Australia announces backing for researchers of solar energy

The Australian government awarded researchers specializing in solar power almost A$1.3 million ($1.3 million) to develop technologies to make the energy source more efficient and cost effective.

The grants are part of the government’s Skills Development Program, resources minister Martin Ferguson said in an e-mailed release today.

“From techniques to improve the efficiency of solar cells made from low-cost and readily available organic materials, to investigating ways to optimize hybrid solar-diesel systems in remote areas using smart grids, the Skills Development Program is helping to drive Australian solar innovation,” Ferguson said in the statement.

Renewable energy sources generated enough electricity to power the equivalent of more than 4 million average Australian households in the 12 months ended in September, according to a report by the Clean Energy Council, an industry association.

Hydro electricity accounts for about two-thirds of Australia’s energy from renewables, followed by wind, bioenergy and solar power from photovoltaic sources, the council says.

Australia is in the midst of efforts to cut carbon emissions that the government says are the highest per capita in the developed world.

Coal generated 77 percent of the nation’s electricity in 2009 and 2010, while natural gas accounted for about 14 percent, according to data from the Energy Supply Association of Australia.

Solar Energy Corpn to set up demonstration plants

The newly set up Solar Energy Corporation of India intends to set up a few ‘demonstration plants’, to engender home-grown solar technologies, the Chairman of the Corporation, Dr Anil Kakodkar, told Business Line on Thursday.

The not-for-profit, “Section 25 company”, with an authorised capital of Rs 2,000 crore, has a broad mandate to develop the solar industry in India and to implement the next phases of the National Solar Mission, which is one of the eight National Missions taken under the National Action Plan for Climate Change.

The Corporation is thinking of MW-scale plants, of say, 5 MW, that would adopt global available solar technologies to suit Indian conditions. The first of such plants could come up near an existing R&D centre with sufficient human resources to tap, Dr Kakodkar said, without giving more details.

He said that the objective would be to bring down costs so that solar power is not costlier than conventional power.

Asked for examples of technologies that he had in mind, Dr Kakodkar mentioned variants of concentrated solar power and dust-control innovations.

He noted that it is possible to have large solar collectors on which sun’s rays would fall, then move along the plane of the collectors and finally be gathered into a PV module. Another variant of CPV that he described was like a combination of tower and PV-mirrors would reflect sunlight on to a reflector on a tower which would in turn beam the rays back on to a PV panel on the ground.

Dr Kakodkar, a nuclear scientist, who headed the Atomic Energy Commission a few years ago, drew a parallel between such solar technologies that could be indigenously developed, and the ‘pressurised heavy water reactors’ that India developed and became masters in, in the atomic energy field.

In the 1970s, when India was denied technology and fuel, the country developed the PHWR type reactors that use Uranium economically. Today, the PHWRs are very competitive.

“Our approach in solar would be driven by that logic,” Dr Kakodkar said.

Answering a question, he said he was in favour of developing a domestic solar equipment industry.

Asked what role the Corporation would have in the upcoming Phase-II of the National Solar Mission, Dr Kakodkar said that the Corporation could own some solar projects. However, they would not be “run of the mill” plants, but those that would demonstrate an evolving technology, he said.

Dr Kakodkar seemed to see a big role for the Corporation in socially-oriented areas such as rural electrification, micro grids and solar lanterns.

He said that the Corporation was working on a ‘public energy outlet’ model. Giving an example to illustrate this he said that it was possible to have a solar plant on the rooftop of, say, a school, where children could bring their solar lamps for charging during the day. These lamps would light up their homes during the nights.

6 solar stocks reacting to a changing market

Solar energy has been harnessed by humans since the beginning of time. Humans first used solar energy to dry food and clothes. The sun has produced energy for billions of years, where a very small part of it reaches the earth. With the Obama administration promising to take on global warming and lessen the country's dependence on foreign oil, renewable energy may be the answer. Wind turbines, geothermal plants and bio-fuel plants will be important contributors. Ultimately, the most abundant form of energy comes from the sun.

A study by the International Energy Agency (IEA) in 2011 revealed that "the development of affordable, inexhaustible and clean solar energy technologies will have huge longer-term benefits. It will increase the energy security of many nations through reliance on an indigenous, inexhaustible and mostly import-independent resource. Furthermore, solar energy will enhance sustainability, reduce pollution, lower the costs of mitigating climate change, and keep fossil fuel prices lower. These advantages are global. Hence, the additional costs of the incentives for early deployment should be considered learning investments. They must be wisely spent and need to be widely shared."

