphones, GPS units, MP3 players and point-and-shoot cameras. Anything more than that is likely to provide results that are a bit more frustrating.

Goal Zero Guide 10 Plus Adventure Kit

Goal Zero's Guide 10 Adventure KitLarger and more powerful than Solio's offering, the Guide 10 Plus Adventure Kit from Goal Zero is designed for the adventure traveler that intends to be in the backcountry for an extended period of time. It features twin 9-inch solar panels that are capable of generating up to 7 Watts of power, charging up the included battery pack in as little as 3-4 hours. Like the Solio Classic2, this kit features a built-in USB port capable of putting out a 1 Amp charge but it also includes 4 AA batteries, a rechargeable flashlight and cables that help round out the package, providing everything you need to keep your gadgets charged while living off the grid.

Putting Goal Zero's solar charger to the test, I found that it wasn't necessarily faster at charging up my devices than Solio's much smaller device. That's in part because they both share that same 1 Amp USB charging port, which made charging times on smartphones and cameras roughly the same. Where the Guide 10 Plus shines is that it can charge its battery pack much more quickly and consistently than the Solio Classic2. Collecting power from the sun is a more viable option with the Guide 10 Plus kit, and while with Solio's offering it, it was a more uneven experience.

The Guide 10 is considerably larger than the Classic2, although it does fold up into a rather compact form for transport. The solar cells are designed to connect to a backpack so that they can collect the suns rays while hiking throughout the day. That means by the time you make camp in the evening, you'll have gathered plenty of power to charge your gadgets overnight.

It should be noted that like the Solio Classic2, the Guide 10 kit is more than capable of charging your iPad using nothing but solar power. No matter which device you use, it can be a slow process, particularly with the higher capacity batteries of the iPad 3. The larger solar cells make this a more efficient process on Goal Zero's offering, however, and that is the option I'd recommend if you absolutely need to keep your tablet powered while in the field.

Both the Classic2 and Guide 10 are viable options for using solar power and I think they are both good at what they do, provided you understand their strengths and limitations ahead of time. The Classic2 is small, compact and easy to carry everywhere. Its battery pack is good for 3-4 recharges of various devices, although it is slow to refill using the sun. On the other hand, the Guide 10 can charge much more quickly and reliably, but it is larger and bulkier to carry with you.

Most travelers will find the $99 Solio Classic2 will fit their needs quite nicely, while backpackers, mountaineers and long distance trekkers will appreciate what Goal Zero's Guide 10 Adventure Kit delivers. That $159 solution has everything they need to stay powered up for extended journeys and its more rugged construction is designed to stand up to punishment on those kinds of excursions.

It's great that we're finally to the point where solar power is a true option for gathering power while traveling.


Source: http://www.gadling.com/2012/09/24/gadling-gear-review-solar-chargers-for-travel/

Local Solar Company Trains Five Cities Firefighters on Solar Safety

Solarponics, the longest continuously owned and operated solar company in California, offered Five Cities Firefighters solar safety training courses. The courses took place September 4th, 5th, and 7th, each session educating a different group of 15-20 local firefighters. Classes covered the basics of how solar electric works, equipment components and other knowledge firefighters working around solar electric need to understand.

"Although solar panels have been around for some time, the fire service is now encountering more and more solar installations on businesses and residences," said Riki Heath, Five Cities Fire Authority Battalion Chief.

As solar PV systems increasingly appear on rooftops throughout the United States, especially in California, Solarponics felt that there was a need to train firefighters on system safety. Battalion Chief Heath said that though there is a training program offered by the state, he does not know how comprehensive the program is.

"The firefighters want to feel comfortable around solar electric systems. We want them to know that we are a resource if they have any questions," said Kristian Emrich, Vice President of Solarponics.

The training took place at CJ's Cafe, located at 611 E. Grand Avenue in Arroyo Grande. CJ's was one of the first restaurants to install a solar panel system on the Central Coast. Using a location with an installed, operating solar system allowed Solarponics to give firefighters hands-on training, on CJ's roof.

"I believe this training is vital to the safety of all firefighters. I think it was a very good idea and I hope to repeat it on an annual basis. We greatly appreciate Solarponics for approaching us and offering the excellent training they provided us," said Heath.

