Filed under: california solar electric
By David Zahniser and Phil Willon
November 25, 2008
Mayor Villaraigosa unveils solar plan for Los Angeles. More than 1,700 solar panels were installed on the roof of the Staples Center in downtown L.A. earlier this year. The mayor’s proposal aims to have solar power meet one-tenth of L.A.’s energy needs by 2020. But skeptics wonder if the plan will be cost-efficient and friendly to private enterprise. Los Angeles Mayor Antonio Villaraigosa unveiled an ambitious long-range plan Monday for securing enough solar power to meet one-tenth of the city’s energy needs by 2020, a move aimed at making L.A. a hub of the solar-energy industry.
Appearing at a South Los Angeles manufacturing plant where solar panels are made, Villaraigosa said the initiative will help the Department of Water and Power wean itself off of fossil fuels — natural gas and coal — as part of the effort to address global warming.
The plan calls for enough solar panels to produce 1,280 megawatts of power, a goal that would be reached through a combination of private and public generating facilities and the installation of solar panels on homes.
“Nobody’s contemplated that many megawatts for one city,” said Rhonda Mills, Southern California director of the Center for Energy Efficiency and Renewable Technologies and a solar power advocate.
The announcement Monday is the latest in a series of renewable energy initiatives touted by the mayor in recent weeks, including using redevelopment funds to lure “clean” technology companies and investing city pension dollars in environmentally friendly companies.
Shifting Los Angeles to cleaner fuels could buttress both Villaraigosa’s run for reelection and any future run for governor. If he runs in 2010, Villaraigosa would likely face state Atty. Gen. Jerry Brown, an avid environmentalist.
“L.A. has everything it takes to make this [solar plan] work,” said Villaraigosa, standing alongside environmentalists, union leaders and City Council members. “We have the sun in abundancy. We have the space. We have the largest municipal utility in the country.”
Still, one DWP watchdog questioned the financial underpinnings of the plan
“There is one huge assumption here — that they’ll get these huge tax credits, volume discounts and economies of scale,” said Jack Humphreville, a neighborhood council member who has been pressing the DWP to appoint a ratepayer advocate. “I have serious questions about whether that is pie-in-the-sky or not.”
DWP General Manager and Chief Executive H. David Nahai said his agency will spend the next 90 days developing a financial analysis of the solar plan, including its effect on ratepayers.
Under the plan, the largest share of solar power, 500 megawatts, would come from generating facilities built by private-sector companies in the Mojave Desert.
An additional 380 megawatts would be achieved through smaller programs, including one that would help low-income residents add solar panels to their homes and another that would allow DWP customers to purchase shares of city-owned solar plants.
Voters will decide on another part of the mayor’s solar plan on March 3, at the same time that Villaraigosa seeks a second and final four-year term. That ballot measure would allow the DWP to install and own 400 megawatts of rooftop solar panels by 2014. Villaraigosa and the council have been criticized in recent weeks over that proposal, which was conceived by an organization with strong ties to the union that represents DWP employees.
Business leaders contend that the ballot measure was written by and for DWP employee unions and would lock out companies that specialize in rooftop solar panels.
Gary Toebben, president and chief executive of the Los Angeles Area Chamber of Commerce, said he is encouraged to see the mayor place a greater emphasis on private-sector solar initiatives. But he said there are unanswered questions about the solar ballot measure’s effect on electrical rates.
“We still have a concern that the cost of the ballot initiative has not been laid out,” he said.
Villaraigosa said the solar plan could lead to higher rates as soon as 2011. But City Council President Eric Garcetti noted that coal, one of the DWP’s cheapest — and most polluting — energy sources, will also become more expensive as Congress moves to impose a carbon tax.
“Coal is not going to be the same price that it is today,” he said.