First Solar (FSLR) recently disclosed that it will build two utility-scaleplants in Australia, which represents 159 megawatts of production. The next day, shares of First Solar rose by 17%. First Solar also benefited from the announcement that it will delay the plant closing in Frankfurt, Germany, by about three months due to an increase in demand for solar modules in Europe. First Solar's stock value has dropped around 85% over the past year, from a 52-week high of $142 in June 2011. The company's operating cash flow has hovered around -$5.8 million.

Heavily indebted JA Solar Holdings (JASO) also recently announced that it will buy back its shares before the end of September 2012. JA Solar Holdings has lost nearly half its market value in the past five months. The announcement of a buyback program of up to $100 million sent the stock up 25% within the day. Other solar energy companies, such as LDK Solar (LDK), Yingli Green Energy Holding (YGE) andReneSola (SOL), have also been buying back shares as share prices go down. JA Solar Holdings posted revenue losses for the past year as solar panel prices dropped due to declining subsidies given by different government organizations to renewable energy usage. JA Solar Holdings has 195.8 million shares outstanding, with a market capitalization of $219 million and an enterprise value of $590 million. Its first-quarter revenue declined by 56% year-on-year, which equated to a trailing twelve month (TTM) diluted earnings per share of -$1.15. The current partnership will not make a great impact in the market for the short term, as many investors see buybacks such as this as a band-aid solution to revenue problems.

Trina Solar (TSL) recently presented its new Honey Ultra module, a second-generation model of Trina Solar's Honey technology, which generated 284.7 watts peak power when tested in May. The company also unveiled Trinasmart, a new power optimizer and monitoring solution. System performance can be monitored and controlled in real time with a web-based Trinasmart platform. The new platform can be accessed using a smartphone or an internet connected computer. Additionally, the platform improves the safety of PV systems by automatically shutting down affected PV modules in case of electrical failure or malfunctions. Moreover, in case of an external fire, the modules can be cut off via remote control. Commercial availability of Trinasmart is scheduled for September 2012. Trina Solar has over 70.5 million shares outstanding, a market capitalization of $501 million, and enterprise value of $998 million.

In the first quarter of 2012, developers installed 85% more solar panels than last year in the U.S. alone. According to the Solar Energy Industries Association, the total U.S. installations were 506 megawatts and may reach 2,200 megawatts by year end, around 11 percent of the global market.

Schools around the country are one of the many catalysts that turned to solar energy to lower operational cost. More than 500 schools have installed solar panels over the past years. The waning prices of solar panels by almost 35% in the past years made the technology more affordable. Solar power is often cheaper than the retail cost of electricity in most states. Costs have fallen because manufacturers have increased production, creating a surplus of solar panels. With surplus in production and technological advances that increased capability to generate power by almost four times in the past five years, demand for solar power has surged.

India has recently inaugurated its newest solar park in Gujarat. The solar park is expected to produce 214 megawatts, surpassing China's Golmud Park. In 2010, India decided to increase the capacity of solar power from virtually zero to 20,000 megawatts by 2022. The targets are attracting developers around the world as private companies in New Delhi are mandated to source 15% of energy needs from green resources by 2022.

Japan just this morning, June 18, 2012, announced a premium price for solar electricity, which is about three times the conventional power. Analysts say that this could spur at least $10 billion in new installations. The Japanese government desire to bring down the country's reliance on atomic energy will help the solar industry, which is dwindling in the past quarters due to incentive cuts in Europe and over production. Japanese companies such as Kyocera (KYO) and Sharp are gearing up to supply the country, as the government eyes solar energy as an important energy source.

The solar industry has struggled in the recent years, as increased competition created a surplus in the market, which in turn forced the prices lower. The lower prices have prompted a number of U.S. solar companies to limit production or even file for bankruptcy. Last month, the U.S. imposed a 31% duty on solar panel imports to curb the increasing number of cheap Chinese products that are entering the market.

I expect the demand for solar energy in the U.S. and Europe to decline in the second half of the year mainly due to the economy, but growth in India, Japan, China and other areas could prove to be significant in the coming years. I suggest holding onto solar energy stocks.

Tamil Nadu keen to tap solar power in a big way

The State government was working on a draft solar policy that would provide an immense thrust to power generation from solar power sources. It had embarked on a major initiative to energise streetlights and houses through solar energy, said S.E.S. Syed Ahamed, Deputy General Manager of Tamil Nadu Energy Development Agency (TEDA). 

The draft solar policy, under the consideration of Chief Minister Jayalalithaa, envisaged generating 3,000 MW through solar parks and roof-top solar power systems that would power houses. He informed this while addressing ‘Energy Acme 2012,’ a conference on energy management and renewable sources organised here on Friday by the Confederation of Indian Industry (CII), Madurai Zone.