The goal of the training program is to educate firefighters about the safest ways to interact with solar systems. Emrich says there are few risks for firefighters who are aware and trained on how to work with solar systems. Solarponics plans to continue solar safety training for firefighters with another round of training next month. They encourage any fire department interested in learning more about solar safety to contact them.

"I am glad to work for a team that prides itself on preventative measures and truly specializes in not just solar, but the important safety measures associated with solar such as electrical codes," said Mike Wiegel, Design Manager and Solar Safety Trainer at Solarponics.

Future PV installs are expected to feature additional preventative measures required by The National Electrical Code (NEC), Cal Fire and local jurisdictions (AHJ). Some of these safety measures include walkways around all arrays, reflective labels to help identify solar conduits and separate devices to shut off each module.

Solarponics is the Central Coast's alternative energy pioneer, helping residents achieve energy independence for over 35 years. The longest continuously owned and operated solar company in California, Solarponics has been family owned and operated since 1975. Solarponics can install and service solar electric systems, solar hot water, wind energy systems, solar pool heating and radiant heating systems.


Source: http://www.fireengineering.com/news/2012/10/06/local-solar-company-trains-five-cities-firefighters-on-solar-safety.html

Palestinians Design Solar Car To Break Energy Dependence On Israel

Necessity is the mother of invention, and for Palestinians living on the West Bank trying to break their dependence on Israel for energy has resulted in a new solar powered vehicle.

The four-seater is covered in solar panels to convert the suns rays into energy to power a small electric motor which pushes the vehicle along at 20 kilometers per hour for about 10 hours. And if the sun doesn’t shine it can be plugged into the wall, and the battery recharged from the mains.

It looks a bit like an over-sized golf cart and took the Royal Industrial Trading Company around two months and $5000 to develop.

“This car was the first step, and now we are working on two other cars. If the work is successful, then we will do a lot of cars and sell them”, says Nabel Az-Zagheer, chairman of the Royal Industrial Trading Company.

Based in the town of Al-Khalil, the company specializes in sanitation and water supply products, and adapted them to create the new vehicle.

A greater use of solar energy could help the people of the West Bank escape escalating energy prices.

Israel has control over the fuel supply to the Palestinian population, and according to the Oslo agreements, the Palestinian Authority is obliged not to sell its gasoline for less than 15 percent of Israel’s market price, reports the The Electronic Intifada.

"Such supply monopolies are a form of power. They provide easy ways to exert political pressure on the Palestinian Authority and ordinary Palestinians and to enforce their compliance with Israel’s interests", Charles Shamas, a founder of the Mattin Group, a Ramallah-based research and advocacy organization told the Middle East Media Center.

The Palestinians are also heavily dependent on electric power provided by Israel. A power station in Gaza provides some 40% percent of the Strip’s electricity; the rest has to be purchased from Israel. Some small amounts are also sold by Egypt and Jordan.

“We want to lower as much as possible our dependence on Israel, because we won’t be able to reach a reasonable level of national security if Israel can, at any point, disconnect our electricity, and even harm the power plant in Gaza, as it did in 2006 as punishment for the abduction of Gilad Shalit,” Hanna Siniora, chairperson of the Palestinian-American Chamber of Commerce, has told Al-Monitor.com

Constantly rising fuel prices affect the cost of basic foodstuffs such as maize, vegetable oil and bread.

Palestinian efforts to reduce its dependency on Israeli energy have met strong opposition from Tel Aviv.

In March RT reported on Israel’s plans to bulldoze eight solar panels in the West Bank. They were donated by a number of international charities in 2009, yet have were deemed “illegal” by Israeli authorities due to the lack of an appropriate building permit.

The 62% of the West Bank controlled by Israel is not connected to the national energy grid. On the other hand, the Jewish settlements in the area are connected to national energy and water grids, reports the Guardian.

"We saw a systematic targeting of the water infrastructure in Hebron, Bethlehem and the Jordan valley. Now, in the last couple of months, they are targeting electricity. Two villages in the area have had their electrical poles torn down. There is a systematic effort by the civil administration targeting all Palestinian infrastructure in Hebron. They are hoping that by making it miserable enough, they [the Palestinians] will pick up and leave," an anonymous UN expert told the Guardian.

Source: http://www.arabamericannews.com/news/index.php?mod=article&cat=ArabWorld&article=5910

Five Solar-Powered Trash Compactors Installed

The town recently received five solar-powered trash compactors free of charge from the state Department of Energy Resources. Tewksbury was awarded the BigBelly Solar trash receptacles because of its designation by the state last year as a Green Community.