Filed under: california solar electric
We all a know the sun does not shine on us all equally. This is the reality that has long slowed the growth of solar power. Where you live in the country, or even in your city will vary considerably with the same array of photovoltaic solar panels. What matters is the precise amount of sunlight that hits your roof. While we all know that San Diego gets more sunny days than Seattle, what about one neighborhood of San San Diego compared to another? What about one block of Seattle compared to the next block? Kenneth Westrick, the CEO of the renewable mapping company 3Tier says “Without that knowledge, renewables can be a bit of a crap shoot.”
Thanks to companies like 3Tier and other city sponsored programs like CH2M in San Francisco, the Solar and Wind Industry could benefit from better data. The engineering company CH2M Hill, in an an effort to resolve barriers to Solar Development, is now joining forces with the U.S. Department of Energy to provide Internet solar maps of 25 American cities. With Google Earth technology to chart precise solar potential of neighborhoods, rooftop by rooftop, the company has just cpmpleted the mapping of all of San Francisco. Residents interested in Solar can simply now to enter their address and take a solar reading of their home address. According to Gavin Newsom, the city’s deep-green mayor says: “People in San Francisco think we don’t have any solar potential but the map shows we have a lot more sun than you’d believe.” To use or learn about this new program click on the San Francisco solar map website here: sf.solarmap.org. You will get a Google Earth view of the entire city. The site shows that CH2M Hill has already labeled all 925 existing solar electric systems throughout the city which include commercial sites, government sites, and also all of the residential sites. The site truly stands on it’s merits when you enter in any address in San Francisco as the Google Earth camera shifts to a rooftop view of the business or home with data on the size of the roof, the estimated solar energy potential, with the electricity that could be produced and the electric bill savings. Also estimated is the amount of carbon that can be saved per location. One other critical feature is the site’s abiulity to provide estimates of what it would cost you to convert — with the federal, state and city incentives factored in.
Johanna Partin says “It’s a one stop shop for solar power”. As San Francisco’s renewable energy program manger she makes the case that “If you can’t get solar power with the help of the CH2M Hill map, you’re just not trying very hard.”
Other companies are even going global in conducting such solar surveys. One to keep an eye on is Seattle-based 3Tier as they are steadily mapping the solar, wind and hydro power potential of the entire planet. They call this their Remapping the World Initiative. They offer utilities and businesses to use the 3Tier website to research the best locations for wind power projects, and offer the opprotunity for ordinary citizens to check the solar potential of their home address. As this is just the beginning of these solar and wind targeted research programs we are yet to see how much all will be helped in an energy hungry world. If San Francisco is any indication, and as the focus shifts from fossil fuels to renewable options, the data will make many decisions, and savings, easy.
San Francisco already hosts hardware producing 6.5mW of solar power. Most of the power is from a relatively small number of big commercial and public / city projects. Governor Newsom has goals for 31mW of solar by 2012, which is part part of a bigger plan to provide 50mW of total renewable energy by the same year including wind, hydro, etc. Part of Newsom’s task is in identifying the 1,500 business that have the biggest solar potential in San Francisco. Those who qualify can earn a special incentive if they employ graduates of San Francisco’s workforce training program, which is part of the mayor’s push for green jobs. “Everyone’s talking about green jobs, but to say is not to do,’ he says. “We want to actually do this.’
The imperative shift to renewable energy, especially solar and wind, won’t happen on it’s own — it needs front leading government policies and state of the art technological innovations. One example of this is solar mapping.
Filed under: residential solar power
1. Determine your historical energy use from your past electric bills. Pay attention to the difference between Summer and Winter power usage.
2. Determine your roof area available for Photovoltaic Panels. These Solar Panels mounted on your roof or ground contain the Photovoltaic (PV) cells which convert sunlight into DC power. South facing surface areas are best but seasonal variations in sun exposure allow for a variety of Solar Panel placements to be used. Also, new technology allows for sun “tracking” or programmed mechanical moving of the solar panels to maximize sun exposure during the day and across all seasons of the year.
3. Contact a licensed Solar Installation Contractor(s) in your area to perform an on-site evaluation. Your contractors will know all the current solar technologies available and how to take advantage of all possible Federal, State, and possibly local solar tax rebates, grants, etc.
