TODAY’S STUDY: IRELAND GETS READY FOR CARS WITH PLUGS

ELECTRIC VEHICLES Roadmap 2050
January 2012 (Sustainable Energy Authority of Ireland)

Introduction to the Electric Vehicle Roadmap

Transport accounts for one third of Ireland’s energy requirement and energy related CO2 emissions and is almost entirely dependent on oil. Increasing oil scarcity, oil price volatility, and environmental concerns are driving a search for an alternative means of powering our transport system.

The transport sector has been the largest sectoral driver of energy demand in Ireland over the past two decades, increasing at twice the rate of increase in overall energy demand over the same period. Private road transport is the largest contributor to transport demand at 43%, with air transport and road freight contributing less than 20% each. In the context of an EU commitment to achieve an 80% reduction in carbon emissions by 2050, and concerns about future scarcity, alternatives to oil (particularly in private road transport) must be encouraged.

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A number of alternative approaches are emerging, with different options being considered appropriate for different modes of transport. Biofuels are being promoted for all transport, but may be of most value for road freight and air transport, where length of journey will require higher density fuels. Options to address private road transport include modal shift towards public transport and cycling, and technology advancements, including more efficient internal combustion engines (ICE) and electric vehicles (EV).

For Ireland, with access to large amounts of variable renewable wind and ocean energy, and with relatively short driving distances for most private vehicle users, electric vehicles offer the prospect of reducing energy consumption in transport, while at the same time reducing our import of fossil fuels, and providing an additional demand to balance the supply of variable renewable generation. The development of high energy density lithium batteries, the inherently high efficiencies of an electric drive train, and the current race between auto manufacturers to bring credible commercial electric vehicles to market is driving the cost of ownership towards parity with conventional vehicles. This means a transition to electric vehicles could provide economic benefits as well as energy diversity and reduced CO2 emissions.

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Achieving the potential benefits envisaged in a high electric vehicle deployment scenario assumes that a global high deployment scenario is achieved, driving technical innovation and providing scale economies which Ireland’s market cannot achieve on its own. In addition, it will require a strategic approach that integrates the deployment of electric vehicles and variable renewable generation with the development of smart grid technology, providing intelligence across the system and enabling communications between system operators, vehicle charging systems, and generators.

This roadmap provides scenarios for accelerated deployment of battery electric vehicles (BEVs) and plug in hybrid electric vehicles (PHEV) in the private vehicle fleet to 2050. It was developed alongside a wind energy roadmap and a smart grid roadmap, and key assumptions across all three are aligned. Our roadmap builds on the work of the International Energy Agency to present the potential impacts of accelerated electric vehicle deployment on energy demand, fossil fuel imports, and CO2 emissions. The developments in policy, technology and infrastructure that will enable accelerated deployment are also identified. The delivery of an integrated low carbon energy strategy that facilitates electric vehicle deployment while increasing our use of zero carbon variable renewable resources is achievable by 2050. This roadmap highlights the substantial work required for its successful delivery and, along with the other roadmaps developed by SEAI, points to a possible low carbon future for Ireland…

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Electric Vehicles Key Points

Electric vehicles within this roadmap include battery electric vehicles and plug-in hybrid electric vehicles in the Irish passenger car market up to 2050

With an abundance of accessible wind and ocean energy and distances from the capital city to key neighbouring cities ranging from 170km to 260km, Ireland is well suited to become an early adopter of electric vehicle technology. This roadmap offers a vision of how the Irish market for electric vehicles could develop up to the year 2050 and models a number of EV deployment scenarios. The impact of EVs on energy efficiency, fossil fuel imports and CO2 emissions are presented. Additional analysis results considering the impact of EVs on electricity demand and on critical peak load periods are shown.

A technical annex detailing assumptions and analyses is available on the SEAI web site.

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Key Findings

●● Passenger Car Fleet increases by 60% from 2011 with 2.9 million vehicles on the road by 2050

●● By 2020 the EV contribution to the passenger car segment is 2.4%, growing to 60% by 2050 in the medium scenario

●● Transport fossil fuel imports reduce by up to 50% compared with 2011: this equates to a reduction in fossil fuel imports of 800,000toe per annum for the passenger car segment

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●● Renewable energy in the passenger vehicle segment increases by up to 50% by 2050

●● CO 2 emissions for the passenger car fleet reduce by about 1% with respect to 2011 emissions, despite a significantly larger fleet size in 2050

●● Based on projected cost reductions for battery production, EVs may offer cheaper 10 year cost of ownership than future ICE vehicles from the period 2019 to 2025 without financial incentives

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●● Comparing the Mean EV deployment scenario, including 60% EVs and 18% Hydrogen vehicles, with a future fleet of only ICE vehicles, the cumulative savings to society could range from €2.3 billion to €12.4 billion by 2050

●● EV deployment causes gross electricity consumption to grow by just 14%. Assuming EV energy is consumed only at night time, there could be sufficient capacity available to supply an EV Fleet of up to 1.8 million vehicles with 2.9GW of electrical capacity required at night. Adjusting this window to an 8hr period reduces this capacity figure to 1.8GW. Therefore, some method of aggregating and managing the EV load will be required to minimise grid development costs and enable EVs’ demand to assist in managing wind variability

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Key Results

The key results are presented here for the Mean EV Deployment Scenario with 60% EV (BEV plus PHEV) and 18% H2 Fuel Cells car sales by 2050. The High and Low Scenarios comprise the same overall car stock levels but differ by +/-20% from the Mean EV levels. Note that new ICE vehicles sold from 2011 onwards are subject to the EU prescribed CO2 emission improvements to 95 gCO2/km by 2020. The only forms of renewable electricity included in the study are wind and ocean power. Alternative transport fuels such as liquid biofuels and natural gas are excluded, to focus exclusively on the effect of electricity in transport. This will lead to conservative estimates of CO2 reduction and transport fuels consumption. Results for all scenarios are presented in table form.

QUICK NEWS, February 2: COMBINING WIND AND SUN; FARMERS FOR SOLAR; TRADING OLD COAL FOR EE

COMBINING WIND AND SUN
GE banks on solar-wind link
Ros Davidson, 30 January 2012 (Windpower Monthly)

"General Electric is wooing its wind-turbine customers with thin-film solar panels made at GE's new solar assembly plant in Colorado…GE recently unveiled its first 'hybrid' sale of 23MW of solar panels to a US-based wind customer, Invenergy, for installation next to the latter's 210MW Grand Ridge wind project in Illinois."

[Vic Abate, vice president for renewables, GE:] "Putting wind and solar in an interconnected system can more effectively use the transmission system, and energy can be more easily dispatched…Wind tends to blow more at night and solar captures power during the day…Most wind farms have power lines [that are] used 40% of the time; [for] solar [it's] about 20%..."

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"Turbine manufacturers are facing plummeting sales in the US, and the wind industry faces expiration of eligibility for the federal Production Tax Credit on 31 December. Congress is discussing an extension to the ten-year subsidy.

"Solar projects can instead draw on the Investment Tax Credit, which does not expire until 2016. Solar panel costs have now dropped enough to justify GE's strategy of hybrid sales…[U]sing solar panels in wind farm locations was attractive because…the [developer already knows the] community, how to get the permits and secure interconnections to the grid…"


FARMERS FOR SOLAR
USDA Invites Applications for Renewable Energy and Energy Efficiency Projects
January 20, 2012 (U.S. Department of Agriculture)

"…USDA is seeking applications to provide assistance to agricultural producers and rural small businesses to complete a variety of energy efficiency and renewable energy projects. Funding is available from USDA's Rural Energy for America Program (REAP) authorized by the Food, Conservtion, and Energy Act of 2008 (Farm Bill)…

"The Rural Energy for America Program (REAP) is designed to help agricultural producers and rural small businesses reduce energy costs and consumption and help meet the Nation's critical energy needs. For 2012, USDA has approximately $25.4 million budget authority available to fund REAP activities, which will support at least $12.5 million in grant and approximately $48.5 million in guaranteed loan program level awards."

