FOR IMMEDIATE RELEASE

2012 Photovoltaic Projects of Distinction Award Presented to Arizona Western College and PPA Partners for their landmark Five-Megawatt Multi-Technology Solar Installation and Program.

San Jose, California, March 21, 2012 –The 5MW multi-technology solar installation at Arizona Western College (AWC) in Yuma, AZ was recognized Wednesday morning by the Solar Energy Industries Association (SEIA) and the Solar Electric Power Association (SEPA) as one of the three most unique photovoltaic projects of  2012.  The announcement and ceremony took place at PV America’s annual conference in San Jose, CA.

This system is composed of five one-megawatt sites across the campus, and will offset nearly 100% of the campus’s daytime electricity, while saving the College approximately $62 Million over the lifetime of the contract.

“This prestigious award shows what is possible on our nations Community College Campuses. Having our project recognized with this award proves what a resource our Community Colleges truly are. When complete the AWC Solar Program will provide opportunities for community involvement, valuable research, data and curriculum support for the School and for Arizona. Furthermore, additional incubation sites that new and existing technologies can access will be available for them to measure their performance under Yuma and Arizona’s amazing Solar Resource.” said Bruce Mercy CEO of PPA Partners after the award ceremony.

“These are exciting times for the U.S. solar industry and the recipients of these awards exemplify energy innovation at its best,” said Rhone Resch, president and CEO of SEIA. More than 84 projects were evaluated by a panel of independent judges, determining the uniqueness and collective benefit to the community. Judges also looked for innovative use of policy and financing to enhance the project’s impact, according to SEPA and SEIA.

The project was financed and will be owned throughout the 30 year contract by Mainstreet Power, and was constructed by Rosendin Electric.

The installation was facilitated by the APS Renewable Energy Incentive Program, which offers financial incentives to residential and commercial customers.  The Program is funded by APS customers and approved by the Arizona Corporation Commission.

The technologies include CPV panels from SolFocus and GreenVolts, Thin Film panels from Sharp Solar, Mono Crystalline panels from SolarWorld and Poly Crystalline panels from Suntech. The system will utilize single-axis trackers from SunEdison and dual-axis trackers from SolFocus and GreenVolts; the tracking systems allow the panels to continually track the movement of the sun in order to maximize electricity generation. The system utilizes Satcon Inverters.

PPA Partners LLC is a project developer of distributed generation solar programs across North America, specializing in Colleges and Universities interested in saving on their Energy bills, and creating unique learning and revenue generation opportunities.

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The US Congress has released a draft bill that would provide tax credits for manufacturers of renewable energy equipment and funding for other sources of clean energy.

House Ways and Means Committee Chairman Sander Levin, D-Mich., unveiled the draft legislation which aims to encourage domestic manufacturing of energy equipment and renewable fuel development.

The proposed legislation would modify the Section 48C advanced manufacturing tax credit to provide an uncapped 30 percent investment tax credit for expenditures to re-equip, expand or modify facilities that manufacture and fabricate solar energy property, fuel cell power plants, and advanced energy storage systems (including batteries for advanced vehicles).

The proposal would extend for two years (through 2012) and codify the direct payment in lieu of tax credit program that was initially created by Section 1603 of the American Recovery and Reinvestment Act of 2009 for renewable energy facilities (e.g., wind, solar, and biomass facilities), combined heat and power facilities, fuel cells and microturbines that qualify for the production tax credit and investment tax credit. Among other technical improvements, the proposal would clarify that real estate investment trusts may participate in the program.

Under current law, residential fuel cells are eligible for a 30 percent investment tax credit (capped at $1,000 per kilowatt hour of capacity). Commercial fuel cells are eligible for a 30 percent investment tax credit (capped at $3,000 per kilowatt hour of capacity). The proposal would harmonize the capacity limitation of residential fuel cells to the capacity limitation of commercial fuel cells (i.e., $3,000 per kilowatt hour of capacity). Furthermore, the proposal would allow micro-combined heat and power systems to qualify for the 30 percent investment tax credit for residential energy efficient property.

The proposal would also extend the 50 percent investment tax credit for alternative vehicle refueling property for three years (through 2013). The proposal would also make modifications clarifying the availability of this credit for electric vehicle refueling pump property and for property that fuels non-motor vehicles that run on hydrogen fuel cells.

Source: Fuel Cell Today

By:Eric Wesoff

VC heavyweight Vinod Khosla and Bill Gates get behind a wildly unorthodox nuclear reactor design.

“[It's like taking] the entire nuclear infrastructure and collapsing it into one vessel.”
— TerraPower’s John Gilleland at an April 2009 presentation at UC Berkeley

Can nuclear power be considered green?

Greentech Media has been on the forefront of covering nuclear power as a potential clean energy source for several years now.  We have taken detailed looks at small modular reactors (SMRs) and even looked at some activity in fusion science (including SMRs from NuScale and Hyperion, fusion from General Fusion and TriAlpha, nuclear waste disposal from Kurion, Small Modular Reactor report here).