4. The Solar Installation Contractor will determine best location for your Photovoltaic Panels and best Inverters to use for the size of the Solar System. Location of solar panels can vary as can type of panels. Inverters (which convert the solar panel current from DC to usable AC current) need to be chosen based on best size and type for the system as does the Production Meter (explained below). The power from the Solar Panels are sent to an Inverter (or power converter) which converts the DC electricity from the solar modules to AC power, which is the same type of power being sent from your utility company to your home or business.
5. Discuss all costs for various solar electric system options and installation timing with your Solar Installation Contractor to finalize all variables. Once all is decided upon it is the time to sign the contract with your Solar Installation Contractor.
6. Your Solar Installation Contractor will submit applications to your electric utility and begin paperwork with all possible Federal, State, and possibly local tax rebates, grants, etc., to save you the most money possible.
7. You will then sign a contract with your electric utility. This is called a Net Metering Agreement and states that the power utility will credit your account for the excess power you produce which flows to the power grid. Also an important consideration is the use of a Time-of-Use Meter. This will allow you to be credited for electricity you generate at different rates. These rates can be Peak and Off Peak Rates. These rates are dependent on time of day you produce power, day of the week, and month of the year. Peak Rates are often summer afternoon week days. If you send power to the grid during peak times, you will get credit at the higher, peak rate. When you gain credit and then draw on your credit at Off Peak periods your account will be debited at Off Peak rates. If all of the electricity being generated by your solar energy system is immediately being used, your meter will not “spin backwards”.
8. Your Solar Installation Contractor will generate design drawings and pull all permits needed and, when you are ready, will install your system.
Once completely installed your County or City will inspect the system to insure compliance of your system and insure you are elligible for the Solar Tax Rebates and / or benefits you have applied for.
9. You Utility Company will be Sending you your Solar Rebate Check 6 to 8 Weeks after Inspection of System.
10. Enjoy decades of environmentally friendly and maintenance-free electricity solar power while adding value to your home! Give yourself a good pat on the back for saving money AND the planet.
Filed under: Solar Videos | Tags: battery california cells charger electric electricity generator heater lighting lights onlywire outdoor panels photovoltaic plants power roof small solar systems tower turbine water wind windmills
Filed under: Solar Videos | Tags: california solar, california solar energy, grid tie, grid tie inverter, net metering, outdoor solar lighting, photovoltaic cells, photovoltaic solar, residential solar power, solar battery, Solar Calculator, solar cells, solar charger, solar electric, solar electricity, solar grid tie, solar hot water heaters meter monitoring, Solar Installation Estimate, solar installers, solar lights, solar panels, solar power, solar roof, solar systems, solar water heater, wind generator, wind power plants, wind solar power, wind tower, wind turbine, wind turbines, windmills
Filed under: Solar Videos | Tags: california solar, california solar energy, grid tie, grid tie inverter, meter monitoring, net metering, outdoor solar lighting, photovoltaic cells, photovoltaic solar, residential solar power, solar battery, solar cells, solar charger, solar electric, solar electricity, solar grid tie, solar installers, solar lights, solar panels, solar power, solar roof, solar systems, solar water heater, wind solar power
Filed under: solar systems | Tags: california solar, california solar energy, grid tie, grid tie inverter, meter monitoring, net metering, outdoor solar lighting, photovoltaic cells, photovoltaic solar, residential solar power, solar battery, solar cells, solar charger, solar electric, solar electricity, solar grid tie, solar installers, solar lights, solar panels, solar power, solar roof, solar systems, solar water heater, wind solar power
Blogging the Singularity » Blog Archive » IBM Reveals Five …
Energy saving solar technology will be built into asphalt, paint and windows – You will have a crystal ball for your health – You will talk to the Web . . . and the Web will talk back – You will have your own digital shopping assistants …
