Sopogy, Inc. Inaugurates World's First MicroCSP Solar Thermal power Plant In Hawaii

Solar Thermal Plant Produces 2 Megawatts (MW) And Energy Storage at Natural Energy Laboratory of Hawaii

Holaniku at Keahole Point, Hawaii Concentrating Solar Power (CSP) Array

Natural Energy Laboratory of Hawaii, Kona, HI and Sopogy, Inc. of Honolulu, HI inaugurated the World’s first MicroCSP Solar Thermal Plant December 10, 2009 at the Natural Energy Laboratory of Hawaii.

According to the Sopogy Press Release the 2 Megawatt (MW) solar thermal energy project uses 1,000 Sopogy proprietary MicroCSP solar panels on 3.8 acres in the hot Kona desert.

“Through the use of mirrors and optics and an integrated sun tracker, these panels achieve higher efficiencies than conventional solar panels. The system also uses a unique thermal energy storage buffer that allows energy to be produced during cloudy periods and to shift energy produced from the day to evening periods.”

Holaniku at Keahole Point, Hawaii Solar Thermal Energy Storage

“The project name: ‘Holaniku at Keahole Point’ comes from the Hawaiian term for a location that has everything required for self-sufficiency.”

“MicroCSP is an achievement in rugged, modular and cost effective solar thermal technology.” According to Darren T. Kimura, President and CEO of Sopogy, Inc., “The completion and demonstration of this 2 megawatt solar thermal project is an important first step in bringing the solution to the World.”

“With the initialization of the Hawaii Clean Energy Initiative, the state has become a magnet for renewable energy project development. Sopogy and its local solar project development partner Keahole Solar Power have a goal to bring 30 megawatts of MicroCSP power to the state by 2015.”

Sopogy Total Solar Solutions

Contact: Ann Fitzgerald – Marketing and Public Relations Coordinator, Sopogy, Inc.

Email: afitzgerald@sopogy.com Tel: 808.237.2422

Sopogy Mirrored Solar Collectors, Holaniku at Keahole Point, Hawaii

Photo by Baron Sekiya, Hawaii 24/7

ROOFTOP & SMALL-SCALE CONCENTRATING SOLAR POWER NOW COMMERCIALLY AVAILABLE

Sopogy SopoFlare Rooftop Parabolic Mirror Collector

This system for rooftop mounting measures 8 feet long by about 2 feet high with a mirror width of about 2.5 feet.

Sopogy of Honolulu, HI announced on October 27, 2009 that the company is releasing the world’s first commercially available rooftop concentrating solar thermal power system.

Sopogy claims that its SopoFlare MicroCSP parabolic mirror system is priced at 30 percent cheaper than competing rooftop solar technologies.

According to the Sopogy Press Release:

“The system easily retrofits into existing facilities, reducing natural gas consumption (and) giving users an estimated 3-year payback on installation.”

“SopoFlare's compact design at 8 feet long by 2.5 feet wide is perfect for quick and easy installation by local HVAC and Plumbing professionals.”

“This brings concentrating solar power to the commercial and industrial facility in a cost effective, space efficient and contractor friendly solution.”

Sopogy’s products illustrate the range of scalability of concentrating solar thermal power (CSP/CSTP) installations. CSP/CSTP can provide utility-scale solar thermal electric power in excess of hundreds of megawatts as well as residential- and commercial-scale power in the range of a few kilowatts. In addition, CSP/CSTP can be used for air-conditioning, water heating, space heating, and commercial process heating.

Concentrating Solar Thermal Power (CSP/CSTP) has a significantly higher conversion efficiency of sunlight into energy. CSP/CSTP systems currently boast efficiencies ranging from about 20 to 40 percent compared with about 15 percent for most commercially available solar photovoltaic (PV) systems. CSP/CSTP systems also are able to produce excess heat during daylight hours that can be stored for use during cloud cover, darkness, or to supplement peak power demands.

Concentrating Solar Thermal Electric Power Generation Schematic showing Parabolic Trough Mirrors and Thermal Storage Tanks. Parabolic trough mirrors focus solar heat onto a fluid-filled pipe. The heated fluid is carried to storage and/or to a heat exchanger that heats water into steam. The steam runs the turbine that generates electricity.

Andasol 1 Concentrating Solar Thermal Electric Power Plant Parabolic Trough Mirrors & People for Scale

Andasol 1 is one of three similar CSTP plants constructed or planned in the Aldeire and La Calahorra area, Marquesao del Zenete Region, Granada Province, Spain

Andasol Power plants 1, 2, & 3 are each designed using 209,664 mirrors. The solar field peak efficiency is about 70 percent, and the annual average solar field peak efficiency is about 50 percent. Molten salt thermal storage retains enough heat for about 7.5 peak load hours of operation during cloudy or dark conditions, or in response to demand. Each of the three Andasol CSTP plants is rated at about 50 megawatts (MW) of power. The peak efficiency of each CSTP plant is about 28 percent, with an annual average efficiency of about 15 percent. The estimated lifespan of the power plants is at least 40 years.

Reegle Launches A Map Of The Clean Energy World

The Renewable Energy & Energy Efficiency Partnership (REEEP) announced on April 27, 2009 that it now provides a global map to assist researchers with information on clean energy topics by country.

The “Reegle Maps” application provides a visual entry point to clean energy news and projects by countries and regions. The map allows searches by sectors under the major headings of:

• Climate Protection
• Cogeneration
• District Heating Systems
• Energy Efficiency
• Renewable Energy
• Rural Electrification,
  
• ...and many subheadings under these major headings.

“Reegle acts as a unique state-of-the-art search engine, targeting specific stakeholders including governments, project developers, businesses, financiers, NGOs, academia, international organizations and civil society.”

“Reegle’s information gateway provides information and data on all the various sub-sectors within sustainable energy at a global level including:

• Jurisdiction and laws
• News and announcements
• Political declarations and discussion papers
• Project activity and financial reports
• Statistical data
• Studies, manuals and reports
• Tenders, grants and bids”

The REEEP was launched at the Johannesburg, South Africa World Summit on Sustainable Development (WSSD) in 2002. The REEEP’s goal is to accelerate the global marketplace for energy efficiency and renewable energy. The partner organizations actively facilitate financing mechanisms for sustainable energy projects, and structure policy initiatives for clean energy markets.