Tamil Nadu had the potential to generate at least solar power to the tune of 20 to 30 MW per square kilometre and another 20,000 MW through wind sources. Already, India occupied the fifth place globally in wind power generation with Tamil Nadu having the highest installed capacity of windmills for any State. Many foreign investors had expressed interest in investing in renewable energy in the State.

Further, he said that Tamil Nadu had the honour of hosting the first ever 5 megawatt (MW) solar photo voltaic (SPV) power of India at Sivaganga where Sapphire Industrial Infrastructure, a subsidiary of Moser Baer, had established a plant at a cost of Rs. 110 crore. Deploring the tendency of alternative energy power developers to depend on the government largesse, Mr. Syed said that disbursement of subsidies was problematic. 

Also, policy changes in the future could result in subsidies being done away with. Noting that soon it might be made mandatory for industries to use solar power, he said that three ways were being mulled: direct installation of solar plants at industrial units; purchase of power at renewable energy rates fixed by the Tamil Nadu Electricity Regulatory Commission; and third party sales. P. Sundararajan, convenor of manufacturing panel, CII, Madurai Zone, said that constrains always boosted efficiency. Industries have adapted to power crisis. N. Krishnamoorthy, chairman, CII, Madurai Zone, spoke.

Shri Sushil Kumar Shinde Inaugrates Solar AC System At NTPC

NTPC is adopting new technologies for promoting green energy said Shri Sushil kumar Shinde, Union Minister of Power, while inaugurating the Solar Thermal Heating Ventilation & Air Conditioning System (HVAC) at the NTPC Energy Technology Research Alliance (NETRA ), the research wing of NTPC today . He called for use of latest technology for efficiency improvement and appreciated NTPC’s efforts towards conservation and protection of the environment. Shri Arup Roy Choudhury, CMD , NTPC , Shri Ashok Lavasa , Addl. Secretary Power and senior officials of Ministry of Power and NTPC were present on the occasion.

In his address , Shri Ashok Lavasa, Addl. Secy, Ministry of Power said that successful companies not only excelin their core area but also in the areas of R&D and human capital and hewas glad to note that NTPC is following the same model. Shri Arup Roy Choudhury , CMD, NTPC , reiterated NTPC ‘s commitment to adopting super critical technology in all its upcoming plants for both efficiency and environmental sustainability so as to keep with the global standards.

The Solar Thermal HVAC system is low carbon, green house gas free AC solution. It has an efficiency of 80%, consumes less auxiliary power and occupies less area compared to the conventional AC system.

For NETRA, improving the availability, reliability and performance of the existing power stations and new power plants is not only a priority but a challenge also. Development of New & Renewable Energy sources is another key area of research and technology development at NETRA. With depleting fossil fuels the alternate sources of energy are expected to play a dominant role. NETRA provides high-end Scientific Services to NTPC Stations and other Utilities to improve their availability, reliability and performance by solving their generic & specific problems.

NTPC is India’s largest power utility, playing a major role in meeting the power needs of the country and contributing to its economic and social development. The present installed capacity of NTPC is 39174 MW comprising of 16 coal based stations, 7 combines cycle gas/ liquid fuel based stations and 7 JV stations ( 6 coal based and 1 gas based).NTPC plans to become a 1,28,000 MW company by 2032

Solar installation costs down dramatically since 2010

The cost of solar installations in all sectors has decreased by a significant amount in the past two years. According to a recent Motley Fool article, the cost of residential installations such as rooftop solar have gone down by 15.6 percent since the first quarter of 2010. The cost reductions are even higher for non-residential solar, which saw a 27.2 percent decrease, and utility-scale solar saw the greatest decrease at 54.8 percent.

"Despite the performance of solar stocks over the past two years, the fundamental cost of installing solar power continues to fall rapidly," the article states. "Long term, this is great for the industry and should drive sales and eventually (surviving) solar stocks higher in the future."

The article highlighted the United States Department of Energy's SunShot program, which is an initiative designed to make solar installation less expensive by funding permit-streamlining and other efforts. For example, the program recently awarded funding to Tigo Energy to develop photovoltaic cell optimizing software.

"Module-level data is essential to truly understanding and utilizing the full potential of solar," said Sam Arditi, CEO, Tigo Energy. "Software is a critical component in optimizing solar arrays and bringing down ownership costs. This DOE award allows us to develop the most efficient system based on our extensive data with the lowest associated costs."

The $500,000 award will be used to develop analytics tools to measure and manage PV systems. According to Tigo, the software will be able to identify faults in solar systems and the benefits of repairing those systems by comparing service costs to the value of the energy that would be lost if the faults were not repaired. This is the second SunShot award the company has won, the first being $3 million for a new, low-cost DC arc-fault detector.