Because they compact trash, the receptacles can each hold significantly more than a standard trash barrel and do not need to be emptied as often. Two of the compactors have been installed at Livingston Recreation Area, and one each at the Town Common, Wynn Middle School, and the public library. The compactor at the Town Common is for regular trash only, while those at the other four locations are for both regular trash and recyclables.

Source: http://www.boston.com/news/local/massachusetts/articles/2012/08/19/five_solar_powered_trash_compactors_installed/

Tanzania: Energy - Solar Cooker Ideal for Rural Areas

NYEGINA is one of the villages in Musoma District, Mara Region. The village is located some 16 kilometres from the town centre.

I recently visited the village, to pay homage to my ancestral home. It had been ten years since I last visited Nyegina Village. Not so much has changed except for more brick houses and the availability of electricity in some few houses.

However, what caught my attention was not this change but a cooker that uses solar energy. It's just not the solar cookers that we know about but a much simpler cooker. So many Tanzanians struggle to make the ends meet in providing their families with the daily basic needs.

Some of them succeed, but others barely make it. This cooker is an example of a cheap technology that will help the majority of population that struggles to meet its daily basic needs. It is another invention that would simply make life less miserable.

The cooker only needs a few materials to be made, which can be easily obtained; box materials, aluminum, and cloth used for book binds like those used on counter books. The cooker is designed in such a way that a cooking pot with food is simply placed inside it.

Depending on the size, even two cooking pots painted in black colour can be placed in the cooker which is then placed in the sun for the food to cook. The scientific process applied here is that the aluminum material is a good conductor of heat. Thus the material on the inside of the cooker receives heat from the sun and passes it to the cooking pot whose material also conducts heat.

This is because the black colour painted around the pot absorbs heat. Therefore the food is heated in such manner till it is fully cooked. For most of the technology we use today, we consider one important aspect; whether it is environmental friendly. In this case, the cooker serves the purpose.

Besides, environmentalists have always looked for alternative sources of energy other than charcoal and firewood which are largely used in our country. Further, the sun is an energy resource that cannot be overexploited and it never is exhausted.

The cooker also uses cost effective materials, no installation costs are incurred and the operation is easy. One only needs to place the cooking pot inside the cooker and place it under the sun It is suitable for rural areas where people spend most of their time on the farms and come back late in the evening.

Therefore, the food can be left in the cooker and can be removed in the evening when it will definitely be ready. In addition, the cooker is useful for foods that take long hours to cook such as makande and beans. However, despite its usefulness the cooker has its disadvantages. Perhaps it could be modified to improve its functioning. The cooker is time consuming since it takes long hours for food to cook.

During the rainy season or when sunshine isn't sufficient the cooker is not useful. And in rainy areas the cooker can get destroyed since it is made of boxes. It is also not adequate that once you place the food inside the cooker, one needs to watch for animals since the top of the cooker is not covered.

The question however is do people really benefit from such inventions? It seems the authorities is too busy to realize that such innovations do exist and support for improvement is important. According to a relative, the women in the village were taught by the parish nuns how to make these cookers.

The private sector has played its role inventing and educating the women, what then of the public sector? My aunty does not use the cooker and so do most of the women who attended the one week seminar at the parish church. Projects such as these could be expanded into bigger ones and start them in urban areas too were life is also expensive.

Source: http://allafrica.com/stories/201208180291.html

Solar for iPhone

Most weather apps try to convince you to ditch the default Weather offering in iOS by adding more features. Solar takes the opposite approach, stripping down its weather report to essentially offer time, temperature, and condition-appropriate color patterns. Whether Solar tops what you already get for free from Apple's built-in app depends on the value you place on aesthetics.

Because make no mistake: Solar is an awfully pretty app, relying on what it calls "Rothko-esque colorscapes" to not only tell you what the temperature is but to also depict current conditions. That's Rothko, as in Mark Rothko, the abstract expressionist painter known for his use of color. A typical Solar screen stacks colors on top of each other; cooler temperatures have a bluish hue, while the colors become more orange and red as the mercury rises. Besides the handy visual reference, the app also displays time and temperature.