The REEEP lists of partners, international organizations, MOU organizations, governments, and international processes offers an impressive overview of global attention to creating a new energy economy.

USA National Science Board Wants Your Input On A Sustainable Energy Future

NSB Task Force on Sustainable Energy Public Review and Comment Opportunity

The USA National Science Board released for public review and comments the 61-page draft report, Building a Sustainable Energy Future (NSB-09-35) and dated April 10, 2009.

The report contains a wealth of information on USA energy science, technology, economics and policy by way of tight summaries based on an extensive reference list.

The public invitation for review and comments says:

"The fundamental transformation of the current extractive U.S. fossil fuel energy economy to a sustainable energy economy is a critical grand challenge facing the Nation today."

"Transforming toward a sustainable energy economy requires national leadership and coordination, a new U.S. energy policy framework, and robust support for sustainable energy research, development, demonstration, deployment, and education (RD3E). In its report, the Board makes a number of recommendations to the U.S. Government and offers guidance to the National Science Foundation."

"Given the importance to promote national security through increasing U.S. energy independence, ensure environmental stewardship and reduce energy and carbon intensity, and generate continued economic growth through innovation in energy technologies and increases in green jobs, we hope that you will take this opportunity to express your views on the draft report."

"Submit comments by Friday, May 1, 2009, to Tami Tamashiro, Executive Secretary, Task Force on Sustainable Energy, at NSBenergy@nsf.gov. If you have any questions, contact Ms. Tamashiro at (703) 292-7000."

From the report:

U.S. Energy Supply (p. 9-10):

Today, 85 percent of the U.S. energy supply comes from the combustion of fossil fuels (e.g., oil, natural gas, and coal), and nuclear electric power provides 8 percent. Sustainable energy sources derived from water (hydroelectric), geothermal, wind, sun (solar), and biomass account for the remaining 7 percent of the U.S. energy supply. Dramatic advances and investment in the production, storage, and distribution of U.S. sustainable energy sources are needed to increase the level of sustainable energy supplies.

U.S. Energy Consumption (p. 10):

U.S. energy consumption varies by economic sector and by energy source. About one-third of energy delivered in the United States is consumed by the industrial sector, and one-half of that is consumed by three industries (bulk chemicals, petroleum refining, and paper products). The transportation sector accounts for the second highest share of total end-use consumption at 29 percent, followed by the residential sector at 21 percent and the commercial sector at 18 percent.

Across all sectors, petroleum is the highest energy source at around 40 percent, followed by natural gas (23 percent), coal (22 percent), nuclear electric power (8 percent), and renewable energy (7 percent). The transportation sector has historically consumed the most petroleum, with its petroleum consumption dramatically increasing over the past few decades. In 2007, petroleum accounted for 95 percent of the transportation sector’s energy consumption.

Recommendation 2: Boost R&D Investment (p. 16-17): Increase Federal investment in sustainable energy R&D

• Support a range of sustainable energy alternatives, their enabling infrastructure, and their effective demonstration and deployment. Funding should support investigation into a wide range of sustainable energy RD3E topics, including, but not limited to:

Advanced, sustainable nuclear power;

Alternative vehicles and transportation technologies;

Basic S&E research that feeds into applied energy technologies;

Behavioral sciences as it relates to energy consumption;

Carbon capture and sequestration;

Economic models and assessments related to sustainable energy;

Energy efficiency technologies at all levels of generation, transmission, distribution and consumption;

Energy storage;

Information and communications technologies that can help conserve energy and/or use it more efficiently, such as broadband cyberinfrastructure;

Renewable energy supply technologies (e.g., solar, wind, geothermal,
hydroelectric, biomass/biofuels, kinetic, tidal, wave, ocean thermal technologies);

Smart grid;

“Systems” approach to large-scale sustainability solutions, including full life-cycle analyses of energy systems (e.g., advanced fossil-fuel technologies andbiomass-derived fuels); and

Zero-energy buildings.


Recommendation 3: Facilitate Essential Policies (p. 17):

Consider stable policies that facilitate discovery, development, deployment, and
commercialization of sustainable energy technologies to reflect advances in basic and applied
research

• Understand the explicit and implicit subsidies of current energy sources that impede conversion to the use of sustainable energy sources, and actively work to establish research-based strategies that encourage greater market deployment of sustainable energy technologies.

Conclusion (p. 22):

This report marks a concerted effort by the Board to join with colleagues and stakeholders throughout the Federal, private, academic, and nonprofit sectors to address the challenges and opportunities for sustainable energy in the 21st century. The recommendations made herein to the U.S. Government strive to promote leadership of harmonized efforts in moving toward a sustainable energy economy. In addition, the Board offers guidance for NSF that aims to prioritize innovation in sustainable energy, by supporting sustainable energy RD3E that leads to the development and deployment of viable sustainable energy technologies. With resolve and invigorated initiative, the United States is positioned to successfully build and support a sustainable energy future.

Appendix A: History and Context of Sustainable Energy (p.25-44):

Provides interesting reading on the topics listed under Recommendation 2 above, the current state of USA energy supply and consumption, and a USA legislative timeline from President Truman's signing of the Atomic Energy Act (McMahon Act) in 1946 to President Obama's signing of the American Recovery and Reinvestment Act of 2009.

South Africa To Produce 10,000 Gigawatt-Hours of Wind & Solar Energy Using Feed-In Tariffs

South Africa's National Energy Regulator (NERSA) in late March 2009 introduced a system of Feed-in Tariffs (FITs) intended to produce 10 (ten) Terawatt-hours (TWh) = 10,000 (ten thousand) Gigawatt-hours (GWh) of electricity generated from wind, solar, small hydro, and landfill gas for the country by 2013.

"Feed-In Tariffs - Boosting Energy For Our Future" Report Front Cover, World Future Council, Hamburg, Germany, 2008.