Tigo and several other companies plan to showcase solar technology at Intersolar North America 2012, held July 9 through 12. The event will feature exhibits such as PV Energy World, which is partially supported by the California Energy Storage Alliance. PV Energy World is designed to share information and display technology in the area of energy storage. According to CESA, energy storage plays a crucial role in accelerating renewable energy adoption.

"Energy storage offers the solar industry the opportunity to bring several goals to fruition, including faster grid interconnection, more precise timing of output, fewer curtailment and imbalance penalties, and the potential to secure valuable new revenue from wholesale ancillary services and capacity markets," said Janice Lin, executive director of CESA. Lin indicated advancements in energy storage would provide huge benefits to the California solar installation industry.

Delhi govt ‘least bothered’ about clean, solar energy

The Delhi government is one of the least supportive state governments in promoting solar projects, according to officials of the new and renewable energy ministry at a conference on Friday.

Revising the subsidy system, maintenance and accreditation of solar products are essential to ensure that all villages get electricity by 2020, said experts at a meet on ‘Solar Power and Challenges Ahead’, organised by the Centre for Science and Environment (CSE). 

G Prasad, a scientist with the ministry, said that despite funds released by the union ministry for off-grid solar projects for electricity, street-lighting and liquid electronic display lamps, several state governments are uncooperative in encouraging people to use them. According to Prasad, only 0.20 per cent solar projects have been sanctioned in 2011-2012 in Delhi under the Jawaharlal Nehru Solar Mission. 

The Delhi government has sanctioned only 2.50 MW solar plants in an entire decade, while during the same period, Gujarat has sanctioned 654.80 MW solar plants.

“Although there are some problems, such as high capital cost for mini grids and collection of monthly charges from users, the main issue is the attitude of state governments towards these problems,” said Prasad. “But these initiatives were considered hoping that state governments would support us,” added Prasad.

Gireesh B Pradhan, secretary of renewable energy ministry, said they are doing a serious revamp of the off-grid solar programme. “CSE’s recommendations will help us to a great extent. We need to tap into all sort of energy resources to ensure that we get adequate electricity,” he said.

According to experts, so far only five states  Assam, Uttarakhand, Chhattisgarh, Haryana and parts of
 Uttar Pradesh  have been successful in tapping solar energy. 

Target 2020

India has a target of providing electricity with the help of renewable energy sources to 145 million households by 2020 across the country, as per CSE’s estimates. 

“Though the number of households using solar energy in villages has been increasing since 2001, the number of houses with no lighting has also doubled,” said Joel Kumar, a researcher with CSE. “Most solar energy users tend to overload systems as there is absolutely no sensitisation,” said Kumar.

Sunita Narain of CSE said India needs to ensure that phase-2 of the National Solar mission heads in the right direction, unlike phase-1.

“The biggest barrier to any innovation is that there is no accreditation of products. We also need to ensure that a model of maintenance is in place. If the Chhattisgarh government can provide maintenence without any issues, why can’t other state governments follow a similar model?” she said.

Encourage now

Experts suggested that small power producers in all states should be encouraged to come forward. 

“Rural India will take the lead in developing a truly smart grid solar ‘photo voltage’, if small players are allowed to expand. ‘Photo voltage’ are domestic solar appliances that can be installed in households.

“Banks are not willing to work with solar project providers because of marginalised incentives,” said Hari Natarajan, chief executive officer of infrastructure development fund agency S3IDF. 

He said most off-grid solar models are fixed and customers are not given a chance to explore all options. 

However, both government officials and solar energy experts say that with falling prices of solar products, India will get better access to renewable lighting and reduce dependency on kerosene lamps in rural areas.

NY adopts CO2 rules that limit new coal power plants

 New York environmental regulators on Thursday adopted carbon dioxide emissions (CO2) limits for new and expanded power plants that are slightly stricter than proposed federal limits and make it nearly impossible to build a new coal unit in the state.

There are no coal plants under active development in New York, which currently has about two dozen coal units -- some very old, small and rarely operated -- capable of generating about 2,800 megawatts (MW) of power.

"By preventing new high-carbon sources of energy, this performance standard will serve to further minimize the power sector's contribution to climate change, which poses a substantial threat to public health and the environment," Joseph Martens, Commissioner of the New York State Department of Environmental Conservation (DEC), said in a release.

The new regulation will take effect July 12.

The New York regulations establish CO2 emission limits for proposed new major power plants that have a generating capacity of at least 25 MW, and for increases in capacity of at least 25 MW at existing facilities.