In an especially useful touch, Solar takes advantage of your phone's location-awareness features to always display the temperature for where you are. You can also add cities on your own, storing up to 20 locations within the app.

Other reviews of Solar have praised the app for its intuitive controls. I didn't exactly find them to be that way, figuring out most of the controls through trial-and-error and by studying a promotional video on the website of developer Hollr like it was the Zapruder film. Dragging your finger up the screen will show how the temperature will change over the next 24 hours. Pulling down displays a three-day forecast. A single tap makes the temperature and time data disappear, leaving you with just the colorscape. Double-tapping shows all of the cities you have stored laid out in a four-city-per screen grid.

Eye-catching though Solar may be, I prefer the five-day outlook the built-in Weather app offers. I also think Weather's hourly outlook is a bit easier to manage than the finger slide that Solar relies on.

Still, Solar's location-based component is a nice feature. And iPhone owners with a keener eye than mine will doubtlessly appreciate the colorful approach Solar brings to the weather.

Source: http://www.computerworld.com/s/article/9230058/Solar_for_iPhone?taxonomyId=18

Himachal Pradesh To Give Solar Lamps At Remote Villages

Himachal Pradesh will provide solar lamps at pastoral settlements in non-electrified villages, an official said here on Friday.

The ministry of new and renewable energy has sanctioned Rs 1.07 crore to the state government under the energy conservation scheme for distributing solar lanterns among sheep and goat breeders in remote and tribal areas, a government spokesperson told IANS.

He said as many as 4,337 lanterns would be provided by Himurja, a state-run agency that is promoting use of non-conventional energy.

Himachal Pradesh has developed a master plan to promote non-conventional energy and is developing two solar-powered towns - Shimla and Hamirpur.

The state's first solar energy plant of 200 KV capacity has been set up at Baru Sahib in Sirmaur district, while 216 police posts would soon be getting two KV solar power plants.

The state government distributed compact fluorescent lamps (CFLs) to every household free of cost in 2008-09. This has resulted in a saving of about 270 million units of power worth Rs 100 crore in a year.



Source: http://articles.timesofindia.indiatimes.com/2012-08-04/the-good-earth/33035255_1_solar-lamps-solar-lanterns-solar-energy-plant

Solar Power Shines In Electric Car Industry

The electric vehicle (EV) market is set for take-off, but unless renewable energy is used in the charging systems or within the vehicle design, owners are still using fossil fuels for transportation.

Electric car being charged from solar panels designed to resemble a tree.

Photovoltaics (PV) are poised to play a vital role in the transport sector. Not only is PV being used to power EVs but some companies now produce PV modules that can be retrofitted to hybrid EVs such as the Toyota Prius to extend their range and economy. An example is Solar Electric Vehicles, which was founded in 2005 with the aim of enhancing the performance of HEVs through the use of solar energy. The roof-mounted modules on a Toyota Highlander hybrid are based on mono-crystalline PV cells that are used in conjunction with an additional battery pack. The unit designed for the Prius generates 215 Watts and provides this vehicle with up to 30 miles per day in the battery solar mode. It also yields improved fuel economy of between 34 and 60%, depending on driving habits, speed, and road conditions. An interesting factory-fitted option on the Prius is solar-powered air conditioning. A solar panel is fitted in the optional glass sunroof and is used to power a fan to keep the vehicle ventilated. The air conditioning can be switched on remotely using the key fob, cooling the car for up to three minutes before you enter.

Source: http://evworld.com/news.cfm?newsid=28365

Solar-Powered Plane Leaves Spain For Morocco

An experimental solar-powered plane has taken off from Madrid en route to Morocco in a bid to complete its first transcontinental flight.

The Solar Impulse HB-SIA experimental aircraft is pulled out a
hanger at Barajas airport in Madrid, Spain, Tuesday, June 5,
2012. The solar-powered airplane arrived in Madrid on May 25,
2012 from Payerne, Switzerland, and now goes on to Rabat,
Morocco on its first transcontinental trip. The mission is
described as the final dress rehearsal for a round-the-world
flight with a new and improved aircraft in 2014.

The single-seat aircraft fitted with 12,000 solar cells is the size of a jumbo jet. Organizers said in a statement it is due to arrive in the Moroccan capital Rabat late Tuesday night after leaving Spain before dawn.

Solar Impulse arrived from Switzerland in late May on the first leg of the journey.