Feed-In Tariffs For South Africa:

A March 31, 2009 Media Announcement briefs the NERSA Decision on Renewable Energy Feed-In Tariff (REFIT).

The 40-page report, South Africa Renewable Energy Feed-In Tariff (REFIT) - Regulatory Guidelines 26 March, 2009, states in its introduction:

"Grid connected renewable energy is currently the fastest growing sector in the global energy market. Installed global wind capacity at the start of 2008 is in the order of 90GW, with total world installed capacity having doubled since 2004. India, China, the United States, Spain and Germany together added over 20GW of wind power in 2007. China and India each are currently installing wind electricity in excess of 1GW per annum and both have targets of achieving over 10GW by 2015. The capacity of grid connected solar PV has also quadrupled from an installed capacity of 2GW in 2004 to approaching 8GW at the end of 2007. Commercial-scale solar thermal power plants are also under construction in countries such as the US and Spain. Targets for the promotion of renewable energy now exist in more than 58 countries, of which 13 are developing countries."

'The renewable energy industry is now a major economic player, with the industry employing over 2.5 million people worldwide. Renewable energy companies have grown significantly in size in recent years, with the market capitalisation of publicly traded renewables companies doubling from $50 billion to $100 billion in just two years (2005-7)."

"South Africa has a high level of renewable energy potential and presently has in place targets of 10,000 GWh of renewable energy by 2013. To contribute towards this target and towards socio-economic and environmentally sustainable growth, and kick start and stimulate the renewable energy industry in South Africa, there is a need to establish an appropriate market mechanism."

"Feed-in Tariffs (FIT) are, in essence, guaranteed prices for electricity supply rather than conventional consumer tariffs. The basic economic principle underpinning the FITs is the establishment of a tariff (price) that covers the cost of generation plus a "reasonable profit" to induce developers to invest. This is quite similar to the concept of cost recovery used in utility rate regulation based on the costs of capital."

"Under this approach it becomes economically appropriate to award different tariffs for different technologies. The price for the electricity produced should be set at a level and for a period that provides a reasonable return on investment for a specific technology. The tariff should also be certain and long term enough to allow for project financing to be raised by the project."

"Feed-in tariffs to promote renewable energy have now been adopted in over 36 countries around the world, including Spain and Germany and a number of states in the US, and also including developing nations such as Turkey, Thailand, Sri Lanka, Nicaragua, Indonesia, Ecuador, China, Brazil, Argentina and most recently Kenya."

"The establishment of the Renewable Energy Feed-In Tariff (REFIT) in South Africa will provide an excellent opportunity for South Africa to increase the deployment of renewable energy in the country and contribute towards the sustained growth of the sector in the country, the region and internationally."






"Feed-In Tariffs - Boosting Energy For Our Future" Report Back Cover, World Future Council, Hamburg, Germany, 2008.

Hybrid CSTP/Natural Gas Power Plant Under Construction In Florida

The following information supplements the post of December 7, 2008 on a co-located solar/natural gas-fired power plant in Indiantown, Florida.

Co-locating industrial-scale solar power plants with existing fossil-fuel fired power plants can be an economical solution to power transmission and other problems. Co-location allows clean energy to be phased in as fossil-fuel energy is phased out, with the fossil-fuel energy plant becoming a backup, then eventually becoming unnecessary as solar heat storage technology improves.

Solar radiation is available onsite, whereas fossil fuels must be continually mined and transported to the old-technology plant. Co-locating solar power on the existing plant site takes advantage of transmission infrastructure already in place, avoiding costs of building extensive new transmission lines. Solar power plants avoid many of the water-use and land- and water-pollution problems of old-technology power plants. Thus, opportunities for land and water systems restoration after abandoning fossil-fuel power plants will increase substantially.

Lauren Engineers & Constructors and Florida Power & Light Company Building Martin Next Generation Solar Energy Center in Indiantown, Florida.

Lauren Engineers & Constructors is working with NextEra Energy Resources, a Florida Power & Light Company (FPL) Group Company on a new 75-megawatt (MW) concentrating solar thermal power (CSTP or CSP) facility.

The CSTP part of the facility will employ parabolic trough mirror technology and include approximately 180,000 parabolic mirrors on 500 acres of land. Solar power output is expected to be 155,000 megawatt-hours (MWhr) annually.

Artist's Conception of the FPL Martin Concentrating Solar Thermal/Natural Gas-Fired Power Plant, Indiantown, Florida.

Lauren Engineers & Constructors also worked with ACCIONA to build the Nevada Solar One Power Plant, a 64 MW parabolic mirror facility located in Boulder City, Nevada. This plant went online in June, 2007.








Nevada Solar One Concentrating Solar Thermal Power (CSTP) Plant, Boulder City, Nevada. This facility uses parabolic mirror technology and 182,000 curved mirrors, occupies 400 acres of land, and generates 64 megawatts (MW) of power. The plant began operating in June, 2007. Photograph: CNET News, March 12, 2007.


















Detail views of Nevada Solar One CSTP Plant showing parabolic mirror arrangement. The parabolic mirrors are aligned on north-south axes, and rotate from east to west throughout the day to track the sun. The mirrors focus sunlight on an oil-filled pipe that carries the heated oil to a heat exchanger. The heat exchanger creates steam that powers an electricity-generating turbine. Photographs: Acciona U.S. Projects.

Tracking The Sun

Solar Panels On Rooftops, Ohta, Japan, Focus Solar, 2008

Solar Photovoltaic Power Costs In USA Drop 30 Percent Over Past Decade

The Environmental Energy Technologies Division, Lawrence Berkeley National Laboratory in California released a new report, “Tracking the Sun,” that documents the installed costs of solar photovoltaic (PV) power in the USA from 1998-2007.

The February 27, 2009 revision of the 42-page document indicates a positive outlook for the future of customer economics of solar PV. Primary indicators include an oversupply of solar PV modules in the near future together with lifting the cap on the Federal Investment Tax Credit (ITC) for residential PV will reduce costs for residential installations. Large commercial solar PV promises to be the dominant growth market because of economies of scale, but both large and small solar PV systems stand to make major gains in reduced costs per unit of energy generated.