MCT Seeks Lease to Deploy Tidal Technology – Renewable Energy World
Tidal energy company, Marine Current Turbines (MTC) confirmed that it intends to apply for a lease from the Crown Estate to deploy its world-beating tidal technology in Scotland’s Pentland Firth. Subject to financing and securing the …
Earth – Online video vote to decide $10m green technology prize …
As solar technology becomes more prevalent, cooler applications keep springing up. A great new example is the Solar Vertical Lamp by Korean designers Yoon-Hui Kim and Eun Kyung Kim, a set of vertical … more …
Filed under: Solar Thermal Technology | Tags: california solar, california solar energy, grid tie, grid tie inverter, meter monitoring, net metering, outdoor solar lighting, photovoltaic cells, photovoltaic solar, residential solar power, solar battery, solar cells, solar charger, solar electric, solar electricity, solar grid tie, solar installers, solar lights, solar panels, solar power, solar roof, solar systems, solar water heater, wind solar power
By Alex Hutchinson
1. Back-Contact Silicon PV Panels
Back-Contact Silicon PV Panels
When it comes to solar technology, no one is better equipped to separate the genuine potential from the hype than the Department of Energy, which spearheads the country’s solar research efforts. So it’s worth noting that the DOE’s choice for the brand-new 205-kilowatt solar installation on the roof of its Washington, D.C., headquarters, unveiled in September, was the unique high-efficiency solar panels built by Silicon Valley-based SunPower Corporation.
Energy Secretary Samuel Bodman called the choice “both practical and symbolic,” and he was right. It’s practical because, earlier this year, SunPower’s silicon photovoltaic cells demonstrated an efficiency of 23.4 percent—a record for large-scale, mass-produced cells. SunPower uses what’s called a “back-contact” design, which means that all the electrical contacts are on the back of a cell, leaving a larger area on the front of the cell exposed to the sun. Such designs have always been efficient, but it’s only in the last few years that manufacturing costs have become competitive.
It’s also symbolic, because SunPower provides a glimpse of what it takes to successfully bring a solar technology to market. Its back-panel PV design was developed at Stanford University in the early 1980s, and the company was founded in 1985. That’s a long time to get the product from the lab to the consumer, notes Larry Kazmerski, the director of the National Center for Photovoltaics at the National Renewable Energy Laboratory (NREL). “We have to shorten that timeline,” he says.
For SunPower, at least, the wait is over. With PV cells that the company boasts as 50 percent more efficient than conventional crystalline silicon cells, SunPower is moving full steam ahead, most recently with an agreement to build a 250-megawatt “solar ranch” in the California Valley. The project should begin delivering power in 2010 and will be—at least temporarily—the largest PV installation in the world.
2. Microinverters
Microinverters
People who want toinstall PV panels on their roofs soon run into a very basic electrical engineering problem: Solar panels produce DC (direct current) power, but the appliances we plug into the wall require AC (alternating current) power. There are plenty of systems that convert DC to AC, allowing solar power to feed into the grid or power home appliances directly, but they typically lose power in the process, add complexity and cost enough to discourage small-scale applications.
The solution is a new breed of small devices called “microinverters.” Connected directly to individual solar panels, microinverters enable each panel to output AC instead of DC power. They can also be combined with a wireless monitoring system that allows the performance of each panel to be monitored. “The combination of our inverter and monitoring system will promote large amounts of grid-connected solar power,” says Patrick Chapman of SmartSpark Energy, one of the companies rushing to release microinverter systems.
SmartSpark was one of 12 companies that received a total of $24 million from the Department of Energy in August to pursue “solar-energy grid integration”—a recognition that solar panels will need to integrate seamlessly into existing home electrical systems if they’re going to succeed. It’s been a neglected niche up to now, but there are signs that investors are taking note. Enphase Energy, which brought the first solar microinverter to market in June, received a $15 million injection of venture capital in September to help it cope with rapidly growing demand.