The mission is being described as a final dress rehearsal for a round-the-world flight with a new and improved plane in 2014.

The project began in 2003 and is estimated to cost about $100 million over 10 years.

The two-leg Europe to Africa trip covers 2,500 kilometers (1,554 miles).

Read More

Solar Cells from Grass Clippings

Within a few years, people in remote villages in the developing world may be able to make their own solar panels, at low cost, using otherwise worthless agricultural waste as their raw material.

That's the vision of MIT researcher Andreas Mershin, whose work is an extension of a project begun eight years ago by Shuguang Zhang, a principal research scientist and associate director at MIT's Center for Biomedical Engineering. In his original work, Zhang was able to enlist a complex of molecules known as photosystem-I (PS-I), the tiny structures within plant cells that carry out photosynthesis. Zhang and colleagues derived the PS-I from plants, stabilized it chemically and formed a layer on a glass substrate that could — like a conventional photovoltaic cell — produce an electric current when exposed to light.

But that early system had some drawbacks. Assembling and stabilizing it required expensive chemicals and sophisticated lab equipment. What's more, the resulting solar cell was weak: Its efficiency was several orders of magnitude too low to be of any use, meaning it had to be blasted with a high-power laser to produce any current at all. Now Mershin says the process has been simplified to the point that virtually any lab could replicate it — including college or even high school science labs — allowing researchers around the world to start exploring the process and making further improvements. The new system's efficiency is 10,000 times greater than in the previous version — although in converting just 0.1 percent of sunlight's energy to electricity, it still needs to improve another tenfold or so to become useful, he says.

The key to achieving this huge improvement in efficiency, Mershin explains, was finding a way to expose much more of the PS-I complex per surface area of the device to the sun. Zhang's earlier work simply produced a thin flat layer of the material; Mershin's inspiration for the new advance was pine trees in a forest.

Mershin, a research scientist in the MIT Center for Bits and Atoms, noticed that while most of the pines had bare trunks and a canopy of branches only at the very top, a few had small branches all the way down the length of the trunk, capturing any sunlight that trickled down from above. He decided to create a microscopic forest on a chip, with PS-I coating his "trees" from top to bottom.

Turning that insight into a practical device took years of work, but in the end Mershin was able to create a tiny forest of zinc oxide (ZnO) nanowires as well as a sponge-like titanium dioxide (TiO2) nanostructure coated with the light-collecting material derived from bacteria. The nanowires not only served as a supporting structure for the material, but also as wires to carry the flow of electrons generated by the molecules down to the supporting layer of material, from which it could be connected to a circuit. "It's like an electric nanoforest," he says.

As an bonus, both zinc oxide and titanium dioxide — the main ingredient in many sunscreens — are very good at absorbing ultraviolet light. That's helpful in this case because ultraviolet tends to damage PS-I, but in these structures that damaging light gets absorbed by the support structure. Mershin thinks that because he and his colleagues have now lowered the barrier to entry for further work on these materials, progress toward improving their efficiency should be rapid. Ultimately, once the efficiency reaches 1 or 2 percent, he says, that will be good enough to be useful, because the ingredients are so cheap and the processing so simple.

"You can use anything green, even grass clippings" as the raw material, he says — in some cases, waste that people would otherwise pay to have hauled away. While centrifuges were used to concentrate the PS-I molecules, the team has proposed a way to achieve this concentration by using inexpensive membranes for filtration. No special laboratory conditions are needed, Mershin says: "It can be very dirty and it still works, because of the way nature has designed it. Nature works in dirty environments — it's the result of billions of experiments over billions of years."

Because the system is so cheap and simple, he hopes this will become a "way of getting low-tech electricity to people who have never been thought of as consumers or producers of solar-power technology." He hopes the instructions for making a solar cell will be simple enough to be reduced to "one sheet of cartoon instructions, with no words." The only ingredient to be purchased would be chemicals to stabilize the PS-I molecules, which could be packaged inexpensively in a plastic bag.

Essentially, Mershin says, within a few years a villager in a remote, off-grid location could "take that bag, mix it with anything green and paint it on the roof" to start producing power, which could then charge cellphones or lanterns. Today, the most widely used source of lighting in such locations is kerosene lanterns — "the most expensive, most unhealthy" form of lighting there is, he says. "Nighttime illumination is the number one way to get out of poverty," he adds, because it enables people who work in the fields all day to read at night and get an education.