The report examines 37,000 grid-connected solar PV systems installed in 12 USA states from 1998-2007. Among these, average costs before financial incentives or tax credits declined from $10.50 per watt in 1998 to $7.6 per watt in 2007 – roughly a 35 percent cost reduction over ten years.

Non-module costs such as inverters, mounting hardware, labor, permitting and fees, shipping, overhead, taxes and profit were responsible for the bulk of cost reductions.

Systems less than 5 kilowatts in size exhibited the largest cost reductions; however, data are lacking for larger solar PV systems with output greater than 100 kilowatts.

Average costs for all systems flattened and remained almost unchanged from 2005-2007.

Installed costs of solar PV show economies of scale. Systems less than 2 kilowatts averaged about $9.00 per watt in 2006-2007, and systems greater than 750 kilowatts averaged about $6.80 per watt during the same period.

State and utility cash incentives for solar PV installations declined from 2002 through 2007.

The increase in the Federal ITC in 2006 tended to stimulate commercial-scale solar PV from 2007-2009; however, residential solar PV should gain cost advantages in 2009 with changes in the Federal residential ITC.

In its introduction, the report says: “Despite the significant year-on-year growth, however, the share of global and U.S. electricity supply met with PV remains small, and annual PV additions are currently modest in the context of the overall electric system.”

Nonetheless, the growth of solar PV is encouraging. The data on its declining costs with time offer a promise of even more accelerated growth in the next few years.

A February 25, 2009 brief at WorldChanging expands upon the following:

Business Green reported on February 23, 2009 that the price of solar PV panels could fall by as much as 40 percent by the end of this year. Other analysts have been predicting this price drop that is based on huge increases in polysilicon supplies leading to a drop in production costs.

New Energy Finance also predicts a fall in solar PV module prices because of recent global investments in increasing silicon production.

China-based solar PV panel manufacturer Suntech Power Holdings estimates that demand from the USA could reach 700 megawatts (MW) during 2009 as a result of President Obama’s new stimulus package.

Climate Progress suggests if the dramatic price drop for solar PV panels materializes, solar PV will become "...one of the largest job-creating industries of the century, projected to grow from $20 billion two years ago to a $74 billion industry by 2017."

Solar Electric Power And Renewable Energy Futures For Colorado

SES Stirling Energy Systems Solar One Power Plant in the Mojave Desert near Barstow, CA will develop 500 megawatts (MW) of electricity generating capacity with an expansion option to 850 MW. The plant will use 20,000 to 34,000 solar Dish/Stirling concentrators like the ones shown here.

A recent report on the renewable energy future of Colorado assesses the state’s potential to meet its own renewable energy standards (RESs) while also producing renewable energy for export to other markets.

The report is entitled, “Connecting Colorado’s Renewable Resources to the Markets -- Report of the Colorado Senate Bill 07-091 Renewable Resource Generation Development Areas Task Force Revised Edition July 2008”

The 64-page document treats wind, solar, hydroelectric, and geothermal power generation, and biomass, ethanol, and biodiesel fuels. The report sets these energies in the context of policy, economics, power transmission, land-use, and related elements. Importantly, the Task Force assesses electricity generation costs for different carbon dioxide (CO2) emissions penalty scenarios.

For wind and solar power, the Task Force identified “Generation Development Areas” or GDAs indicating power generation potential from specific regions of the state.

For wind power, the GDAs lie on the High Plains east of the Rocky Mountain Front and within which the Task Force found a potential for ninety-six (96) gigawatts (GW) of wind power generation. I will treat the implications of wind power development for Colorado and other regions in a future post.

For solar power, the Task Force defined two GDAs in the southern part of the state together having a potential to generate as much as thirteen hundred (1,300) gigawatts (GW) of electricity.

One "Central Solar Power" GDA is the San Luis Valley of south-central Colorado. The other, larger GDA includes a region extending from the eastern base of the Sangre de Cristo Mountains well into the High Plains of southeastern Colorado along the Colorado-New Mexico border.

The Task Force acknowledges the impracticality of the 1,300-GW scale of generation, saying that all the land in the GDAs would need to be covered with solar generation equipment. Further, the 1,300-GW output would be more than one hundred (100) times the current peak energy demand for the state.

The Task Force makes no specific recommendation for the level of solar power generation, but says about two (2) percent of the total land area of the two GDAs would allow production of about twenty-six (26) gigawatts (GW) of electrical generation capacity.

The Task Force then describes three utility-scale solar technologies currently available and operating elsewhere in the USA and the world. These technologies are grouped under the heading of Concentrating Solar Thermal Power (CTSP), frequently referred to in other reports and the media as Concentrating or Concentrated Solar Power (CSP).

The three technologies are Parabolic Trough Systems, Dish/Stirling Systems, and Solar Tower Systems. In each of these systems, large mirrors focus reflected solar radiation onto receivers that transform the intense heat into energy.

Parabolic Trough Systems focus solar radiation onto oil-filled pipes, and the heated oil is used to boil water, creating steam to drive electricity-generating turbines.



Sandia National Laboratories Researcher Rich Diver poses with a Parabolic Trough solar power concentrator, Albuquerque, NM, May 15, 2007. The parabolic mirrors focus sunlight on the oil filled pipe running above his head. The oil then flows though a heat exchanger to generate steam to power a turbine to generate electricity.

As illustrated by SES Stirling Energy Systems, Dish/Stirling Systems use large, mirrored, lens-shaped dishes to focus solar radiation on a Stirling engine mounted at the focal point of the lens. The heated fluid in the Stirling engine expands, creating pressure to drive pistons or turbines for electrical power generation.



The SES Stirling Energy Systems SunCatcher is a 25-kilowatt (kW) Solar Power System consisting of a 38-foot diameter dish structure that supports 82 curved glass mirrors. The system is also called a heliostat because it tracks the movement of the sun throughout the day. The device labeled "Power Conversion Unit (PCU)" is the Stirling engine and its housing.