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"USDA is accepting…renewable energy system and energy efficiency improvement grant applications and combination gant and guaranteed loan applications until March 30, 2012…renewable energy system and energy efficiency improvement guaranteed loan only applications on a continuous basis up to June 29, 2012…renewable energy system feasibility study applications through March 30, 2012; and…energy audits and renewable energy development assistance applications through February 21, 2012…

"This funding is an example of the many ways that USDA is helping revitalize rural economies to create opportunities for growth and prosperity, support innovative technologies, identify new markets for agricultural producers, and better utilize our nation's natural resources…The Obama Administration is working to promote domestic production of renewable energy to create jobs, reduce our dependence on foreign oil, combat global warming, and build stronger rural economy…"


TRADING OLD COAL FOR EE
Avoiding a Train Wreck: Replacing Old Coal Plants with Energy Efficiency
August 22, 2011 (American Council for an Energy Efficient Economy)

"Changes in fossil fuel markets and updates to environmental regulations may result in the retirement of existing coal-fired electric power plants, putting on the order of 40,000 megawatts of generation at risk of retirement. This capacity is primarily located in the Ohio Valley, Upper Midwest, Mid-Atlantic, and Southeast. The investments required for replacing or upgrading these plants would raise electricity rates for all customers…Customer-side investments in energy efficiency and combined heat and power can replace this capacity at a lower cost, reducing customer rate impacts…"

EE is the best deal in energy. (click to enlarge)

"Energy efficiency investments by large energy consumers, particularly manufacturing firms, should be the target. Many manufacturing firms are poised to make major new capital capacity investments as the economy recovers and demand for manufactured products increases. These investments would modernize manufacturing, generating local job creation and enhanced environmental compliance for the facilities…Current utility regulatory and business models do not encourage utilities to make these customer-side investments. A new utility regulatory business model…[should allow utilities] to invest ratepayer funds in the demand-side projects and…earn a preferred return on these investments…"

TODAY’S STUDY: JOBS BUILDING SUN

Solar Installation Labor Market Analysis
Barry Friedman, Philip Jordan and John Carrese, December 2011 (National Renewable Energy Laboratory)

Executive Summary

The potential economic benefits of the growing renewable energy sector have led to increased federal, state, and local investments in solar industries, including federal grants for expanded workforce training for U.S. solar installers. However, there remain gaps in the data required to understand the size and composition of the workforce needed to meet the demand for solar power. Through primary research on the U.S. solar installation employer base, this report seeks to address that gap, improving policymakers’ and other solar stakeholders’ understanding of both the evolving needs of these employers and the economic opportunity associated with solar market development. Included are labor market data covering current U.S. employment, expected industry growth, and employer skill preferences for solar installation-related occupations. This study offers an in-depth look at the solar installation sectors. A study published by the Solar Foundation in October 2011 provides a census of labor data across the entire solar value chain.

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The data in this report were gathered using a mixed-method (telephone and Web) questionnaire for solar photovoltaic (PV) and solar heating and cooling (SHC) technology installers throughout the United States in August 2010. Utilizing standard methodological approaches, the report represents the first statistically valid job count in the solar installation sector. The sample of respondents includes 1,425 unduplicated completed questionnaires from a census of solar installers and from a random sample of firms in construction industries. These responses were used to extrapolate data about solar installation workforce demand in the United States. It is the first study to use a random sample of the broader construction economic sectors to ensure their inclusion in the solar installation job count.

As of August 2010, the sector employed approximately 46,500 permanent solar workers, defined for this study as employees that spend at least 50% of their time on solar-related work. Three in four of these, or approximately 33,000 employees, are engaged in solar activity for more than 75% of their time. These estimates represent a range of approximately 32,000–38,000 full-time equivalent workers (FTEs). Because some workers do not work on solar installations on a full-time basis, estimates of the number of workers with varying degrees of solar focus always exceeds estimated FTEs. About half of the jobs identified in this study were derived from the random sample of the broader construction sectors, for which solar installation activity was not previously quantified. Solar installation firms also employ nearly 20,000 additional temporary and seasonal employees. These estimates represent gross jobs associated with the solar installation sector; measuring net jobs is a separate question beyond the scope of this report. Net job estimates would account for potential lost jobs through displacement from other fields.

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Other key findings include:

• In most regions of the United States, installation companies expressed strong interest in workers with real-world construction and electrical experience and knowledge. They place an emphasis on the importance of informal on-the-job or hands-on training.
• Most installation companies surveyed (about 8 in 10) were optimistic about the future.
• Companies prefer experienced workers and are having difficulty finding them. About half (52%) of firms reported “some” or “great” difficulty in finding entry-level candidates who have the appropriate skills and training; 59% reported difficulty finding non-entry-level employees. Although unemployment is high in most solar markets, in many cases workers seeking employment do not possess the skill sets or hands-on experience that employers seek. In some cases, they may lack sufficient knowledge of effective pathways to solar careers.
• Critical skills and desired experience include those associated with electrical and construction trades, customer service, and specialized solar knowledge.
• To be most effective, training programs need to understand local market trends and continue developing partnerships with local solar employers.
• For a variety of reasons, most notably increased competition, worker experience, and the expansion of large utility-scale PV installations, U.S. labor productivity is likely to improve in the future, suggesting caution about future projections of jobs needed based on current labor intensities.

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As with any early stage market, one would expect improvement in labor productivity over time, scale, and industry development. SEIA and GTM Research estimates a total of 878 MWdc of PV was installed in 2010 (SEIA/GTM 2011a. Based on global estimates of expected labor intensities (e.g., New Energy Finance 2009), the U.S. installation workforce is larger than would be expected to serve a market that size. Further, respondent data show that 64% of U.S. installers employ 10 or fewer people, and many of these small start-up firms would be expected to consolidate over time in the natural course of market development. Increasing competitive market forces and worker experience tend to improve labor productivity. In addition, given the fact that the United States is still early in market development, supply and distribution chains will likely become more efficient over time. The solar market may be over-staffed relative to the size of the market for various reasons. For example, there may be extra staff required to manage state, local, and utility regulations and requirements that tend to be inconsistent or cumbersome. In addition, human resources and extra staff time are required for any new business, especially one in a new industry, for such disparate organizational development tasks as building and training staff, conducting market research, business development, establishing credit, and raising capital. Labor intensity, as defined by jobs per installed megawatt, is also likely to decrease as large utility-scale plants currently planned move into construction and become a significantly larger portion of U.S. installed capacity. Finally, at least in the near-and-mid-terms, labor demand growth may be impinged by the expiration of recovery funds and programs aimed at solar markets, such as the cash grant in lieu of tax credit program administered by the U.S. Treasury Department, set to expire December 31, 2011.

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More than half of U.S. installation employers report difficulty in meeting their labor needs for both skilled and unskilled workers, particularly for installers and sales staff. In the face of very high unemployment in construction sectors of the U.S. economy, these findings underscore the opportunity to provide solar training to unemployed workers in these sectors, such as those with the foundational construction or electrical experience preferred by solar installation employers. The construction industry (NAICS 23) has consistently had the highest unemployment rate of all industries in the United States at 34%, expressed as a percentage of jobs in the industry—one in three of the 12–15 million unemployed workers. Unemployed workers can be found in many regions, but it is not yet clear that they are accessing the information or the training they need to fill the demand. Because of the current mortgage crisis, some workers who would otherwise be suited for solar installation jobs may lack the mobility that might be required to relocate to be in proximity to the available jobs. In other cases, solar installation wages may be insufficient to justify relocation to available jobs.