It’s always a contentious issue.

Yes, nuclear power is carbon-free in operation — but uranium extraction and plant construction can hardly be considered carbon neutral.  And yes, it’s baseload power with a low price per kilowatt hour, but it’s very expensive to build and harrowingly difficult to finance.

And then there are the huge and vexing issues of safety and proliferation.

But TerraPower’s wildly unorthodox reactor design actually can consume used nuclear fuel as its power source.  And the firm has just raised a $35 million financing round.

Bill Gates, Massachusetts-based VC firm Charles River Ventures and Khosla Ventures joined in the Round B, according to a Reuters article.

It’s an absolutely audacious VC bet and the entrepreneurs and investors involved deserve credit for sheer (I don’t know if I can say this in a family publication) brass balls, given the staggering technical, regulatory and temporal risks involved.

Background on the TerraPower idea

TerraPower was spun out of Intellectual Ventures (the think-tank created by ex-Microsoft chief scientist Nathan Myhrvold) to develop nuclear reactors that run primarily on depleted uranium. Blll Gates is an active funder and participant in the firm and, based on comments from the CEO, money is not an obstacle.

Switching from enriched fuel to DU reduces risks associated with nuclear proliferation and transportation as well as the amount of nuclear waste. TerraPower’s reactor does, however, need fissile material (i.e., enriched uranium) to initiate a reaction.

TerraPower has at least 20 employees and is run by John Gilleland, a big name in the reactor physics field and the manager of the nuclear program at Intellectual Ventures. Before Terrapower, he was the CEO of Archimedes Technology Group, where he focused on new technologies for mitigating waste from nuclear weapons, reprocessing spent reactor fuel and enriching uranium. Before that, he was at Bechtel and was the managing director at the International Thermonuclear Experimental Reactor program. In 16 years at General Atomics, he headed the construction of an advanced fusion research test bed.

In an April 2009 presentation in Berkeley, Calif., Gilleland described the TerraWave Traveling Wave Reactor (TWR) as embodying a “self-sustaining deflagration of breeding and burning,” with “waves of breeding and burning propagating through fertile material indefinitely.”  The presentation also claims that a “core life of 60 years is practical.”

The firm has hired an all-star team of nuclear engineers to design this revolutionary type of reactor.

In a recently published paper co-authored by Myhrvold, representatives of LLNL, and the Hoover Institute entitled “Nuclear fission power for 21st century needs: Enabling technologies for large-scale, low-risk, affordable nuclear electricity,” the team proposes a “[r]epresentative system-level integration that obviates all fuel supply issues, including the entire set of isotopic enrichment ones, while rendering comparably useful as nuclear fuels all of the actinide elements and isotopes. It entirely avoids transport and reprocessing and the full set of ad hoc waste disposal issues, and completely precludes all those involving proliferation/diversion of fissile isotopes into weapons programs. It provides zero biospheric hazard in the event of either natural or man-made catastrophe. It requires — indeed, admits of — no operator control actions, other than initial start-up and final shutdown commands, so that operator errors are entirely precluded; during the half-century of potentially full-power operational life in between these two commands, it thermostatically regulates in an entirely automatic manner its own nuclear power generation to match the heat removed from its core in a time-varying fashion.”

The team concludes: “We therefore project a bright future for cheap electricity safely obtained in >10 TWe quantities from nuclear power reactors of this new type, moreover over multi-century time frames.”

TerraPower has stated that commercial deployment can begin in less than 15 years.

The firm is considering modular 100 MWe and 300 MWe sizes as well as 1 GWe units.

Regulatory quicksand and long time frames

Introducing a small modular reactor like the NuScale design, a new reactor that still bears a great resemblance to existing light water reactors, is a challenge to the testing and approval process of the Nuclear Regulatory Commission.  It takes years and years from the date of submission of plans to approval and eventual site permitting and construction.

Introducing a new reactor design like TerraPower, one that operates on radically different physical principles than that of a light water reactor, is a proposition that is saddled with profound marketplace and regulatory challenges.

It is unlikely that some of the investors will live to see the plant actually switched on and operating.  It would seem that the time frame would require a different type of VC fund lifetime instead of the typical eight to ten years.  Clearly, Khosla and Gates want to partner with or license the technology to Toshiba or Areva or Babcock & Wilcox.

Nuclear remains a financial and safety challenge, and nuclear’s detractors make good arguments — everyone from Amory Lovins and his Rocky Mountain Institute to NIRS, the Nuclear Information and Resource Service, are able to point out the cost overruns and safety concerns (more valid objections can be found here).

About 20 percent of U.S. electricity comes from nuclear sources.  Other nations like China, India and France will rely on nuclear for baseload power to an even greater degree going forward.  We can’t just wish it away.

TerraPower will look to partner with firms and nations other than the U.S. where nuclear is less stigmatized — perhaps Russia, China, India or France.

In any case, kudos to the entrepreneurs involved for thinking way outside of the box — and to the investors who are putting their money where their mouth is.