Babak Parviz, an associate professor of electrical engineering at the University of Washington who specializes in bionanotechnology, says this is "a very exciting paper and a very nice step toward integrating biomolecules for building solar cells. This shows a very promising and creative first step toward building organic photovoltaic cells that can use biologically (naturally) produced cores." He adds that while the present system still needs further development, "further work in the field can perhaps improve the stability and performance of these devices."

The research was funded in part by an unrestricted grant from Intel Corp., and also included researchers at the University of Tennessee.

SOURCE: http://www.energyharvestingjournal.com/articles/solar-cells-from-grass-clippings-00004142.asp?sessionid=1

The World’s Prettiest Solar Car Drives Through America

The world’s prettiest solar car (the one from Bochum) kicked off its U.S. leg of its journey around the world this week. The SolarWorldGT is in California today, after successfully completing the first 3,100 miles of its journey in Australia and New Zealand.

Solar-Powered Sports Cars – the Future?

The purely solar-powered car, called the SolarWorld Gran Turismo (or GT), is a joint effort made by American solar panel manufacturer SolarWorld and Bochum University of Applied Sciences of Germany. As a sports car it seats two, and as a solar car, it’s powered by the solar cells integrated into the roof.

Kevin Kilkelly, president of Solarworld Americas (the company’s commercial unit based in California), spoke briefly to Business Wire about the future of solar cars in the industry as he sees it:

“The SolarWorld GT is an ambassador for sustainable personal transportation, reminding us that the power to shift our driving habits away from dirty fossil fuels is within our grasp. Clean energy from the sun is there for the taking – without depleting the Earth’s riches.”

From Sea to Shining Sea (or Something)

Going far beyond the 3,000 miles raced by solar cars in Australia every other year, the SolarWorld GT is aiming for a 21,000 mile record-breaking drive – the longest distance ever driven by a solar car. It will travel over 3,700 miles in the United States alone, starting in California and finishing up in South Carolina. The trip should take 49 days in all, with receptions hosted by the drivers and crew at each of the five planned stops.

The SolarWorld team will also be hosting a Facebook competition to see if anyone recognizes where the car has been from clues dropped during the journey. Winners get stuff from SolarWorld, but the big incentive to participate is the drawing for an Apple iPad 2 (which will not be solar powered, sadly).

You, Too, Can See the SolarWorld GT in Action

For those of you who are in the area and want to see the car in person, the receptions at each planned stop are open to the public:

• 4 p.m. Feb. 3, University of California Santa Barbara, Bren School of Environmental Management, Santa Barbara, CA.
•  8:30 a.m. Feb. 6, SolarWorld Americas, Camarillo, CA.
•  4 p.m. Feb. 10, Arizona State University, Office of Knowledge Enterprise Development, Tempe, AZ.
• 4 p.m. Feb. 23, Texas Christian University, School of Geology, Energy and the Environment, Fort Worth, TX.
•  4 p.m. March 9, Florida A&M University, High Performance Materials Institute, Tallahassee, FL.

After leaving South Carolina, the SolarWorld GT will head on to Europe, Africa, and Asia. The final leg of the trip will be back in Australia later this year.

Source: Clean Technica (http://s.tt/15wZ1)

SOURCE: http://cleantechnica.com/2012/02/03/the-worlds-prettiest-solar-car-drives-through-america/

Harnessing Nature’s Solar cells

Within a few years, people in remote villages in the developing world may be able to make their own solar panels, at low cost, using otherwise worthless agricultural waste as their raw material.

Andreas Mershin

That’s the vision of MIT researcher Andreas Mershin, whose work appears this week in the open-access journal Scientific Reports. The work is an extension of a project begun eight years ago by Shuguang Zhang, a principal research scientist and associate director at MIT’s Center for Biomedical Engineering. Zhang was senior author of the new paper along with Michael Graetzel of Switzerland’s École Polytechnique Fédérale de Lausanne.

In his original work, Zhang was able to enlist a complex of molecules known as photosystem-I (PS-I), the tiny structures within plant cells that carry out photosynthesis. Zhang and colleagues derived the PS-I from plants, stabilized it chemically and formed a layer on a glass substrate that could — like a conventional photovoltaic cell — produce an electric current when exposed to light.