One of the critical roles of the emerging solar installation training infrastructure is to better understand local labor supply-demand dynamics. Training workers into nonexistent job markets, or providing training programs without sufficient regard to available local jobs and the needs of local employers, could be counter-productive. It is incumbent upon training programs to know their local markets and offer a conduit to local solar employers.

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Despite the generally optimistic outlook of solar installation employers and their difficulty in finding suitable workers, the jobs opportunity represented by solar industry growth should not be overestimated. Current labor intensities are not likely to remain constant. Rather, labor productivity is likely to improve as the market expands, and proportionally fewer workers per installed megawatt will be required as the market seeks to drive down costs, even as labor demand increases in absolute terms. For example, design, process, and technology improvements to streamline installation represent potential opportunities for improvements in labor productivity in future years.

Although the overall growth rate reported by solar employers is approximately five times higher than what is expected among similar traditional construction industries and nine times higher than the expected overall job growth rate nationwide, when applied to the very small solar industry, this high growth rate still signifies less than 10,000 new installation jobs per year. Additionally, there is still little or no job market in more than half of the states where the solar industry has yet to gain much traction at all. There is an ongoing need for training programs around the country to take a targeted approach to the dynamic needs of the labor market, both in terms of geography and specialized skills. For example, at the present time there is a need for specialized training in codes, permitting, and inspection for both code officials and installers, as well as for sales professionals or installers with sales skills.

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This report also provides employer preferences in regards to critical education, training, and skill sets for solar installation-related occupations. Electrical and construction skills and experience, customer service skills, and a general understanding of solar power are the most important skill sets for employees.

The information contained in this report provides a picture of a small but growing economic sector. For most occupations, employers are facing difficulties finding qualified applications to meet this new demand. Provided with this new information, training providers can assess priorities, evaluate how best to communicate employer needs to their students, and work with local employers and government agencies to equip and re-train workers to obtain the skills that are most important to potential employers.

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Conclusions

To be most effective, training programs need to understand local market trends, including occupational demand, employer preferences, and the size of their local markets. The labor market data contained in this report provide critical information to SITN and other stakeholders on the current employment market. These include the size of the labor market by region and by occupation, as well as employer challenges and skill preferences for solar installation-related occupations. At this early stage of market development, labor productivity is low but likely to improve in the future, suggesting caution about future labor demand projections based on current workforce estimates. Labor intensity will be reduced through competition and worker experience and as more large-scale PV projects move into construction. Labor demand may experience a temporary decline with the expiration of the S. 1603 grant program set to expire December 31, 2011.

Although U.S. solar installation employers are optimistic about the growth prospects of the labor market, more than half report difficulty in finding even entry-level workers. Yet, the construction industry has the highest unemployment rate of all economic sectors in the United States at 34% (EMSI 2010). Depending on the region, training providers that find ways to identify, recruit, and up-skill unemployed construction workers for solar may find that their construction experience is desirable to prospective employers, making solar an important option in their job search. Employer data collected for this report also indicate a strong preference for workers with some background knowledge or experience, most critically:

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• Hands-on construction experience
• Electrical knowledge or experience and knowledge of the National Electrical Code S.690
• Customer service/sales skills or experience
• An understanding of basic principles of solar power, which can be shown through completion of certification programs.

The growth rate expected by solar employers is significantly higher than what is expected among traditional construction industries and the expected overall job growth rate nationwide. On review of many of the existing solar training programs in the nation, it appears that more emphasis could be given to providing work experience or other fieldwork related to installations. Job projections reported by the solar industry suggest expectations for continued growth, with employers facing difficulties finding qualified workers to meet this new demand despite high levels of unemployment in construction sectors. Provided with this new and timely information, training providers can realistically assess their training priorities, how they should be communicating employer needs to their students, and how they can equip and re-train workers to obtain the skills that are most important to their potential employers. Finally, this report raises questions not yet answered; to name just a few, more detail on state and sub-state labor markets, detailed employer profile data by state, and data to further explore the gap between unemployed workers and difficulty hiring would be useful to continue to complete the picture of this growing renewable energy sector.

QUICK NEWS, February 1: CONGRESS ON VERGE OF RUINING WIND IN 2013; WHAT SOLAR POWER PLANTS NEED; BIG MONEY IN ZERO ENERGY

CONGRESS ON VERGE OF RUINING WIND IN 2013
Iberdrola Suspending New US Wind Farms Without Tax Credit – Executive
January 25, 2012 (Dow Jones Newswire via Fox Business)

"… Spain's Iberdrola SA (IBDRY, IBE.MC) has suspended planning for new wind farms in the U.S... anticipating that Congress may not extend a popular tax credit for the industry…Rich Glick, vice president of government affairs for Iberdrola Renewables…[said] there would be ‘close to zero’ megawatts of wind power built in the U.S. in 2013 if the credit isn't extended soon…

"…[A] broader legislative deal to give payroll tax breaks to U.S. workers is being debated]. If the wind provision isn't included in that bill…to be voted on [by the end of February]… it might not be considered again until after the November elections…Wind farms that are producing electricity by the end of this year can claim the credit, and industry observers say 2012 could be a record year for wind installations as developers race to complete projects…"

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"But the wind industry is scaling back future plans now because it takes years to plan a project and they can't count on any future tax credits…Acciona Wind Power North America… said the company's turbine assembly facility in Iowa might be able to keep its workforce at about 125 without the credit by shipping the turbines to wind farms in Canada, Mexico, or elsewhere. But it could be ramping up production and hiring more people if the credit were still in place…

"The American Wind Energy Association and other trade groups support a bill that would extend the credit by four years. Senate Majority Leader Harry Reid (D., Nev.)…suggested it should be part of ongoing negotiations on the payroll tax…[but] Rep. Fred Upton (R., Mich.), said provisions to delay enforcement of Environmental Protection Agency rule on industrial boiler emissions and to expedite the approval of the cross-border Keystone XL oil pipeline from Canada should also be part of the deal. Many Senate Democrats oppose both…"


WHAT SOLAR POWER PLANTS NEED
SEIA, LSA Submit Recommendations For Solar Energy Development On Public Lands
31 January 2012 (Solar Industry)

"The Solar Energy Industries Association (SEIA) and the Large-scale Solar Association (LSA) say they have submitted comments on the supplemental draft programmatic environmental impact statement (PEIS) for solar energy development in Southwestern states… issued by the U.S. Department of the Interior's Bureau of Land Management (BLM)."