Solar Tower Systems use a mirror array to concentrate and focus solar heat on a tower containing molten salt. The heated salt is used to produce steam to drive electricity-generating turbines.



Solar Tower System at Sandia National Laboratories National Solar Thermal Test Facility, Albuquerque, NM. In this 2006 view the nine-acre test facility at Sandia consists of a 200-foot-high solar tower, 212 computer-controlled mirrors called heliostats, and a separate five-story control tower. The heliostats focus sunlight on the tower to generate heat that produces steam to drive electricity-generating turbines.

Each of these three industrial-sale systems has different land-use and water-use requirements plus heat storage potential across a broad range of existing and evolving technologies. Despite many references to steam, the Task Force does not assess water use for different industrial-scale solar power systems in the July 2008 revision of its report.

In fact, Parabolic Trough and Solar Tower Systems can either consume significant quantities of water through evaporation as steam, or they can minimize water consumption using closed-loop and other dry-cooling systems. Dish/Stirling Systems operate at high temperatures, and require essentially no water other than what is needed to wash the mirrors from time to time.

The U.S. Department of Energy, Sandia National Laboratories (SNL) in 2006 published comparative water uses for coal, coal IGCC (Integrated Gasification Combined-Cycle), other fossil fuels, biomass, nuclear, geothermal steam, solar trough, solar tower, natural gas, and hydroelectric power. This report for the USA Congress is entitled “Energy Demands on Water Resources,” and the water demand tables are on pages 17 and 38.

I will devote a future post to land- and water-use requirements for specific renewable energy technologies. I will also devote a separate post to rapidly developing opportunities and technologies for storing solar and other forms of renewable energy.

In concluding the section on solar power generation potential for Colorado, the Task Force discusses solar photovoltaic systems (Solar PV), distributed solar photovoltaics (DG), and current and necessary future policy for Colorado regarding solar power development.

The Wedge Game – Solving the Climate Problem By 2055

Targets For Legislative Proposals In The USA Congress Of Mandatory Cap And Trade Programs For Greenhouse Gases Emissions, courtesy of World Resources Institute (WRI) – December 8, 2008.

The top (red) line shows historical and projected carbon emissions for the USA for 1990-2050 under conditions of "business as usual." The other lines show estimated carbon emissions reductions trends for 2010-2050 under different legislative proposals.

WRI offers a high resolution image of this graph plus details about the methodology, assumptions and references that went into creating it. WRI updates the graph each year.


A World In Transition

In the brief span of about two years – between the end of 2006 and the beginning of 2009 – our global society has greatly accelerated its transformation towards a new energy economy. Considering where we were just two short years ago, those of us in the business of climate change and economic improvement solutions should be very encouraged by this progress. In late 2006, global warming and climate change science and solutions were barely on the radar of our general public and the popular media.

As we begin 2009, concrete measures to better understand our Earth’s systems together with actions to manage climate change dominate global news, global politics, and the thinking of people at all levels of our global societies. Two years ago, I would have told people that such an expansive level of activity was a decade or more away.

By about the middle of 2007, my correspondents and audiences were demanding a story far more comprehensive than scientific accounts of global warming and its impacts. People were demanding solutions. And like people everywhere, they were demanding (and offering) straightforward solutions. And most were (and remain) convinced that somehow there would be an easy-to-understand and easily implemented single solution. How do we fix this quickly? What is the single most important thing we can do? What technology do we need? How much will it cost?

Unfortunately, there is no “silver bullet” solution to drastically eliminating the bulk of our polluting greenhouse gases (GHG) emissions in a reasonably short time. However, we can solve a major part of our emissions problems beginning now and using currently available technologies.

Often described as “silver shotgun” approaches, there are solutions scenarios that comprise several concurrent actions. These are actions that make sense physically, economically, and politically – actions that might be understandable and palatable across a broad spectrum of political, economic, cultural, spiritual and other viewpoints.

In 2004, prominent carbon management researchers Stephen Pacala and Robert Socolow of Princeton University introduced the “stabilization wedges” concept for solving our climate problem for the next 50 years using current technologies. This work continues to advance, and now is a joint project of Princeton University, BP, and Ford Motor Company. The project is called the Carbon Mitigation Initiative (CMI), and it seeks practical solutions to the greenhouse gases emissions problem.



The “stabilization wedges” concept is based upon using a suite of seven low-carbon energy technologies and enhancing natural carbon sinks. The concept name comes from the “wedge” or cut in emissions depicted on a graph of carbon emissions projected for 2005 – 2055. Each “wedge” represents a carbon-cutting strategy that can grow from zero in 2005 to one billion tons of carbon emissions by 2055.

Thus, pursuing seven “wedge” strategies would cut carbon emissions by seven billion tons, keeping global carbon emissions flat for the next 50 years. Pursuing more than seven strategies would reduce our carbon emissions below today’s levels by 2055. The CMI demonstrates that at least 15 “wedge” strategies are available now, showing there is already a more than adequate portfolio of tools available today to control carbon emissions for the next 50 years.



The CMI shows opportunities for cutting carbon emissions using current technologies in combinations of actions under these headings:

Efficiency & Conservation

Increased transport efficiency
Reducing miles traveled
Increased heating efficiency
Increased efficiency of electricity production

Fossil-Fuel-Based Strategies

Fuel switching (coal to gas)
Fossil-based electricity with carbon capture & storage (CCS)
Coal synfuels with CCS
Fossil-based hydrogen fuel with CCS

Nuclear Energy

Nuclear electricity

Renewables and Biostorage

Wind-generated electricity
Solar electricity
Wind-generated hydrogen fuel
Biofuels
Forest storage
Soil storage

The CMI provides briefs showing how GHG emissions reductions are calculated for each opportunity in this list. The briefs include commentaries on the pros and cons of each technology and how they interact with each other. The numbers in these commentaries should be useful to those wishing to understand the dimensions of combatting GHG emissions.