But that early system had some drawbacks. Assembling and stabilizing it required expensive chemicals and sophisticated lab equipment. What’s more, the resulting solar cell was weak: Its efficiency was several orders of magnitude too low to be of any use, meaning it had to be blasted with a high-power laser to produce any current at all.

Now Mershin says the process has been simplified to the point that virtually any lab could replicate it — including college or even high school science labs — allowing researchers around the world to start exploring the process and making further improvements. The new system’s efficiency is 10,000 times greater than in the previous version — although in converting just 0.1 percent of sunlight’s energy to electricity, it still needs to improve another tenfold or so to become useful, he says.

The key to achieving this huge improvement in efficiency, Mershin explains, was finding a way to expose much more of the PS-I complex per surface area of the device to the sun. Zhang’s earlier work simply produced a thin flat layer of the material; Mershin’s inspiration for the new advance was pine trees in a forest.

Mershin, a research scientist in the MIT Center for Bits and Atoms, noticed that while most of the pines had bare trunks and a canopy of branches only at the very top, a few had small branches all the way down the length of the trunk, capturing any sunlight that trickled down from above. He decided to create a microscopic forest on a chip, with PS-I coating his “trees” from top to bottom.

Turning that insight into a practical device took years of work, but in the end Mershin was able to create a tiny forest of zinc oxide (ZnO) nanowires as well as a sponge-like titanium dioxide (TiO2) nanostructure coated with the light-collecting material derived from bacteria. The nanowires not only served as a supporting structure for the material, but also as wires to carry the flow of electrons generated by the molecules down to the supporting layer of material, from which it could be connected to a circuit. “It’s like an electric nanoforest,” he says.

As an bonus, both zinc oxide and titanium dioxide — the main ingredient in many sunscreens — are very good at absorbing ultraviolet light. That’s helpful in this case because ultraviolet tends to damage PS-I, but in these structures that damaging light gets absorbed by the support structure.

Mershin thinks that because he and his colleagues have now lowered the barrier to entry for further work on these materials, progress toward improving their efficiency should be rapid. Ultimately, once the efficiency reaches 1 or 2 percent, he says, that will be good enough to be useful, because the ingredients are so cheap and the processing so simple.

“You can use anything green, even grass clippings” as the raw material, he says — in some cases, waste that people would otherwise pay to have hauled away. While centrifuges were used to concentrate the PS-I molecules, the team has proposed a way to achieve this concentration by using inexpensive membranes for filtration. No special laboratory conditions are needed, Mershin says: “It can be very dirty and it still works, because of the way nature has designed it. Nature works in dirty environments — it’s the result of billions of experiments over billions of years.”

Because the system is so cheap and simple, he hopes this will become a “way of getting low-tech electricity to people who have never been thought of as consumers or producers of solar-power technology.” He hopes the instructions for making a solar cell will be simple enough to be reduced to “one sheet of cartoon instructions, with no words.” The only ingredient to be purchased would be chemicals to stabilize the PS-I molecules, which could be packaged inexpensively in a plastic bag.

Essentially, Mershin says, within a few years a villager in a remote, off-grid location could “take that bag, mix it with anything green and paint it on the roof” to start producing power, which could then charge cellphones or lanterns. Today, the most widely used source of lighting in such locations is kerosene lanterns — “the most expensive, most unhealthy” form of lighting there is, he says. “Nighttime illumination is the number one way to get out of poverty,” he adds, because it enables people who work in the fields all day to read at night and get an education.

Babak Parviz, an associate professor of electrical engineering at the University of Washington who specializes in bionanotechnology, says this is “a very exciting paper and a very nice step toward integrating biomolecules for building solar cells. This shows a very promising and creative first step toward building organic photovoltaic cells that can use biologically (naturally) produced cores.” He adds that while the present system still needs further development, “further work in the field can perhaps improve the stability and performance of these devices.”

The research was funded in part by an unrestricted grant from Intel Corp., and also included researchers at the University of Tennessee.

SOURCE: http://web.mit.edu/newsoffice/2012/biosolar-0203.html

Kodak’s New Film: Solar

It has been a rough several years for Eastman Kodak, the 120-year-old film and, now, digital imaging company. The pain intensified last week with the announcement that the iconic company will endure a painful bankruptcy restructuring and a US$950 million lifeline of financing from Citibank. While its 1993 spinoff, Eastman Chemical, has thrived and become a Fortune 500 company, Kodak has sputtered. The company sat on the digital technology one of its employees invented in 1975, and years later, when its management realized that Asian companies could produce superior digital products for far cheaper, Kodak’s market dominance had disappeared. Meanwhile, its long and heated rivalry with Fuji became a one-sided smackdown with the Japanese competitor coming out far ahead.