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"…[The] key principles…critical to the development of utility-scale solar power plants on public lands…[are]Flexibility for solar power plants to be responsibly developed outside of designated solar energy zones…Near-term identification of new solar energy zones suitable for project development…Coordination of transmission build-out in areas where solar energy development is occurring; and…Continued allotment of the resources and staff necessary for BLM staff to efficiently process pending project permit applications…"


BIG MONEY IN ZERO ENERGY
Revenue From Net Zero Energy Buildings to Reach $1.3 Trillion by 2035
January 31, 2012 (Pike Research)

"…[T]he goal of designing zero energy buildings, or buildings that consume as much energy as they produce through on-site and renewable energy systems, has emerged as the next major frontier. A number of countries and regions have already established long-term targets and regulations requiring zero energy building construction that will come into effect over the coming years, some as soon as 2016…

"…[S]tringent regulations will accelerate adoption around the world…According to a new report from Pike Research, worldwide revenue from zero energy buildings will grow rapidly over the next two decades, reaching almost $690 billion by 2020 and nearly $1.3 trillion by 2035. That represents a compound annual growth rate of 43%, with much of that growth occurring in the European Union…"

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"…[T]he European Union’s Energy Performance of Buildings Directive (EPBD), which governs EU building energy codes, will require nearly zero energy construction in public buildings by 2019 and in all new construction by 2021. The exact language of these new building codes is still being established, but it is clear they will drive significant investment in zero energy building technologies over the next few decades…

"…Similar regulations have come into effect or are being discussed in the United States and Japan. While the technologies required to make zero energy buildings possible, such as efficient lighting and HVAC systems, improved insulation, solar photovoltaic and other systems, can add significant upfront cost, advances in energy efficiency and renewable energy technologies will improve system performance and reduce costs…"

TODAY’S STUDY: U.S. TIDAL ENERGY POTENTIAL

Assessment of Energy Production Potential from Tidal Streams in the United States
June 29, 2011 (Georgia Tech Research Corporation)

Executive Summary

Tidal stream energy is one of the alternative energy sources that are renewable and clean. With the constantly increasing effort in promoting alternative energy, tidal streams have become one of the more promising energy sources due to their continuous, predictable and spatially-concentrated characteristics. However, the present lack of a full spatial-temporal assessment of tidal currents for the U.S. coastline down to the scale of individual devices is a barrier to the comprehensive development of tidal current energy technology. This project created a national database of tidal stream energy potential, as well as a GIS tool usable by industry in order to accelerate the market for tidal energy conversion technology.

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Tidal currents are numerically modeled with the Regional Ocean Modeling System and calibrated with the available measurements of tidal current speed and water level surface. The performance of the model in predicting the tidal currents and water levels is assessed with an independent validation. The geodatabase is published at a public domain via a spatial database engine and interactive tools to select, query and download the data are provided. Regions with the maximum of the average kinetic power density larger than 500 W/m2 (corresponding to a current speed of ~1 m/s), surface area larger than 0.5 km2 and depth larger than 5 m are defined as hotspots and list of hotspots along the USA coast is documented. The results of the regional assessment show that the state of Alaska (AK) contains the largest number of locations with considerably high kinetic power density, and is followed by, Maine (ME), Washington (WA), Oregon (OR), California (CA), New Hampshire (NH), Massachusetts (MA), New York (NY), New Jersey (NJ), North and South Carolina (NC, SC), Georgia (GA), and Florida (FL). The average tidal stream power density at some of these locations can be larger than 8 kW/m2 with surface areas on the order of few hundred kilometers squared, and depths larger than 100 meters. The Cook Inlet in AK is found to have a substantially large tidal stream power density sustained over a very large area.

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Background

Tidal streams are high velocity sea currents created by periodic horizontal movement of the tides, often magnified by local topographical features such as headlands, inlets to inland lagoons, and straits. As tides ebb and flow, currents are often generated in coastal waters. In many places the shape of the seabed forces water to flow through narrow channels, or around headlands. Tidal stream energy extraction is derived from the kinetic energy of the moving flow; analogous to the way a wind turbine operates in air, and as such differs from tidal barrages, which create a head of water for energy extraction. A tidal stream energy converter extracts and converts the mechanical energy in the current into a transmittable energy form. A variety of conversion devices are currently being proposed or are under active development, from a water turbine similar to a scaled wind turbine, driving a generator via a gearbox, to an oscillating hydrofoil which drives a hydraulic motor.

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Tidal energy is one of the fastest growing emerging technologies in the renewable sector and is set to make a major contribution to carbon free energy generation.. The key advantage of tidal streams is the deterministic and precise energy production forecast governed by astronomy. In addition, the predictable slack water facilitates deployment and maintenance. In 2005, EPRI was first to study representative sites (Knik Arm, AK; Tacoma Narrows, WA; Golden Gate, CA; Muskeget Channel, MA; Western Passage, ME) without mapping the resources (EPRI, 2006g). Additional favorable sites exist in Puget Sound, New York, Connecticut, Cook Inlet, Southeast Alaska, and the Aleutian Islands among others. Besides large scale power production, tidal streams may serve as local and reliable energy sources for remote and dispersed coastal communities and islands. The extractable resource is not completely known; assuming 15% level of extraction, EPRI has documented 16 TWh/yr in Alaska, 0.6 TWh/yr in Puget Sound, and 0.4 TWh/yr in CA, MA, and ME (EPRI 2006b-f). The selection of location for a tidal stream energy converter farm is made upon assessment of a number of criteria:
Tidal current velocity and flow rate: the direction, speed and volume of water passing through the site in space and time.

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Other site characteristics: bathymetry, water depth, geology of the seabed and environmental impacts will determine the deployment method needed and the cost of installation.

Electrical grid connection and local cost of electricity: the seafloor cable distance from the proposed site to a grid access point and the cost of competing sources of electricity will also help determine the viability of an installation.

Following the guidelines in the EPRI report for estimating tidal current energy resources (EPRI 2006a), preliminary investigations of the tidal currents can be conducted based on the tidal current predictions provided by NOAA tidal current stations (NOAA, 2008b). There are over 2700 of these stations which are sparsely distributed in inlets, rivers, channels and bays. The gauge stations are concentrated along navigation channels, harbors and rivers but widely absent elsewhere along the coast. As an example, the maximum powers at some of these locations around the Savannah River on the coast of Georgia are shown in Figure 1. The kinetic tidal power per unit area, power density, given in this figure were calculated using the equation where ρis the density of water and V is the magnitude of the depth averaged maximum velocity.

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These tidal currents and therefore the available power per unit area can have significant spatial variability (Figure 1); therefore, measurements (or predictions) of currents at one location are generally a poor indicator of conditions at another location, even nearby. It is clear that the majority of the data is available along the navigation channel in the Savannah River, with sparse data within the rest of the tidal area. EPRI (2006a) suggest a methodology using continuity and the Bernoulli equation for determining the flow in different sections of a channel. This is a reasonable approach for flow along a geometrically simple channel, but is not applicable for the flow in the complex network of rivers and creeks along much of the US coastline. Thus we have applied a state-ofthe-art numerical model for simulating the tidal flows along the coast of the entire United States…

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Total theoretical available power estimates

The published maps and the database provide the distribution of the existing kinetic power density of tidal streams in the undisturbed flow conditions. These results do not include any technology assumptions or flow field effects as in the case of device arrays. In order to calculate a theoretical upper bound based on physics only, a simplified method that considers both the kinetic and potential power with the exclusion of any technology specific assumptions is applied. The details of the method is outlined in a recent paper (Garrett and Cummins, 2005). The power calculated with this method is used in estimating the tidal power potential for the entire country with a specific value for each state. The method uses undisturbed flow field from the model with simple analytical methods, accounts for the cumulative effect of dissipating energy and provides information on an estuary scale.
Considering a constricted channel connecting two large bodies of water in which the tides at both ends are assumed to be unaffected by the currents through the channel, a general formula gives the maximum average power as between 20 and 24% of the peak tidal pressure head times the peak of the undisturbed mass flux through the channel. This maximum average power is independent of the location of the turbine fences along the channel…

This upper bound on the available power ignores losses associated with turbine operation and assumes that turbines are deployed in uniform fences, with all the water passing through the turbines at each fence.