Global Solar Technology

by Debasish Choudhury

After its best year ever in 2008, the world solar market struggled to survive a tumultuous 2009. What looked like a yawning drop for the photovoltaic (PV) market in the first half of the year turned into a solid gain in total amount of systems installed on the strength of strong German sales in the fourth quarter. But despite annual worldwide PV installations rising from 5.8 GW in 2008 to 6.6 GW in 2009, the PV market value dropped by 15.8% to $17.0 billion due to crashing PV cell and module prices.

The U.S. fared better than most countries, with the PV market up an estimated 6.0% in 2009 to $3.5 billion and PV installations rising to 469 MW. An extension of the solar tax credit and new recovery act funding helped to keep the U.S. PV market on a continuing upward trend.

The U.S. represented only 1% of a world solar thermal collector market dominated by China in 2009, shipping 1.0 GW of collectors worth $79.6 million. While still currently focused on low temperature pool heating systems that represented 82% of the U.S. market (by megawatts of collectors shipped) in 2009, SBI Energy anticipates much stronger growth in residential hot water systems heading to 2014.

Worldwide, the U.S. still has the greatest potential to increase its position in the solar market. SBI Energy foresees 900 MW of PV installations in 2010, rising to 7,600 MW of PV installations in 2014 building on renewed interest in solar from utilities and the extension of the solar tax credit. While the ST market will show only moderate growth in the U.S., the PV market segment will continue to shine in the U.S. and the concentrated solar power (CSP) market is set to explode. SBI Energy estimates the U.S. solar panel market will reach $34.5 billion in 2014.

U.S. Solar Energy Market World Data, 2nd Edition by SBI Energy analyzes the manufacturing and sales of the U.S. solar photovoltaic and solar thermal markets within the context of other key solar countries such as the Germany, Spain, Japan and China. The analysis will include definitions, current product offerings and market detail on the following segments:

• Photovoltaic cells and modules
• Vacuum tube and flat-panel solar thermal modules
• Balance of system components including inverters, frames, batteries and charge controllers

About SBI Energy
SBI Energy, a division of MarketResearch.com, publishes research reports in the industrial, energy, building/construction, and automotive/transportation markets. To learn more, visit www.sbireports.com.

Global Solar Technology

by Debasish Choudhury

Skyline Solar, a manufacturer of High Gain Solar (HGS) arrays for commercial, industrial, government and utility markets, today announced the first commercial installation of its High Gain Solar (HGS) 1000 system in a new municipal solar power plant in the tiny desert town of Nipton, Calif. The 80-killowatt Nipton plant is an upgradeable solar power system that will provide roughly 85 percent of Nipton’s electricity needs—the highest percentage of solar electricity of any town in the United States.

“As the gateway community to the Mojave Desert, Nipton seeks to be a good steward of the environment. Sustainability is paramount to this endeavor,” said Gerald Freeman, Principal Administrator for Nipton. “It is with this in mind that we are extremely pleased to be utilizing the HGS 1000 as our primary source of energy. And the HGS upgradability is a very attractive option.”

The HGS 1000 system brings a number of breakthrough innovations to the solar industry:

• Cost: Skyline Solar’s HGS architecture delivers ten times more energy per gram of silicon versus traditional flat-panel systems in sunny locations. The system utilizes tracking, cooling and concentration components, reducing the amount of silicon needed by 90 percent.
• Upgradability: The power-producing components of the system are upgradeable, allowing system-owners to “future-proof” their investment and upgrade with new solar panel technologies.
• Reliability: Skyline Solar HGS 1000 arrays combine industry-proven silicon cells, durable reflector materials and single-axis tracking into a complete, easy-to-deploy system.
• Scalability: Built primarily out of commodity materials with globally available manufacturing processes from the PV and automotive industries, Skyline Solar HGS 1000 simultaneously improves financial payback and scalability.

“This is a significant milestone in the development of our company as we strive to bring scalable, capital-efficient solar energy to utility, government and commercial customers,” said Bob MacDonald, CEO and co-founder of Skyline Solar. “Our pre-engineered HGS system is ideal for large energy consumers. Nipton, California, a town now 85 percent powered by clean, renewable solar energy, is a shining example to the rest of the country of how even small communities can help drive America’s goal of energy independence.”

The commissioning of the Nipton plant highlights Skyline Solar’s rapid and strategic growth over the past two years. After securing financing in September 2008, Skyline Solar announced its unique HGS architecture in May 2009, followed shortly by the completion of the company’s first demonstration plant with the Santa Clara Valley Transit Authority in San Jose, Calif. In October, the company tapped Cosma, an automotive supplier, as a manufacturing partner as Skyline Solar ramped up to commercial production. More recently, the company was awarded one of the first patents under the US Patent & Trademark Office’s Green Technology Pilot Program, covering key elements of Skyline Solar’s HGS architecture. The Nipton plant is another step in Skyline Solar’s development of upgradeable, pre-engineered solar energy systems that address global demand for scalable, cost-effective solar energy.

For more information, please visit www.skyline-solar.com.