One megawatt can power about 1,000 homes.

The New York regulations set a CO2 limit of 925 lbs per megawatt-hour for most new or expanded base load fossil fuel-fired plants, and a limit of 1450 lbs/MWh for simple-cycle combustion turbines.

Energy analysts have said coal plants produce more than 1000 lbs/MWh of CO2, so the rules would prevent the construction of new coal plants unless they had carbon capture and storage systems installed.

Base load plants, which have historically been coal and nuclear powered, usually operate 24 hours a day, seven days a week. Simple-cycle natural gas turbines generally operate during the summer and winter peaks.

But with natural gas prices touching 10-year lows this spring, many utilities have opted to turn to combined-cycle gas-fired units to generate around-the-clock power instead of coal.

After the DEC proposed its CO2 regulation in January, the U.S. EPA in April proposed a federal CO2 New Source Performance Standard under the federal Clean Air Act.

EPA's proposal contains a primary CO2 emission standard of 1000 lbs/MWh.

New York's biggest coal plants are owned by NRG Energy Inc , which is looking to repower or mothball its plants, and units of AES Corp and Dynegy Inc, which are involved in bankruptcy proceedings.

Waste to energy markets to grow 11.2% annually through 2021: SBI Bulletin

 Industrial and energy market research publisher SBI has released a research study on the global Waste to Energy (WtE) market, revealing the market increased from $4.8 to $7.1 billion during the 2006-2010 historical period, with a compound annual growth rate (CAGR) of 8.0%. The study also projects the market will post a CAGR of 11.2% from 2011 through 2021, growing from $8.5 to $27.2 billion.

The report, SBI Bulletin: Waste to Energy Technologies, Market Size and Growth: 2006-2021, breaks down the WtE industry with discussions of the historic market for WtE technologies and estimates for the future market from 2011 through 2021. The specific methods used for assessing the market size and trends are included in the study, as well as summaries of the major market factors that are expected to influence the growth of the market through 2021.

"During the 2006 through 2010 historic period, approximately 95% of the global WtE market was accounted for by only two technologies: incineration and anaerobic digestion," SBI Bulletin analyst Robert Eckard notes. "However, pyrolysis, plasma gasification, and gasification are expected to gain relative market share, and together will comprise over 30% of the total WtE market by 2015."

SBI Bulletin: Waste to Energy Technologies, Market Size and Growth: 2006-2021 examines the markets for incineration, gasification, plasma gasification, pyrolysis, and anaerobic digestion. Markets are reviewed by global region, with additional discussions of market factors relevant to specific countries and/or sub-regional areas.

Five real-world facts about electric cars

Last year, roughly 17,000 plug-in cars were sold in the United States—more than were sold in any year since the very early 1900s. But to put that number in perspective, total sales in 2011 were 13 million vehicles, meaning that plug-in cars represented just one-tenth of 1 percent. Sales this year will likely be double or triple that number, but it remains a stretch to reach President Obama’s goal of 1 million plug-ins on U.S. roads by 2015.

Both the Nissan Leaf and the Chevrolet Volt sold more units last year than the Toyota Prius did in 2000, its first year on the U.S. market. But 12 years after hybrids arrived in the U.S., they now make up just 2 to 3 percent of annual sales—and about 1 percent of global vehicle production.

Automakers are understandably cautious when committing hundreds of millions of dollars to new vehicles and technologies. They worry that a lack of public charging infrastructure will make potential buyers reluctant to take the chance on an electric car. Moreover, each factory to build automotive lithium-ion cells—an electric-car battery pack uses dozens or hundreds of them—costs $100 to $200 million. Battery companies will only build those factories if they have contracts in from automakers, who will only sign contracts to boost production if they can sell tens of thousands of electric cars a year in the first few years.

Eight to 10 years from now, most analysts expect plug-ins to be roughly where hybrids are today: 1 to 2 percent of global production, with highest sales in the most affluent car markets (Japan, the U.S., and some European regions). That translates to perhaps 1 million plug-in cars a year. There are, by the way, about 1 billion vehicles on the planet now.

The adoption of increasingly strict U.S. corporate average fuel-economy rules through 2025, however, will spur production of electric vehicles. And California has just passed rules that require sales of rising numbers of zero-emission vehicles, on top of the Federal regulations.

(2) There are several different types of cars that plug in, and their electric ranges vary.

The two main plug-in cars that went on sale last year, the Nissan Leaf and Chevy Volt, use somewhat different technologies, and this year will see a third variation arrive, the 2012 Toyota Prius Plug-in Hybrid. Each works slightly differently, and their electric ranges vary considerably, roughly proportional to the size of their battery packs.