This method is applied to the locations bounded between two land masses and has locally increased tidal current speed along the United States coast. A list of these locations grouped by state is given in Table 6. The list displays the coordinates and the name of each location (i.e. the midpoint) together with the width, mean/maximum of the constriction and the total theoretical available power. The totals are given for each state and for the entire country. Once again, Alaska with a total of 47GW constitutes the largest piece of the national total of 50 GW. Cook Inlet has the largest average maximum available power of 18 GW (Figure A22) closely followed by Chatham Strait with 12 GW (Figure A20). Alaska is stands out as an abundant resource of tidal stream…

QUICK NEWS, January 31: NEW PROOF OF CHINA’S SUN PRICE GAMING; CHINA’S VIEW ON TURBINE TOWER PRICE GAMING; BIG BUCKS IN SMART GRID SECURITY

NEW PROOF OF CHINA’S SUN PRICE GAMING
SolarWorld: Import Surge Shows Tariff Evasion By Chinese Solar Producers
Jessica Lillian, 27 January 2012 (Solar Industry)

"SolarWorld and its partners in the Coalition for American Solar Manufacturing (CASM) have unearthed new PV module import data that, according to the coalition, proves that Chinese solar producers flooded the market with product at the end of 2011. The CASM believes this information warrants the application of retroactive duties on Chinese imports.

"SolarWorld filed its initial anti-dumping complaint and countervailing-duty petition last fall, claiming that low-priced crystalline silicon (c-Si) PV cells and modules from Chinese companies have violated international trade laws and harmed U.S.-based solar manufacturing…The International Trade Commission (ITC) made a preliminary determination last December that there is a ‘reasonable indication’ that Chinese manufacturers' practices are detrimental to the domestic solar industry…[The new CASM analysis] found that Chinese c-Si producers have more than doubled their imports into the U.S. since July 2011. This surge, the coalition says, constitutes ‘critical circumstances’ (as defined by the U.S. Department of Commerce) and justifies the implementation of tariffs on imports dating back to Nov. 15…[A decision on that is due] Feb. 15."

click thru for more info

"Suntech…increased its imports into the U.S. by 76% in November, compared to October…[D]ata from the Customs and Border Protection's Port Import Export Reporting Service (PIERS)…[shows] Trina Solar's imports surged 209% in the first half of last December…[O]verall, Chinese imports of solar cells and modules in 2011 increased 346% by quantity and 138% by value, year-over-year. Since 2008, imports from China have risen 939% by value and 1,664% by quantity.

"Whether the end-of-2011 ramp-up in imports is linked to the threat of potential duties, however, remains up for debate…Suntech…[said] the Dec. 31 expiration of the U.S. Department of Treasury's Section 1603 cash-grant program created a strong uptick in demand for the company's products in the U.S. Per the rules of the Section 1603 program, a solar developer needed to at least begin construction on a PV project by the end of 2011 in order to remain eligible for the incentive…Trina Solar similarly denied SolarWorld's claims…Analysts from Jefferies & Co. also attributed the spike in Chinese imports to normal seasonality trends and the end of the Section 1603 program…[President Obama has] indicated support of the complaint…"


CHINA’S VIEW ON TURBINE TOWER PRICE GAMING
China Voices 'Deep Concern' Over U.S. Wind Tower Probe; Investigation by U.S. Commerce Department will examine whether towers from China and Vietnam were subsidized and sold at less than fair value.
January 21, 2012 (AFP via Industry Week)

"China expressed ‘deep concern’…after the U.S. launched a probe into Chinese wind towers that it suspects of being unduly subsidized and sold at a loss on the American market…[saying it would] hamper bilateral cooperation in the field of new energy…harm the interests of U.S. industries…[and] go against global efforts to tackle the challenges of climate change and energy security…

"The U.S. Department of Commerce…[has] opened an inquiry on wind towers made in China and Vietnam…The petitioner for these investigations is the Wind Tower Trade Coalition, comprised of Broadwind Towers...DMI Industries...Katana Summit...and Trinity Structural Towers..."

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"…[China's Ministry of Commerce said if] hopes the U.S. side can respect relevant laws and facts, and abide by the commitment made at the G20 summit in Cannes that all countries should avoid introducing new trade protectionism…

"A wind tower is the structure that supports the engine and blades used to generate wind energy, and the tower captures that energy…If the probe reveals the towers have been sold at a loss, the U.S. could take out anti-dumping measures, conforming to the rules set down by the World Trade Organization…In 2010, imports of utility-scale wind towers from China and Vietnam were valued at an estimated $103.6 million and $51.9 million, respectively…"


BIG BUCKS IN SMART GRID SECURITY
Pike Pulse Report: Smart Grid Cyber Security Threat Management; Assessment of Strategy and Execution for 15 Leading Cyber Security Vendors

"Smart grid cyber security remains a nascent market…[with] established smart grid specialists, niche players, and well-known enterprise security vendors…[C]yber security is often considered a mature market…[but] smart grid cyber security…is not mature at all. The leaders that we identify in this analysis are well positioned for today’s market but some of the large corporations entering the scene can shape a market to their own

"…For the moment, size and scale appear to be somewhat of a disadvantage. Specialist companies have fared well. The ability to quickly react to the market has prevailed so far, but it is by no means certain that large size will remain a disadvantage in the future…"

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"Some trends in the smart grid industry may cause significant change during the coming twelve months. Chief among those, utilities are making it clear that they see the most meaningful ROI in distribution automation, not in smart metering. Smart grid vendors, and therefore security vendors as well, are beginning to hear and process that message. The Leaders in our ranking already have done that.

"This Pike Research report evaluates 15 of the leading cyber security threat management vendors in the smart grid market and rates them on 12 criteria for strategy and execution, including vision, go-to-market strategy, partnerships, product strategy and roadmap, technical innovation, geographic reach, market share, sales and marketing, product performance and features, product portfolio, control system focus, and staying power…"

TODAY’S STUDY: ENERGY OLD AND NEW, THE GOVERNMENT REPORT

Annual Energy Outlook 2012 Early Release Overview
January 23, 2012 (U.S. Energy Information Administration)

AEO2012 Early Release Overview Executive Summary

Projections in the Annual Energy Outlook 2012 (AEO2012) Reference case focus on the factors that shape U.S. energy markets in the long term, under the assumption that current laws and regulations remain generally unchanged throughout the projection period. The AEO2012 Reference case provides the basis for examination and discussion of energy market trends and serves as a starting point for analysis of potential changes in U.S. energy policies, rules, or regulations or potential technology breakthroughs. Some of the highlights in the AEO2012 Reference case include:

Projected growth of energy use slows over the projection period, reflecting an extended economic recovery and increasing energy efficiency in end-use applications Projected transportation energy demand grows at an annual rate of 0.2 percent from 2010 through 2035 in the Reference case, and electricity demand grows by 0.8 percent per year. Energy consumption per capita declines by an average of 0.5 percent per year from 2010 to 2035. The energy intensity of the U.S. economy, measured as primary energy use in British thermal units (Btu) per dollar of gross domestic product (GDP) in 2005 dollars, declines by 42 percent from 2010 to 2035.

Domestic crude oil production increases Domestic crude oil production has increased over the past few years, reversing a decline that began in 1986. U.S. crude oil production increased from 5.1 million barrels per day in 2007 to 5.5 million barrels per day in 2010. Over the next 10 years, continued development of tight oil, in combination with the ongoing development of offshore resources in the Gulf of Mexico, pushes domestic crude oil production in the Reference case to 6.7 million barrels per day in 2020, a level not seen since 1994. Even with a projected decline after 2020, U.S. crude oil production remains above 6.1 million barrels per day through 2035.