3. Concentrating PV Panels
Concentrating PV Panels
Most of the big solar power companies are pretty skittish about revealing precise numbers for the cost of their technology—primarily because it’s still too expensive when compared with alternatives like burning a pile of coal. So a startup called Sunrgi made quite a splash in April when it confidently predicted that its XCPV (Xtreme Concentrated Photovoltaics) solar panels (click for video) would soon be producing electricity at a cost of $0.05 per kilowatt-hour—easily cheap enough to be competitive with conventional sources of electricity. And they made it sound easy.
“In a little more than a year we were able to develop and successfully test XCPV,” said company co-founder Robert Block. “We expect the Sunrgi system to become available for both on- and off-grid power applications, worldwide, in 12 to 15 months.”
The key to Sunrgi’s technology: Using lenses to concentrate incoming sunlight by a factor of 1600, in the same way that a kid can fry an ant using a magnifying glass. This allows Sunrgi to use fewer of the expensive semiconductors that make up solar cells, saving money while getting the same amount of power out of the system. For now, though, the record stands at 40.8 percent, set in August by a prototype cell at the National Renewable Energy Laboratory that was illuminated with the concentrated light equivalent of 326 suns.
A host of other companies are also racing to make concentrating PV a commercial reality. Emcore, a New Mexico-based company whose solar cells have broken efficiency records in outer space, says that its “inverted metamorphic multijunction” solar cells will have up to 45-percent efficiency when used with concentrating lenses and mirrors. Solaria is another player, with a design that maximizes sunlight while minimizing silicon use.
4. CIGS Thin-Film Panels
CIGS Thin-Film Panels
A key factor holding back the growth of solar power is the price of silicon: A prolonged shortage has caused prices to soar to 10 times their previous levels—and the economic crisis isn’t exactly helping. Other semiconductors that can replace silicon in PV cells are also expensive, but because they can be used as “thin films,” far less of the material is required to build the cells.
The current market leader for thin-film technology is Arizona-based First Solar, which makes its PV cells from cadmium telluride and expects to ramp up its manufacturing capacity to over 1 gigawatt of solar modules in 2009. The technology isn’t perfect, though: The solar conversion efficiency is only about 10 percent, and cadmium is considered a hazardous material, which creates extra complications in the disposal of cad-tel panels.
The next big thing, NREL’s Kazmerski insists, is thin-film panels made of cadmium indium gallium selenide (CIGS). “Right now, CIGS is grabbing an incredible amount of attention,” he says. Earlier this year, researchers at NREL reached an important milestone when they built a CIGS cell with a record 19.9-percent efficiency—nearly double that reported by First Solar, and very similar to the efficiency of silicon panels.
“This is an important milestone,” NREL scientist Miguel Contreras says. “The thin-film people have always looked for matching silicon in performance, and we are reaching that goal.”
Not surprisingly, a swarm of young companies is racing to capitalize on the new CIGS technology, including San Jose-based Nanosolar, Santa Clara-based Miasole and Austin-based HelioVolt. “There are so many startups, it’s a bit scary,” Kazmerski says, “because not all of them will be around in a few years.” But if any of them succeed, the rewards will be immense.
5. Solar Thermal Storage
Solar Thermal Storage
Any discussion of solar power eventually has to face the obvious question: What happens when the sun goes down? Given the limited capacity and high cost of batteries, there hasn’t been an easy answer—until, perhaps, now. Construction is wrapping up on the Andasol 1 plant on the Guadix plateau in the Spanish province of Grenada. When it begins operations in late October, Andasol 1 will be the first commercial solar power plant to incorporate a thermal storage capacity, enabling it to run for about 7.5 hours when the sun is down or disappears behind a cloud.
“This [storage capacity] is the aspect that has captured the excitement of the utilities,” says Fred Morse, a former Department of Energy official who now works for Abengoa Solar. It represents a major shift in how we think about solar power, because instead of simply pumping electricity into the grid whenever the sun is shining, utilities can choose to save and deploy that power during peak periods, when electricity is at its most expensive.