The Nissan Leaf is a “pure” battery electric vehicle. It has a 24-kilowatt-hour battery pack (it uses 20 kWh) that delivers electricity to the motor that powers the front wheels for 60 to 100 miles. That’s it. On the plus side, this is the simplest setup of all, and battery electrics require very little servicing beyond tires and wiper blades. On the minus side, if the driver is foolish enough to deplete the battery—the car makes strenuous efforts to warn against this—the car is essentially dead until it can be recharged.

The Chevrolet Volt is a range-extended electric vehicle. It has a 16-kWh battery pack (of which it uses about 10 kWh) that powers an electric drive motor for 25 to 40 miles. Once the pack is depleted, a gasoline “range extender” engine switches on, not to power the wheels but to turn a generator to make more electricity to power the drive motor that makes the car go. The 9-gallon gas tank provides about 300 more miles of range, and the Volt can run in this mode indefinitely. But 78 percent of U.S. vehicles cover less than 40 miles a day, so many Volts that are plugged in nightly may never use a drop of gasoline.

Finally, the new plug-in Prius is known as a plug-in hybrid. It too has an electric drive motor and a gasoline engine, and its 4-kWh battery pack gives 9 to 15 miles of electric range. But like all hybrids, the gasoline engine switches on whenever maximum power is needed, so even if the battery pack is fully charged, those fast uphill on-ramp merges mean the engine will fire up for maximum power. Toyota says that if it’s plugged after each trip, many drivers can cover more than half their mileage on electric power.

Today, all three cars cost $35,000 to $40,000 before tax incentives. That’s up to twice as much as a gasoline car of the same size. And each one has pros and cons. The Leaf has the longest electric range, and will never emit a single pollutant. The Volt offers the quiet, quick pleasure of driving electric, but with unlimited range. And the Prius Plug-In brings low charging time and higher electric range to the familiar, trusted Prius range.

(3) In the early years, most charging will be done in garages attached to private homes.

There will soon be more public charging stations than there are gas stations in the U.S. That’s a little deceptive, since most gas stations have a dozen or so pumps, while the electric-car charging stations have one or two cables. But it points out the relatively low cost and fast installation pace of charging stations, aided in some cases by Federal incentives.

Nonetheless, ask any automaker and they will tell you they expect the bulk of electric-car recharging to occur overnight at charging stations installed in garages attached to private homes. And electric utilities very much want that to happen as well. Charging overnight, during their period of lowest demand, has many advantages: It can stabilize the distribution system, and it represents new demand and new business for them. Many utilities are launching rate plans that incentivize overnight charging, to discourage daytime charging that might occur when the load from factories, home air conditioners, and the like is highest.

Another unknown is whether and how much electric-car drivers will expect to pay for public charging. At 10 cents per kilowatt-hour, it costs about $2 to fully charge a Nissan Leaf for 70 to 100 miles. But 2 hours of charging, or 20 to 25 miles’ worth, takes less than a dollar of electricity. So what will drivers pay? A buck? Five bucks? The market will tell us, in time.

In the end, public charging is likely to be like public WiFi. In some places, it’ll be provided free as an amenity (think big-box stores who’d love to trade 50 cents of electricity for the opportunity to keep you in their building for a couple of hours). In others, providers will mark up the power and owners will pay for the convenience (think pricey city-center parking lots that charge $25 or more a day).

But early adopters of electric cars will already have navigated local zoning codes, home wiring changes, and contractor visits to get their own 240-Volt “Level 2” charging stations installed. Owners can get their electric cars to remind them—via text message or e-mail—if they forget to plug in to recharge at night. Soon, plugging in the car may be just as unremarkable as plugging in a mobile phone every night.

(4) You have to consider where and how you use your car(s) if you consider buying electric.

Plug-in cars are not for everyone. They still cost more than the gasoline competition, though their running costs are far lower. And the limited range of battery electric cars may make them impractical for households with only a single vehicle. Range-extended electrics and plug-in hybrids solve that problem, but the complexity of two powertrains plus the pricey battery pack makes them more costly than regular hybrids.

Potential buyers should consider two factors: range and climate. If the miles you cover each day in your car are highly variable, electric cars may cause more “range anxiety” than if you commute the same predictable daily distance. If you drive much more than 60 miles round-trip during a day, a battery electric like the Leaf won’t do it.

And the range of an electric car falls significantly in cold weather. Hybrid owners in cold climates already know their gas mileage goes down each winter; electric cars exhibit the same pattern. Batteries are pretty much like humans; they like to live around 70 degrees. If it’s a lot colder, they’re simply not able to deliver as much power. Worse, it takes a lot of battery energy to heat the cabin in winter—though a bit less to run seat heaters, which is how electric car designers try to keep occupants comfortable without having to warm up the entire interior.