The CMI has produced a “Teachers Guide to the Stabilization Wedge Game.” This is a team-based exercise in which players build a portfolio of stabilization strategies and assess their impacts and costs. Those interested in explanations of our climate and carbon problem – and the relative contributions and costs of solutions using the strategies above – might want to examine this guide and its associated resources.

A significant feature of the “wedge” concept and game is that people may choose their preferred combinations of strategies from the above list, and reject strategies that might be less palatable for various political, economic or other reasons. For example, if you do not like current-technology nuclear or coal-fired electricity as a part of the suite of solutions, you can select a balancing alternative from the list of 15 opportunities. You might also consider the extra costs and benefits of substitututing compensating amounts of current-technology wind- and solar-generated electricity, for example.

Wind, Water & Sun Are Superior Energy Solutions

Vestas Horn Reef wind power facility off the coast of Denmark.

Stanford University on December 10, 2008 announces the results of the "...first quantitative, scientific evaluation of the proposed, major energy-related solutions..." and their respective impacts on "...global warming, human health, energy security, water supply, space requirements, wildlife, water pollution, reliability and sustainability."

This significant work debunks many of the myths surrounding our progress towards a new energy economy, notably the "clean coal" myth, the "nuclear power solution" myth, and the myths challenging the reliability and variability of wind, solar and wave power.

"Coal with carbon sequestration emits 60- to 110-times more carbon and air pollution than wind energy, and nuclear emits about 25-times more carbon and air pollution than wind energy..."

[Despite significant technological progress and applications of interconnected wind farms, stored solar energy, etc., that I have reported during the past two years, politicians, mass media, special interest groups, and others continue to dismiss wind and solar power potential for supplying baseline power. The potential is there, and we only must develop that potential while ignoring false claims that baseline wind, solar and wave power systems are not possible.]

See the reference links at the end of the article for supporting information and Professor Jacobson's 2007 work on interconnected wind systems for supplying baseline power. That study focused on interconnected wind system potential for an array of wind farms that have been growing for the past few years across eastern New Mexico, northern Texas, western Oklahoma, southwestern Kansas, and southeastern Colorado.

Note the priority lists of best to worst power and vehicle options near the end of the article.

Importantly, Mark Jacobson's work represents a high level of integrity inasmuch as the research "...received no funding from any interest group, company or government agency."


Stanford University News Service

Energy & Environmental Science

Stanford Report, December 10, 2008

Wind, water and sun beat other energy alternatives, study finds

BY LOUIS BERGERON

The best ways to improve energy security, mitigate global warming and reduce the number of deaths caused by air pollution are blowing in the wind and rippling in the water, not growing on prairies or glowing inside nuclear power plants, says Mark Z. Jacobson, a professor of civil and environmental engineering at Stanford.

And "clean coal," which involves capturing carbon emissions and sequestering them in the earth, is not clean at all, he asserts.

Jacobson has conducted the first quantitative, scientific evaluation of the proposed, major, energy-related solutions by assessing not only their potential for delivering energy for electricity and vehicles, but also their impacts on global warming, human health, energy security, water supply, space requirements, wildlife, water pollution, reliability and sustainability. His findings indicate that the options that are getting the most attention are between 25 to 1,000 times more polluting than the best available options. The paper with his findings will be published in the next issue of Energy and Environmental Science but is available online now. Jacobson is also director of the Atmosphere/Energy Program at Stanford.

"The energy alternatives that are good are not the ones that people have been talking about the most. And some options that have been proposed are just downright awful," Jacobson said. "Ethanol-based biofuels will actually cause more harm to human health, wildlife, water supply and land use than current fossil fuels." He added that ethanol may also emit more global-warming pollutants than fossil fuels, according to the latest scientific studies.

The raw energy sources that Jacobson found to be the most promising are, in order, wind, concentrated solar (the use of mirrors to heat a fluid), geothermal, tidal, solar photovoltaics (rooftop solar panels), wave and hydroelectric. He recommends against nuclear, coal with carbon capture and sequestration, corn ethanol and cellulosic ethanol, which is made of prairie grass. In fact, he found cellulosic ethanol was worse than corn ethanol because it results in more air pollution, requires more land to produce and causes more damage to wildlife.

To place the various alternatives on an equal footing, Jacobson first made his comparisons among the energy sources by calculating the impacts as if each alternative alone were used to power all the vehicles in the United States, assuming only "new-technology" vehicles were being used. Such vehicles include battery electric vehicles (BEVs), hydrogen fuel cell vehicles (HFCVs), and "flex-fuel" vehicles that could run on a high blend of ethanol called E85.

Wind was by far the most promising, Jacobson said, owing to a better-than 99 percent reduction in carbon and air pollution emissions; the consumption of less than 3 square kilometers of land for the turbine footprints to run the entire U.S. vehicle fleet (given the fleet is composed of battery-electric vehicles); the saving of about 15,000 lives per year from premature air-pollution-related deaths from vehicle exhaust in the United States; and virtually no water consumption. By contrast, corn and cellulosic ethanol will continue to cause more than 15,000 air pollution-related deaths in the country per year, Jacobson asserted.

Because the wind turbines would require a modest amount of spacing between them to allow room for the blades to spin, wind farms would occupy about 0.5 percent of all U.S. land, but this amount is more than 30 times less than that required for growing corn or grasses for ethanol. Land between turbines on wind farms would be simultaneously available as farmland or pasture or could be left as open space.

Indeed, a battery-powered U.S. vehicle fleet could be charged by 73,000 to 144,000 5-megawatt wind turbines, fewer than the 300,000 airplanes the U.S. produced during World War II and far easier to build. Additional turbines could provide electricity for other energy needs.

"There is a lot of talk among politicians that we need a massive jobs program to pull the economy out of the current recession," Jacobson said. "Well, putting people to work building wind turbines, solar plants, geothermal plants, electric vehicles and transmission lines would not only create jobs but would also reduce costs due to health care, crop damage and climate damage from current vehicle and electric power pollution, as well as provide the world with a truly unlimited supply of clean power."

Jacobson said that while some people are under the impression that wind and wave power are too variable to provide steady amounts of electricity, his research group has already shown in previous research that by properly coordinating the energy output from wind farms in different locations, the potential problem with variability can be overcome and a steady supply of baseline power delivered to users.