The Andasol 1 plant, built by German company Solar Millennium AG, will be joined in 2009 by Andasol 2, and the two plants together will supply half a million people with power. The plants rely on “concentrating solar thermal” technology instead of the more familiar photovoltaic panels. Vast arrays of curved mirrors are used to focus sunlight on a liquid, heating it to over 750 F and boiling water to power a steam turbine. Storing power simply requires the equivalent of a giant thermos to store the heated liquid until steam is desired.
Abengoa plans to bring the technology to the U.S. with a storage-enabled 280-megawatt plant in Gila Bend, Arizona, that should be completed in 2011. And they’re looking for more opportunities, Morse says. “New Mexico has a request for bids out. So does Arizona and California. We’re pursuing every opportunity.”
Filed under: Solar Videos | Tags: california solar, california solar energy, grid tie, grid tie inverter, meter monitoring, net metering, outdoor solar lighting, photovoltaic cells, photovoltaic solar, residential solar power, solar battery, solar cells, solar charger, solar electric, solar electricity, solar grid tie, solar installers, solar lights, solar panels, solar power, solar roof, solar systems, solar water heater, wind solar power
Filed under: california solar electric | Tags: california, california solar, california solar energy, grid tie, grid tie inverter, meter monitoring, net metering, outdoor solar lighting, photovoltaic cells, photovoltaic solar, residential solar power, solar battery, solar cells, solar charger, solar electric, solar electricity, solar grid tie, solar installers, solar lights, solar panels, solar power, solar roof, solar systems, solar water heater, wind solar power
San Francisco Provides Comprehensive Incentives In Push For Solar Power
In July, San Francisco launched GoSolarSF a 10-year solar rebate program designed to accelerate the build out of the city’s clean energy infrastructure. On September 30th, Mayor Gavin Newsom announced that applications for new solar installations have quadrupled since then, putting the city on track to double its installed capacity by next year. Under the program, city residents will receive rebates between $3,000-$6,000 off the cost of a solar system, while businesses are eligible for up to $10,000 in savings.
San Francisco has identified 1600 business as likely candidates for solar installations. Combined, the target businesses use a total of 170 MW of power. The city’s current solar installation capacity is 5 MW – a ½ percent of the city’s 1 GW of total annual consumption. With help from a $200,000 grant from the U.S. Department of Energy, San Francisco will begin offering these businesses free energy efficiency and solar audits. The energy efficiency audits will be conducted first and are designed to drive down the businesses’ consumption of energy, thereby enabling smaller and less costly solar systems to cover their remaining energy needs.
When the municipal rebate is combined with the Federal Solar Tax Credit and California Solar Initiative rebate, all but $4,000-$6,000 of a solar installation would be covered by rebates, according to Newsom. Innovative financing, such as power purchase agreements offered by certain solar installers make it is possible that home and business owners would see no upfront costs to convert to solar electricity. San Francisco is also in discussions with its neighbor Berkeley to consider adopting a program similar to Berkeley’s innovative Sustainable Energy Financing District to offset the entire cost of the solar installation. Eventually, Newsom sees the program being expanded to other clean energy technologies, such as wind.
A key component of the GoSolarSF rebate program is a green collar job-training program designed to provide high quality jobs to the city’s underserved communities. In order to participate in the rebate, 16 solar installers have committed to hiring graduates of the city’s workforce development program. Already 8 workers have been hired to date and that number is expected to triple by next month. In a recent post to the Huffington Post, Mayor Newsom wrote: “San Francisco is creating and promoting green jobs, so we can ensure that the neighborhoods that were locked out of the pollution-based economy are locked in to the new green economy.”
At the Mayor’s press conference on September 30, he invited business owners to sign up for the free energy audits and solar assessments, with the prospect of joining the Mayor’s Solar Founders’ Circle. In the last week alone, the SF Department of the Environment has signed up 45 buildings for the program, a great start towards meeting the city’s climate goals.
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Justin Sternberg is a sustainable management consultant based in San Francisco, CA.