In early years, most plug-ins will likely be sold to affluent buyers who have two or three cars in the household. And a disproportionate number of them will live in California. By some estimates, sales of electric cars within Californiawill total those of the next five states put together.

(5) Electric cars are cheaper to “fuel” per than gasoline cars, and they have a lower carbon footprint too—even on dirty grids.

Retail car buyers act irrationally. Often, we more car than we really need, and we also put too much weight on initial purchase price—or the monthly payment—and not enough on the total cost of ownership, including maintenance and fuel cost.

Fleet buyers, on the other hand, are hard-nosed spreadsheet jockeys. They’ll pay more up front for a car if they save money over its entire lifetime. And electric cars can be a fleet buyer’s dream. Battery electric cars require almost no maintenance—tires and wiper blades are about it. Even brake pads and disks last far longer, because the car is slowed largely by “regenerative braking,” or the resistance provided when the electric motor is used as a generator to recharge the battery pack.

Best of all, they’re incredibly cheap to run on a per-mile basis. Electricity costs from 3 to 25 cents per kilowatt-hour in the U.S., but at 10 cents per kWh, fully charging a Nissan Leaf for 70 to 100 miles costs a little more than $2. Those 100 miles would cost $12 in gasoline in a conventional car that gets 33 mpg, with gas at $4 a gallon. Over 10,000 miles a year, that could be $1,000 in savings. Nissan warranties its battery pack for 8 years or 100,000 miles, so you might be looking at savings of close to $8,000 in fuel costs, plus the lower lifetime maintenance cost. Does that make up for the price differential between a Leaf and a regular compact car? Not completely. But knock off the $7,500 Federal tax credit, and you get closer. Many states, localities, and corporations offer additional incentives as well.

Ten years hence, lithium-ion cells will likely cost about half what they do today. Gasoline cars, on the other hand, will be more expensive in real dollars due to the cost of more efficient gasoline engines. Those gasoline cars will get better fuel economy, but battery costs are likely to fall faster (6 to 8 percent a year) than fuel economy will rise (3 to 5 percent).

Then there’s the environmental argument. A well-respected 2007 study done jointly by the Electric Power Research Institute (EPRI) and the Natural Resources Defense Council (NRDC) analyzed the “wells-to-wheels” carbon emissions of driving a mile on gasoline versus driving that same mile using grid electricity. Against a 25-mpg car, an electric car was lower in carbon even if it were recharged on the nation’s dirtiest grids, using almost entirely coal power.

Up the ante to a 50-mpg car (e.g. today’s Toyota Prius), and on a few of those dirty grids, the carbon profile of 1 mile on gasoline in a Prius is slightly lower than on grid electricity. But in coastal states whose grids are relatively cleaner, electric cars are a win on emissions and greenhouse gases against any gasoline car at all.

Sky Solar to invest $900m in Chilean PV project

The facilities will be built in cooperation with the China Development Bank and Sigdo Koppers.

Sky Solar plans to break ground later this year on a 2MW pilot project, followed by an 18MW ground-mounted development.

The aim is for all the plants to be built at grid-parity, with no need for government support to make their operation commercially viable.

After the initial constructions, the remaining 150MW of panels will be installed over an 18-month period.

The China Development Bank will provide finance to support this project.

Have we reached a tipping point for solar powered buildings?

Due to advances in technology and improved manufacturing, the cost of solar technology, specifically solar photovoltaic panels, has declined dramatically over the last few years.  Coupled with available funding from federal, state and local utility company incentives, many industry experts believe we will see a growth in solar power for industrial buildings in the years ahead.   

Could we be nearing the tipping point between the initial cost and long-term utility savings for different types of solar systems for buildings?  The answer is found by investigating the return on investment that solar systems can provide.  In all cases, the return on investment depends on material and installation costs, current utility rates, future utility rates, overall consumption, tax depreciation, and incentives.  Historically, the time period required for solar power savings to offset initial material and installation costs could range anywhere from 10 to 20 years.  Today, with the proper incentives, solar installations are proven to pay for themselves in six years or less.  With this reduced payback timeframe, many owners are investigating the technology further and beginning to incorporate solar power into building projects.   