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With modest economic growth, increased efficiency, growing domestic production, and continued adoption of nonpetroleum liquids, net petroleum imports make up a smaller share of total liquids consumption U.S. dependence on imported petroleum liquids declines in the AEO2012 Reference case, primarily as a result of growth in domestic oil production by more than 1 million barrels per day by 2020; an increase in biofuels use of more than 1 million barrels per day crude oil equivalent by 2024; and modest growth in transportation sector demand through 2035. Net petroleum imports as a share of total U.S. liquid fuels consumed drop from 49 percent in 2010 to 36 percent in 2035 in AEO2012 (Figure 1). Proposed fuel economy standards covering vehicle model years 2017 through 2025 that are not included in the Reference case would further reduce projected liquids use and the need for liquids imports.

Natural gas production increases throughout the projection period Much of the growth in natural gas production is a result of the application of recent technological advances and continued drilling in shale plays with high concentrations of natural gas liquids and crude oil, which have a higher value in energy equivalent terms than dry natural gas. Shale gas production increases from 5.0 trillion cubic feet in 2010 (23 percent of total U.S. dry gas production) to 13.6 trillion cubic feet in 2035 (49 percent of total U.S. dry gas production) (Figure 2).

U.S. production of natural gas is expected to exceed consumption early in the next decade The United States is projected to become a net exporter of liquefied natural gas (LNG) in 2016, a net pipeline exporter in 2025, and an overall net exporter of natural gas in 2021. The outlook reflects increased use of LNG in markets outside of North America, strong domestic natural gas production, reduced pipeline imports and increased pipeline exports, and relatively low natural gas prices in the United States compared to other global markets.

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Use of renewable fuels and natural gas for electric power generation rises The natural gas share of electric power generation increases from 24 percent in 2010 to 27 percent in 2035, and the renewables share grows from 10 percent to 16 percent over the same period. In recent years, the U.S. electric power sector’s historical reliance on coal-fired power plants has begun to decline. Over the next 25 years, the projected coal share of overall electricity generation falls to 39 percent, well below the 49-percent share seen as recently as 2007 (Figure 3), because of slow growth in electricity demand, continued competition from natural gas and renewable plants, and the need to comply with new environmental regulations.

Total U.S. energy-related carbon dioxide emissions remain below their 2005 level through 2035 Energy-related carbon dioxide (CO2) emissions grow by 3 percent from 2010 to 2035, to a total of 5,806 million metric tons in 2035. They are more than 7 percent below their 2005 level of 5,996 million metric tons in 2020 and are still below the 2005 level at the end of the projection period (Figure 4). Emissions per capita fall by an average of 1 percent per year from 2005 to 2035, as growth in demand for transportation fuels is moderated by higher energy prices and Federal corporate average fuel economy (CAFE) standards, and as electricity-related emissions are tempered by efficiency standards, State renewable portfolio standard (RPS) requirements, competitive natural gas prices that dampen coal use by electricity generators, and the need to comply with new environmental regulations. Proposed fuel economy standards covering model years 2017 through 2025 that are not included in the Reference case would further reduce projected energy use and emissions.

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Introduction

In preparing the AEO2012 Reference case, the U.S. Energy Information Administration (EIA) evaluated a wide range of trends and issues that could have major implications for U.S. energy markets. This overview presents the AEO2012 Reference case and compares it with the AEO2011 Reference case released in April 2011 (see Table 1 on pages 12-13). Because of the uncertainties inherent in any energy market projection, the Reference case results should not be viewed in isolation. Readers are encouraged to review the alternative cases when the complete AEO2012 publication is released, in order to gain perspective on how variations in key assumptions can lead to different outlooks for energy markets.

To provide a basis against which alternative cases and policies can be compared, the AEO2012 Reference case generally assumes that current laws and regulations affecting the energy sector remain unchanged throughout the projection (including the implication that laws which include sunset dates do, in fact, become ineffective at the time of those sunset dates). This assumption helps increase the comparability of the Reference case with other analyses, clarifies the relationship of the Reference case to other AEO2012 cases, and enables policy analysis with less uncertainty arising from speculative legal or regulatory assumptions. Currently, there are many pieces of legislation and regulation that appear to have some probability of being enacted in the not-too-distant future, and some existing laws include sunset provisions that may be extended. However, it is difficult to discern the exact forms that the final provisions of pending legislation or regulations will take, and sunset provisions may or may not be extended. Even in situations where existing legislation contains provisions to allow revision of implementing regulations, those provisions may not be exercised consistently. In certain situations, however, where it is clear that a law or regulation will take effect shortly after the AEO Reference case is completed, it may be considered in the projection.

As in past editions of the AEO, the complete AEO2012 will include additional cases, many of which reflect the impacts of extending a variety of current energy programs beyond their current expiration dates and the permanent retention of a broad set of programs that currently are subject to sunset provisions. In addition to the alternative cases prepared for AEO2012, EIA has examined proposed policies at the request of Congress over the past few years. Reports describing the results of those analyses are available on EIA’s website.1

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Key updates made for the AEO2012 Reference case include the following:

• Industrial cogeneration was updated with historical rather than assumed capacity factors for new units and with updated investment decision procedures that reflect regional acceptance rates for new cogeneration facilities.

• A new heavy-duty vehicle model was adopted in the transportation module, with greater detail on size classes and end-use vehicle types to enable modeling of fuel economy regulations covering the heavy-duty vehicle fleet.

• The light-duty fleet model in the transportation module was updated to include a new algorithm for consumer purchase choice that compares fuel savings against incremental vehicle cost for advanced technologies, new technology cost and performance assumptions, and representation of fuel efficiency standards already in effect.

• Shale gas resource estimates for four plays (Haynesville, Fayetteville, Eagle Ford, and Woodford) were updated using the mean value of resource assessments recently released by the U.S. Geological Survey (USGS). The shale gas resource estimate for the Marcellus play was updated using new geologic data from the USGS and recent production data. EIA’s estimate of Marcellus resources is substantially below the estimate used for AEO2011 and falls within the 90-percent confidence range in the August 2011 USGS assessment, although it is higher than the USGS mean value.

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• The tight oil resource estimate for the Bakken play was increased to include more of the Three Forks and Sanish zones.

• The handling of U.S. LNG exports of domestically sourced gas was updated, resulting in exports beginning in 2016.

• The electricity module was updated to incorporate the Cross-State Air Pollution Rule (CSAPR)2 as finalized by the EPA in July 2011. CSAPR requires reductions in emissions from power plants that contribute to ozone and fine particle pollution in 28 States.

• Assumptions regarding the potential for capacity uprates at existing nuclear plants and the timing for existing nuclear plant retirements were revised.

• Updates were made to reflect recent information pertaining to retirement dates for existing power plants and scheduled in-service dates for new power plants.

• California Assembly Bill 32 (AB 32), the Global Warming Solutions Act of 2006, was incorporated for electricity sector power plants serving California. As modeled, AB 32 imposes a limit on power sector CO2 emissions, beginning in 2012 and declining at a uniform annual rate through 2020.

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Economic growth

Recovery from the 2008-2009 recession is expected to show the slowest growth of any recovery since 1960. Table 2 compares average annual growth rates over a five-year period following U.S. recessions that have occurred since 1960.

For the most recent recession, the expected five-year average annual growth rate in real GDP from 2009 to 2014 is 1.3 percentage points below the corresponding average for the three past recessions, with consumption and non-farm employment recovering even more slowly. The slower growth in the early years of the projection has implications for the long term, with a lower economic growth rate leading to a slower recovery in employment and higher unemployment rates.