Jacobson's research is particularly timely in light of the growing push to develop biofuels, which he calculated to be the worst of the available alternatives. In their effort to obtain a federal bailout, the Big Three Detroit automakers are increasingly touting their efforts and programs in the biofuels realm, and federal research dollars have been supporting a growing number of biofuel-research efforts.

"That is exactly the wrong place to be spending our money. Biofuels are the most damaging choice we could make in our efforts to move away from using fossil fuels," Jacobson said. "We should be spending to promote energy technologies that cause significant reductions in carbon emissions and air-pollution mortality, not technologies that have either marginal benefits or no benefits at all".

"Obviously, wind alone isn't the solution," Jacobson said. "It's got to be a package deal, with energy also being produced by other sources such as solar, tidal, wave and geothermal power."

During the recent presidential campaign, nuclear power and clean coal were often touted as energy solutions that should be pursued, but nuclear power and coal with carbon capture and sequestration were Jacobson's lowest-ranked choices after biofuels. "Coal with carbon sequestration emits 60- to 110-times more carbon and air pollution than wind energy, and nuclear emits about 25-times more carbon and air pollution than wind energy," Jacobson said.

Although carbon-capture equipment reduces 85-90 percent of the carbon exhaust from a coal-fired power plant, it has no impact on the carbon resulting from the mining or transport of the coal or on the exhaust of other air pollutants. In fact, because carbon capture requires a roughly 25-percent increase in energy from the coal plant, about 25 percent more coal is needed, increasing mountaintop removal and increasing non-carbon air pollution from power plants, he said.

Nuclear power poses other risks. Jacobson said it is likely that if the United States were to move more heavily into nuclear power, then other nations would demand to be able to use that option.

"Once you have a nuclear energy facility, it's straightforward to start refining uranium in that facility, which is what Iran is doing and Venezuela is planning to do," Jacobson said. "The potential for terrorists to obtain a nuclear weapon or for states to develop nuclear weapons that could be used in limited regional wars will certainly increase with an increase in the number of nuclear energy facilities worldwide." Jacobson calculated that if one small nuclear bomb exploded, the carbon emissions from the burning of a large city would be modest, but the death rate for one such event would be twice as large as the current vehicle air pollution death rate summed over 30 years.

Finally, both coal and nuclear energy plants take much longer to plan, permit and construct than do most of the other new energy sources that Jacobson's study recommends. The result would be even more emissions from existing nuclear and coal power sources as people continue to use comparatively "dirty" electricity while waiting for the new energy sources to come online, Jacobson said.

Jacobson received no funding from any interest group, company or government agency.


Energy and vehicle options, from best to worst, according to Jacobson's calculations:

Best to worst electric power sources:

1. Wind power
2. Concentrated solar power (CSP)
3. Geothermal power
4. Tidal power
5. Solar photovoltaics (PV)
6. Wave power
7. Hydroelectric power
8. A tie between nuclear power and coal with carbon capture and sequestration (CCS).

Best to worst vehicle options:

1. Wind-BEVs (battery electric vehicles)
2. Wind-HFCVs (hydrogen fuel cell vehicles)
3. CSP-BEVs
4. Geothermal-BEVs
5. Tidal-BEVs
6. Solar PV-BEVs
7. Wave-BEVs
8. Hydroelectric-BEVs
9. A tie between nuclear-BEVs and coal-CCS-BEVs
11. Corn-E85
12. Cellulosic-E85.

Hydrogen fuel cell vehicles were examined only when powered by wind energy, but they could be combined with other electric power sources. Although HFCVs require about three times more energy than do BEVs (BEVs are very efficient), HFCVs are still very clean and more efficient than pure gasoline, and wind-HFCVs still resulted in the second-highest overall ranking. HFCVs have an advantage in that they can be refueled faster than can BEVs (although BEV charging is getting faster). Thus, HFCVs may be useful for long trips (more than 250 miles) while BEVs more useful for trips less than 250 miles. An ideal combination may be a BEV-HFCV hybrid.


Related Information

Professor Mark Jacobson discusses alternative energy sources

Jacobson's paper in Energy & Environmental Science

Jacobson's Stanford web page

Stanford December 2007 press release on interconnecting wind farms to smooth power delivery

Jacobson's interconnecting windfarms paper in J. Applied Meteorology and Climatology

Clean Energy Self Reliance Using Homegrown Renewable Power In Each USA State

Greetings, All -- The information below was originally reported on November 11, 2008.

I call to your attention a new report by The New Rules Project that estimates the potential of individual states in the USA to tap into their own and nearby renewable energy resources. The relatively brief, 14-page report is well illustrated with maps and data to help change our way of thinking about renewable energy supplies and options.

For example, in our American Southwest, the New Rules reports says New Mexico has the potential to generate 2700 (twenty-seven hundred) percent of its electricity demands using wind power, and/or 37 (thirty-seven) percent of its electricity demands using rooftop solar photovoltaic power.

One also might consider that the immediate reaction to a solar power potential map for the USA is to believe that solar power must come from the American Southwest from a band extending from southern California eastward to west Texas. However, a more thoughtful reaction to the same map is that there is significant solar power potential in every state of the USA, and the solar resource can be more economically developed locally when long distance transmission costs (and power losses) are considered.

The report has its flaws. For example, The wind data are based on a 1991 study and on 30 m heights, and there is much research done since that provides more accurate data. The report data are based on average wind speeds whereas it is important to take into account fluctuations because loads do not vary linearly with speed. Also, the references used are not scientific peer-reviewed literature but mainly internet resources and blogs.

For an up-to-date report on wind power for the USA, see the 2007 edition of the Lawrence Berkeley National Laboratory Annual Report on U.S. Wind Power Installation, Cost, and Performance Trends

Nonetheless, we should be more concerned with the concept of locally generated energy as an alternative or complement to central station power generation with long-distance transmission. The precise scientific numbers and estimates re wind, solar, and other resources in the New Rules report are perhaps less relevant than creating an immediate national review and debate on retooling our energy infrastructure for our new energy economy.