In today’s market, there are four commonly available solar technologies for buildings:  1. solar photovoltaic; 2. solar thermal for hot water; 3. solar thermal for air heating; and 4. solar outdoor lighting.  The most prevalent conversations to the viability of solar systems revolve around photovoltaic panels which have experienced the greatest change over the last five years.  Solar photovoltaic, or “PV,” is a technology that uses solar panel modules or arrays (groups of modules) installed together to reach a specific design capacity.  The solar array is mounted on the roof or ground nearby the building oriented due south.  Power is generated by converting solar radiation into direct current (DC) electricity using semiconductors that are composed of a number of cells containing photovoltaic material.  As the DC power is generated, an inverter is used to convert this power to alternating current (AC), which is compatible with the power we typically receive from the utility companies. 

The AC power then travels from the inverter into the electrical service panel, which distributes to the electrical loads throughout the facility.  The electrical service panel is also tied into the utility grid.  If the solar system is generating enough power to meet the demand loads of the building, no power is utilized from the utility grid.  If the solar power exceeds the demand of the building, the electricity flows out of the building into the utility grid. A special type of meter is used to measure the power delivered to the grid and energy credits are provided by the utility company to offset electrical charges.  The energy credit process is made possible through an agreement between the utility company and the customer called Net Metering. 

To assess the viability of a solar project, both environmental and structural factors for the building site must be evaluated.  All of these factors influence the economics and functionality of a solar PV system.  The first factor is the amount of energy available from the sun at the location of the building.  Solar designers start by looking at the project site’s “Insolation” value.  Not to be mistaken for insulation, “insolation” is the average amount of solar radiation available to a building which factors in historical climate and weather data.  The insolation value is specific to the latitude and longitude coordinates of the building.  It is also important to take into account any physical shading that might occur on the property.  After the preliminary building design is complete, engineers are able to calculate the demand load of the building to determine the total power required to be produced by a solar array, which is measured in kilowatts (kW).

To understand the economics of a fully integrated building, we will look at a current project being designed by ARCO/Murray National Construction in the western suburbs of Chicago.  The project consists of a 90,000-square-foot industrial warehouse building with 5,000 square feet of office.  The majority of the continuous electrical load on the building is generated by the office as the warehouse is used for storage purposes with gas heat and minimal lighting.  The office load is estimated to be 18 kWh/sf (kilowatt hours per square foot).  The total annual energy usage is determined to be 100,650 kWh.  To offset this demand, an array size of 85 kW composed of 340 standard size, 250 watt modules is required.  The 85 kW array can be mounted on the roof and requires 10,500 square feet of roof area.  The projected annual power generation of the solar array is 106,092 kWh.  The total cost for this solar installation is $425,000. 

To calculate the solar system’s return on investment it is necessary to take the installed cost and subtract the tax depreciation, utility, state and federal solar PV incentives.  The result of this calculation, the “Net System Cost,” is then compared with the total utility savings that is achieved by the use of the solar system.   

So why is solar power not more prevalent in similar type industrial buildings in and around Chicago?  One reason may be that over the past decade, solar technologies have continued to evolve and the market is behind in its understanding of current technology and installation costs.   It may be surprising to learn that many of the old myths about solar power have been overcome.  Here are a few myths that solar supporters now believe to be untrue.   

Myth 1 – PV solar panels only work in sunny areas, like Arizona. 

Solar technology can work in any of the 50 states.  According to PV Watts, a solar output calculator provided by the Department of Energy , 1 kilowatt of solar installed in Chicago will produce 1458 kwh versus 1995 kWh in Phoenix.   By comparison, the same solar array installed in Illinois can obtain 73 percent of the production capability as that of Arizona. 

Myth 2 – PV solar is too expensive for widespread usage. 

While this may have once been the case, solar energy prices have dropped 50 percent since the beginning of 2011.  Combined with financing options and current incentives, most businesses can find a return on their investment within a few years of the initial install. 

Myth 3 – If PV solar power was a viable solution it wouldn’t need government support. 

The United States government decided years ago to support energy resources because they have a direct impact on our economy.  As a result of current policies, every major energy source and technology has benefited from federal government research and development support and incentives of various types.  The same is true for the oil, natural gas, hydroelectric, nuclear, and biofuels industries, all of which like solar, continue to receive government support today.

Whatever the opinion is on solar power, the technology is available at a lower cost and moving toward the mainstream every day.  In 2010, $ 6 billion worth of finished solar energy systems were installed in the United States.  By the third quarter of 2011, this demand had grown by more than 140 percent.  Many analysts project that the U.S. will become the largest solar market in the world over the next few years.

At the very least, it makes sense for building owners and commercial developers to revisit solar technology design and get current market pricing to evaluate the return on investment.  It seems that control of a building’s energy costs will be increasingly important in an uncertain energy future.  Solar technology may be a viable option to save on energy expenses moving forward.