Real GDP in 2035 is 4 percent lower in the AEO2012 Reference case than was projected in the AEO2011 Reference case. Real GDP grows by an average of 2.6 percent per year from 2010 to 2035 in the AEO2012 Reference case, 0.1 percent per year lower than in the AEO2011 Reference case. The Nation’s population, labor force, and productivity grow at annual rates of 0.9 percent, 0.7 percent, and 1.9 percent, respectively, from 2010 to 2035.

Beyond 2012, the economic assumptions underlying the AEO2012 Reference case reflect trend projections that do not include short-term fluctuations. Economic growth projections for 2012 are consistent with those published in EIA’s October 2011 Short-Term Energy Outlook….

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Energy Prices…

Natural gas

With increased production, average annual wellhead prices for natural gas remain below $5 per thousand cubic feet (2010 dollars) through 2023 in the AEO2012 Reference case. The projected prices reflect continued industry success in tapping the Nation’s extensive shale gas resource. The resilience of drilling levels, despite low natural gas prices, is in part a result of high crude oil prices, which significantly improve the economics of natural gas plays that have high concentrations of crude oil, condensates, or natural gas liquids. After 2023, natural gas prices generally increase as the numbers of tight gas and shale gas wells drilled increase to meet growing domestic demand for natural gas and offset declines in natural gas production from other sources. Natural gas prices rise as production gradually shifts to resources that are less productive and more expensive. Natural gas wellhead prices (in 2010 dollars) reach $6.52 per thousand cubic feet in 2035, compared with $6.48 per thousand cubic feet (2010 dollars) in AEO2011.

Coal

The average minemouth price of coal increases by 1.4 percent per year in the AEO2012 Reference case, from $1.76 per million Btu in 2010 to $2.51 per million Btu in 2035 (2010 dollars). The upward trend of coal prices primarily reflects an expectation that cost savings from technological improvements in coal mining will be outweighed by increases in production costs associated with moving into reserves that are more costly to mine. The coal price outlook in the AEO2012 Reference case represents a change from the AEO2011 Reference case, where coal prices were essentially flat.

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Electricity

Following the recent rapid decline of natural gas prices, real average delivered electricity prices in the AEO2012 Reference case fall from 9.8 cents per kilowatthour in 2010 to as low as 9.2 cents per kilowatthour in 2019, as natural gas prices remain relatively low. Electricity prices tend to reflect trends in fuel prices—particularly, natural gas prices, because in much of the country natural gas-fired plants often set wholesale power prices. It can take time, however, for fuel price changes to affect electricity prices because of the varying lengths of fuel- and power-supply contracts and the periods between electricity rate cases. In the AEO2012 Reference case, electricity prices are higher throughout the projection than they were in the AEO2011 Reference case. Although natural gas prices to electricity generators are similar to those in AEO2011, the cost of coal is higher. In addition, reliance on natural gas-fired generation in the power sector increases partially as a result of new environmental regulation covering emissions of sulfur dioxide (SO2) and nitrogen oxides (NOX) that make it a more economical option. Electricity prices in 2035 are 9.5 cents per kilowatthour (2010 dollars) in the AEO2012 Reference case, compared with 9.3 cents per kilowatthour in the AEO2011 Reference case….

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Electricity generation

Total electricity consumption, including both purchases from electric power producers and on-site generation, grows from 3,879 billion kilowatthours in 2010 to 4,775 billion kilowatthours in 2035 in the AEO2012 Reference case, increasing at an average annual rate of 0.8 percent, about the same rate as in the AEO2011 Reference case.

The combination of slow growth in electricity demand, competitively priced natural gas, programs encouraging renewable fuel use, and the implementation of new environmental rules dampens coal use in the future. The AEO2012 Reference case includes the impacts of the CSAPR, which was finalized in July 2011 and was not represented in the AEO2011 Reference case. CSAPR requires reductions in SO2 and NOX emissions in roughly one-half of the States, with an initial target in 2012 and further reductions in 2014. Even so, coal remains the dominant energy source for electricity generation, but its share of total generation declines from 45 percent in 2010 to 39 percent in 2035 (see Figure 3 on page 2). Market concerns about GHG emissions continue to slow the expansion of coal-fired capacity in the AEO2012 Reference case, even under current laws and policies. Low projected fuel prices for new natural gas-fired plants also affect the relative economics of coal-fired capacity, as does the continued rise in construction costs for new coal-fired power plants. As retirements outpace new additions, total coal-fired generating capacity falls from 318 gigawatts in 2010 to 301 gigawatts in 2035 in the AEO2012 Reference case.

Electricity generation using natural gas is higher in the AEO2012 Reference case than was projected in the AEO2011 Reference case, particularly over the next 10 years, during which natural gas prices are expected to remain low. New natural gas-fired plants also are much cheaper to build than new renewable or nuclear plants. In 2015, natural gas-fired generation in AEO2012 is 13 percent higher than in AEO2011, and in 2035 it is still 6 percent higher. Electricity generation from nuclear power plants grows by 11 percent in the AEO2012 Reference case, from 807 billion kilowatthours in 2010 to 894 billion kilowatthours in 2035, accounting for about 18 percent of total generation in 2035 (compared with 20 percent in 2010).

Nuclear generating capacity increases from 101 gigawatts in 2010 to a high of 115 gigawatts in 2025, after which a few retirements result in a decline to 112 gigawatts in 2035. AEO2012 incorporates new information about planned nuclear plant construction, as well as an updated estimate of the potential for capacity uprates at existing units. A total of 10 gigawatts of new nuclear capacity is projected through 2035, as well as an increase of 7 gigawatts achieved from uprates to existing nuclear units. About 6 gigawatts of existing nuclear capacity is retired, primarily in the last few years of the projection, as not all owners of existing nuclear capacity apply for and receive license renewals to operate their plants beyond 60 years. Increased generation from renewable energy in the electric power sector, excluding hydropower, accounts for 33 percent of the overall growth in electricity generation from 2010 to 2035.

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Generation from renewable resources grows in response to Federal tax credits, State-level policies, and Federal requirements to use more biomass-based transportation fuels, some of which can produce electricity as a byproduct of the production process. Near-term market growth in some sectors, such as solar energy, is projected to result in significantly reduced costs in the AEO2012 Reference case, increasing the projected growth for those resources as compared with the AEO2011 projections. More retirements of coal-fired capacity are expected in the AEO2012 Reference case than were projected in AEO2011 because of slower growth in electricity demand, continued competition from natural gas and renewable plants, and the need to comply with new environmental regulations. Growth in renewable generation is supported by many State requirements, as well as new regulations on CO2 emissions in California. The share of U.S. electricity generation coming from renewable fuels (including conventional hydropower) grows from 10 percent in 2010 to 16 percent in 2035. In the AEO2012 Reference case, Federal subsidies for renewable generation are assumed to expire as enacted. Extensions of such subsidies could have a large impact on renewable generation.

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Energy-related CO2 emissions

Although total U.S. energy-related CO2 emissions increased by almost 4 percent in 2010, they do not return to their 2005 level (5,996 million metric tons) by the end of the AEO2012 projection period (see Figure 4 on page 2). Emissions per capita fall by an average of 1 percent per year from 2005 to 2035, as growth in demand for transportation fuels is moderated by higher energy prices and Federal CAFE standards. In addition, electricity-related emissions are tempered by efficiency standards, State RPS requirements, and implementation of the CSAPR, which helps shift the fuel mix away from coal toward lower carbon fuels.