What is happening, unfortunately, is that many political and technical advisors on our energy future have already adopted a model based on old-line thinking that applies to an obsolescent national power generation and transmission infrastructure -- without considering the merits of Distributed Generation. [There will be more on this page about Distributed Generation, Micro-Grid Technology, etc. in other posts.]

Consider this statement published November 14, 2008: "Another point that all [renewable energy] associations agreed was of utmost importance to bring the U.S. out of its economic woes was major investment in interstate electrical grid infrastructure, including new transmission and smart grid technologies. Many of the best renewable energy resources are located in remote areas that do not have ready grid-access. New transmission corridors will be necessary to bring wind, water, solar, and geothermal energy that is harvested in remote areas to areas of the country in which people reside."
See: http://www.renewableenergyworld.com/rea/news/story?id=54078&src=rss

Most of the best renewable energy resources in our nation are co-located with old technology power stations already connected to the national grid. [As one obvious example, the same 40,000 square miles of New Mexico already given over to oil and natural gas production in the San Juan and Permian Basins -- clearly connected to our national transmission grid -- could provide our entire nation's electrical demands via solar power for the remainder of this century.]

Additionally, many of the best renewable energy resources -- especially solar -- are colocated with major metropolitan areas in our nation where multi-millions of people reside [Los Angeles, San Diego, Phoenix, Las Vegas, Tuscon, Albuquerque, Denver, El Paso, Austin, San Antonio, Salt Lake City, etc., etc.]. Thus, there is no immediate need to pursue the hugely wasteful process of building remotely located power plants and thousands of miles of new transmission lines with their inherent power losses with distance.

Nonetheless, political planning and the groundwork for economic resource allocation are already well in progress toward the obsolescent and uneconomical idea that we must necessarily think of our future energy infrastructure as we remember it from our past.

The new report is available for download at: http://www.newrules.org/de/energyselfreliantstates.pdf The Executive Summary follows.


Energy Self-Reliant States: Homegrown Renewable Power

Executive Summary

How much energy could be generated by states tapping into internal renewable resources? To date, no study has addressed this question comprehensively. This report is a first attempt to do so.

The data in this report, while preliminary, suggest that at least half of the fifty states could meet all their internal energy needs from renewable energy generated inside their borders, and the vast majority could meet a significant percentage. And these estimates may well be conservative.

A national renewable energy policy should reflect the unique distribution of these energy sources. Wind and solar and, to a lesser extent, biomass, can be found in abundance in virtually all parts of the country. A federal policy that focuses on harnessing local renewable resources for local markets could dramatically expand the number of communities and states economically benefiting from the use of renewable fuels while minimizing the transportation-related environmental impact of moving energy products long distances.

Yet current federal energy policy is largely focused on harnessing renewable energy in a few states and transporting it hundreds or even thousands of miles to customers in other states.

The rationale for this reliance on long distribution lines is that while renewable energy is widely distributed, the resources and cost of harnessing them vary widely state-by- state.

That is true. Agricultural states in the heartland can grow biomass in larger quantities and at a lower cost than states on the coasts. A state like Nevada has significantly more annual solar energy than Oregon. North Dakota’s high wind speeds translate into lower production costs.

However, while significant variations in renewable energy among states exist; in most cases, when transmission or transportation costs are taken into account, the net cost variations are quite modest. Homegrown energy is almost always cheaper than imports, especially when you factor in social, environmental and economic benefits.

Policies that encourage energy self-reliance at a state and even in many cases a local level could enable communities and regions to achieve economic and environmental goals simultaneously. It’s a win-win situation.

US Renewable Energy

Hello, All -- The latest monthly report from the U.S. Energy Information Administration (EIA) of the U.S. Department of Energy shows that domestically produced renewable energy is now only slightly less than the total of domestically produced nuclear energy from the 103 nuclear power plants now operating in the USA.

Renewable energy now accounts for slightly less than 11 (eleven) percent of total domestically produced energy in the USA, and slightly more than 7 (seven) percent of total USA energy consumption from domestic plus imported energy.

I added three links to EIA information in and below the article for your research and reading pleasure.

Happy Holidays!


http://www.renewableenergyworld.com/rea/news/infocus/story?id=54199

Renewable Energy World/U.S. Energy Information Administration

December 1, 2008

US Renewable Energy Demand Increases 7.4%

Washington, D.C., United States [RenewableEnergyWorld.com]

According to the latest "Monthly Energy Review" issued by the U.S. Energy Information Administration on November 24, 2008, renewable energy accounted for almost 11 percent of the domestically-produced energy used in the United States in the first eight months of 2008.
See: http://www.eia.doe.gov/emeu/mer/contents.html
For the period January 1 – August 31, 2008, the United States consumed 67.550 quadrillion Btus (quads) of energy - of which 45.428 quads was from domestic sources and 22.122 quads was imported. Domestically-produced renewable energy (biomass/biofuels, geothermal, hydropower, solar, wind) totaled 4.886 quads, an amount equal to 10.76% of U.S. energy consumption that is domestically-produced.__

This share is only slightly less than the contribution from nuclear power (12.39%). And while consumption of nuclear power dropped slightly during the first eight months of 2008, compared to the same period for 2007 (5.629 quads, down from 5.637 quads), domestic renewable energy production's share increased by more than seven percent (4.886 quads, up from 4.549 quads). __

Biomass and biofuels combined presently constitute the largest source of renewable energy in the United States (2.554 quads) followed by hydropower (1.916 quads).

Wind power, however, experienced the largest growth rate, increasing by almost 45% compared to the first eight months of 2007 (0.300 quads, up from 0.207 quads).

Solar’s and geothermal’s contributions were at roughly the same levels in 2008 as they were in 2007 – although both are poised to greatly expand their market share in the near future.

Additional References:

Energy Information Administration – Official Energy Statistics From the U.S. Government: http://www.eia.doe.gov/

EIA Renewable & Alternative Fuels: http://www.eia.doe.gov/fuelrenewable.html