Natcore Technologies, one of Kodak’s last hopes

But could Kodak come back? One opportunity lies in thin-film solar technology. The company is partnering with Natcore Technologies, a New Jersey-based startup, to create flexible solar cells.

The process involves using a liquid phase deposition process that covers carbon nanotubes with solar semiconductor material. The results are microscopic thin and flexible solar cells. Natcore, which was awarded a patent for the process last fall, says that this technique could be just as efficient as the conventional silicon cells currently on the market, but would be cheaper to manufacture. In fact, the cost could be reduced as much as half, because they could be produced on Kodak’s equipment that at one time churned out photographic film. While thin film solar has created excitement among solar aficionados, its efficiency still lags behind the dominant silicon offerings available.

Some experts say that no matter how advanced the technology is, there are hurdles to bringing the product to market. An oversupply of solar panels, in part because of cheap exports from China, have resulted in low prices. Investors, however, are bullish on Natcore’s potential and closed on a private placement deal last week. With a bevy of startups entering the solar market, and established companies including Panasonic and Dow looking to revamp their business models, the future looks great for solar energy customers. Companies in this crowded space, however, face a highly competitive landscape and thin profits.

For Natcore, its potential looks bright if its flexible and efficient solar product can scale. Kodak, however, is on thin ice. Close to selling off some of its lucrative patents, and having one year to submit a reorganization plan to bankruptcy court, the former camera and film giant will need more partners like Natcore to keep from shuttering. Kodak’s culture of complacency and arrogance will also have to change; there is no mention of Natcore on its own site.

SOURCE: http://www.triplepundit.com/2012/01/kodak-natcore-film-solar/

Jacksonville Police Cars Charge on Solar Power

Solar charging panels on some police cars allow officers to take advantage of sun power.

The average police car drains two 12-volt batteries a year due to all of the electronics and lights it has to operate. The solar panels help save gas too, said Assistant Chief John Lamb, in charge of the Sheriff's Office's logistics and general support division.

"We wanted to look for alternatives to combat the problems and solar is free," Lamb said.

The basic Chevrolet Impala police cruiser packs a 230-horsepower V-6 gasoline engine with a heavy-duty 12-volt battery. Add spotlights, flashlight charger, radio and emergency lights as well as laptop computer, and that can tax the battery. Replacements can cost hundreds of dollars including labor.

"Even when the car is off, it drains the batteries," said Anthony Turley, fleet coordinator for the Sheriff's Office.

Chevrolet doesn't offer the solar panels as a factory option on its police cars. But other police departments nationwide have added them aftermarket, including Kingsland, Ga., which installed 5-watt solar panels on its 45 patrol cars in 2010. They cost $60 each, funded with seized drug money.

Turley checked out Kingsland's cars, and the decision was made to add solar panels to the equipment installed on the last 90 Jacksonville patrol cars purchased, as well as on some unmarked cars. They cost $311 for a smaller unit atop a patrol car's light bar and $275 for larger ones put on the unmarked car's trunks.

"We were trying to see not just what was cost-effective but also gave the most solar energy," Turley said.

The solar chargers gave the car's 12-volt battery enough juice to run emergency lights for three hours with the engine off and still have power to start it, he said. But when cuts had to be made to the 2012 Sheriff's Office budget, the solar chargers were deleted from the next round of police car purchases.

Turley still found another way to cut back on battery costs. A $65 PriorityStart! module automatically disconnects a cruiser's 12-volt battery if voltage drops below 11.2 volts. Tested on a cruiser parked for four months, it still started, Turley said.

"We took such a hit with the budget," Lamb said ". It made sense to cut the solar panels and make up some of that difference."

Solar power hasn't set totally yet. Lamb said smaller solar chargers that can be put on a dashboard and plugged into the cigarette lighter are being used to trickle charge batteries.

SOURCE: http://www.news4jax.com/news/Jacksonville-police-cars-charge-on-solar-power/-/475880/8481652/-/4286ryz/-/index.html