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Energy-related CO2 emissions reflect the mix of fossil fuels consumed. Given the high carbon content of coal and its use to generate 45 percent of the U.S. electricity supply in 2010, prospects for CO2 emissions depend, in part, on growth in electricity demand as well as the portion of that demand satisfied by coal-fired generation. After declining from 2007 to 2009, electricity sales grew in 2010 by 4.3 percent. Electricity sales continue to grow through 2035 in the AEO2012 Reference case, but the growth is tempered by a variety of regulatory and socioeconomic factors, including appliance and building efficiency standards and a continued transition to a more service-oriented economy. The combination of slow demand growth, competitive natural gas prices, and CSAPR included in the AEO2012 Reference case lowers the consumption of coal within the first 5 years of the projection period; as a result, emissions from coal combustion in the power sector in 2015 are 149 million metric tons below the AEO2011 Reference case projection. With modest growth in electricity demand and increased use of renewables for electricity generation, electricity-related CO2 emissions grow by a total of 4.9 percent (0.2 percent per year) from 2010 to 2035. Growth in CO2 emissions from transportation activity also slows in comparison with the recent pre-recession experience, as Federal CAFE standards increase the efficiency of the vehicle fleet, employment recovers slowly, and higher fuel prices moderate growth in travel. The AEO2012 Reference case projections do not include proposed increases in fuel economy standards for model years 2017 through 2025, which are expected to further reduce fuel use and emissions.

Taken together, these factors tend to slow the growth in primary energy consumption and CO2 emissions. As a result, energy-related CO2 emissions in 2035 are only 3 percent higher than in 2010 (as compared with the 10-percent increase in total energy use), and the carbon intensity of U.S. energy consumption falls from 57.4 to 53.8 kilograms per million Btu (6.3 percent). Over the same period, U.S. economic activity becomes less carbon-intensive, as energy-related CO2 emissions per dollar of GDP decline by 45 percent.

QUICK NEWS, January 30: ADVANCING WIND’S ABILITY; INSTALLER COSTS NOW KEY TO SUN; THE BIG BUSINESS OF BUILDINGS’ ENERGY

ADVANCING WIND’S ABILITY
Gamesa Working With NREL On Wind Turbine R&D And Offshore Wind Technology
27 January 2012 (North American Windpower)

"Gamesa Technology Corp. Inc. and the U.S. Department of Energy's National Renewable Energy Laboratory (NREL) are teaming up to study and test a variety of components and systems that will guide the develpment of the next generation of wind turbines designed specifically for the U.S. marketplace.

"Gamesa and NREL will collaborate on work in three key areas: developing new wind turbine components and rotors for the U.S. market; researching and testing the performance of new control strategies; and devising models that will help advance the development of offshore wind in U.S. coastal waters."

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"Using Gamesa's turbine platform as a laboratory, researchers will study the behavior of systems and how new designs, products or equipment can affect performance.

"Chief among the goals of this research-and-development (R&D) project is the design of new products specifically for the U.S. market, with a sharp focus on interior and exterior components, as well as the rotors themselves…In addition, Gamesa and NREL will work to develop new control strategies that improve energy capture while decreasing loads…"


INSTALLER COSTS NOW KEY TO SUN
Downstream Investments Now Supporting Photovoltaic Installer Innovation
27 Janauary 2012 (Solar Industry)

"With the solar energy industry maturing rapidly and expanding to newer markets, the focus of innovation and investment has shifted from panels to installations - the final critical step for monetization…[Start-ups raised over $1 billion, with SolarCity, SunRun, Recurrent Energy, SunEdison and Solar Power Partners leading the way]…

"A flurry of mergers and acquisitions activity and an influx of venture capital dollars to solar service providers have led to innovation concentrated on creating new, lean business models in an extremely fragmented downstream landscape…SolarCity dominates among residential installers…[C]ompanies are partnering with SunRun, adding muscle to SolarCity's biggest competitor. The Alteris-Real Goods Solar merger in December has added a stronger player to the market."

From solarcity100 via YouTube

"…Commercial- and utility-scale solar have few up-and-coming players. Tioga Energy and Enfinity lead the group of new large-scale developers. The acquisitions of Recurrent Energy, SunEdison and Solar Power Partners led to concentration of large-scale development in the hands of larger companies or vertically integrated suppliers First Solar and SunPower.

"New entrants keep popping up on the back of venture dollars…A burst of entrepreneurial activity, driven by venture capital, is ensuring a steady stream of high-potential start-ups. In 2011, six solar installers were among Inc. Magazine's top 50 fastest-growing companies in the U.S., including Greenspring Energy, re2g, SunDurance Energy, OnForce Solar and FLS Energy."


THE BIG BUSINESS OF BUILDINGS’ ENERGY
Breaking Down the BEMS Market
Jevan Fox, October 28, 2010 (Pike Research)

"…Building Energy Management Systems (BEMS)…[from] Pike Research highlights that buildings over 500,000 SF represent the low-hanging fruit in the BEMS industry…[But] vast potential markets of smaller 25,000 SF, 50,001-100,000 SF, and 100,001-200,000 SF represent…$16 billion, $15 billion, and $16 billion, respectively, of annual energy expenditures, or approximately $47 billion when compounded. That figure accounts for approximately 80% of the total annual energy expenditures of all the other building segmentations.

"…[T]hese segments are underserved by the BEMS market. Clearly, the 100,001 200,000 SF segment will provide the next potential market for BEMS players. It is already showing promise, as several BEMS vendors are focusing considerable attention on the segment. This is especially true of BEMS vendors providing a software-as-a-service (SaaS) model…"

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"Additionally, the more energy progressive states and the more active grid operators in those states will drive utilities to assists in metering smaller buildings. As more buildings receive incentives to install meters, the costs to implement a BEMS will drop in parallel.

"The DOE 2009 Buildings Energy Data Book states that the energy expenditure per SF 100,001-200,000 SF…is $1.57, representing an energy expense of $16,091,000,000 total for the segment. That is more than the total energy expense for any other segment, including 200,000-500,000 SF, 500,001 SF-1,000,000 SF, and greater than 1,000,000 SF. When looking to the smaller buildings (<100,000), the value proposition drops off precipitously, even though the total SF and energy expenditures per SF are high…"

CHEAPER AND CHEAPER SUN

Polysilicon Price Declines Will Continue Sector Shakeout, says GTM Research
Mark Osborne, January 25, 2012 (PV-Tech via PV Group)

"A new and detailed bottom-up analysis of the polysilicon industry by GTM Research further supports growing consensus that polysilicon prices will continue to set record lows in 2012 as they did in 2011 as overcapacity continues. Lower silicon prices in 2012 will likely lead to even lower c-Si module prices and force higher-cost poly producers to exit the market.

"A key consequence of continued low polysilicon prices at or below US$30/kg is expected to see module manufacturers saving approximately US$0.20 per watt, which could bring module prices below US$0.70 per watt, according to GTM Research…"

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"…[M]ajor producers that have significant scale and high-purity products will survive in a low-priced environment, while small-scale producers will struggle to sell at or below US$30/kg, forcing the vast majority to shutter operations and causing many to exit the sector completely…GTM Research expects to see established players such as Hemlock Semiconductor, Wacker, GCL Solar, REC, OCI and Tokuyama to weather this extended period of pricing weakness...

"…[O]versupply in the polysilicon market pushed the spot price of silicon down from US$80/kg in late March 2011 to under US$30/kg in December, representing a more than 60% price drop…[C]ontract renegotiations are inevitable. Average contract pricing was closer to US$50/kg in 3Q 2011, but the collapse in spot pricing will likely pull the contract pricing down sharply."