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Crop Residues
www.CropResidues.com

What are Crop Residues?

Crop residues, also referred to as "agricultural waste," non-photosynthetic vegetation or "farm residue," and are comprised of stalks, cobs, and other plant parts left behind after harvesting the crop/crops on the farm they were grown at.

Why are Crop Residues important?

According to the U.S. Department of Agriculture, crop residues are important because:

When left on the soil's surface, crop residues;

–  Protect the soil from wind and water erosion.
–  Reduce evaporation by acting as a mulch.
–  Their breakdown helps sequester carbon emissions into the soil.
-  This also recycles nutrients.
–  Improve the soil's structure and its water retention capabilities.

When removed from the soil, crop residues:

–  Do not benefit the soil, but can be used for cellulosic ethanol biofuels as well as an excellent biomass feedstock for generating "carbon free energy" through the production of Synthesis Gas from a Biomass Gasification plant.

Biomass supply from crop residues can increase a producer's profits while maintaining the farm's soil quality as long as the farm's reduced tillage and partial residue harvest are used appropriately. 

The Corn Belt, Great Plains, and West Coast's use of crop residues as a biomass feedstock is possible with judicious selection of crops and crop management practices. 

Crop residues are probably the lowest cost form of biomass supply, but the range of costs is wider in the Great Plains than in the Corn Belt. The remaining regions, including the West Coast, the Delta, and the Southeast, also have pockets with crop residue supplies and a wide variation in costs.

Crop residues have the potential to displace 12.5 percent of petroleum imports or 5 percent of electricity consumption in today’s markets. Crop residues also have growth potential from improving crop productivity and declining livestock demands for forage. When crop residues (as a biomass feedstock) are included with some other agricultural sources, biomass supply from crop agriculture could account for more than 100% of the fuel requirements for our country's electricity requirements hrough the production of Synthesis Gas from a Biomass Gasification plant.  

What is "waste to clean energy"?

Waste to Clean Energy, better known as Waste to Energy, are operations and facilities that produce clean, renewable energy through the combustion of municipal solid waste in specially designed power plants equipped with the most modern pollution control equipment to clean emissions. Trash volume is reduced by 90% and the remaining residue is regularly tested and consistently meets strict EPA standards allowing reuse or disposal in landfills. There are 89 waste-to-energy plants operating in 27 states managing about 13 percent of America's trash, or about 95,000 tons each day. Waste to Energy facilities generate about 2,500 megawatts of electricity to meet the power needs of nearly 2.3 million homes, and the facilities serve the trash disposal needs of more than 36 million people. The $10 billion Waste to Energy industry already employs more than 7,000 American workers with annual wages in excess of $400 million.

How do waste to clean energy and waste to energy plants reduce Greenhouse Gas Emissions emitted into the atmosphere?

The use of Waste to Energy technology prevents the release of forty million metric tons of greenhouse gas emissions in the form of carbon dioxide equivalents that otherwise would be released into the atmosphere on an annual basis, according to an analysis developed by the U.S. Environmental Protection Agency and the Integrated Waste Services Association (IWSA) using EPA's Decision Support Tool program. Annual reporting by IWSA to the U.S. Department of Energy's Voluntary Reporting of Greenhouse Gases Program confirms that Waste to Energy also prevents the release each year of nearly 24,000 tons of nitrogen oxides and 2.6 million tons of volatile organic compounds (VOCs) from entering the atmosphere.

America's Waste to Energy facilities dispose of trash, and are an alternative to land disposal that releases methane (a potent greenhouse gas) as trash decomposes. Waste to Energy also produces electricity, lessening reliance on fossil fuel power plants that release carbon dioxide emissions, one of the six and most potent of all greenhouse gas emissions, into the atmosphere when coal or oil are burned. Operation of waste-to-energy plants avoid the release of methane that otherwise would be emitted when trash decomposes, and the release of CO2 that would be emitted from generating electricity from fossil fuels.

In addition to the analysis using EPA's Decision Support Tool, and eight years of reporting by the IWSA to the U.S. Department of Energy, a detailed, project analysis of a facility's contribution to solving the threat of global warming has been completed for a 1500-ton-per-day Waste to Energy facility in the northeast. Researchers used information regarding alternative landfill disposal, plant emissions, trash composition and other plant-specific data and analyzed the information using the EPA Decision Support Tool. The study determined that about 270,000 tons of carbon dioxide equivalent emissions are avoided annually because of this one plant's operations. Company officials currently are talking to greenhouse gas credit brokers about marketing the reductions to buyers of GHG credits.

How Waste to Energy Plants Avoid Greenhouse Gas Emissions and Avoidance Calculations

Assumptions

@ 33 million tons / year⁴ (Amount of municipal solid waste managed by waste-to-energy used to calculate the estimate, above, of 11 million MCTE)

MSW = Municipal Solid Waste

@ 550 kWh / ton MSW⁵

THEREFORE, 1 megawatt hour generated by waste-to-energy technology equals 2 metric tons of CO₂ equivalent or 2.2 standard tons of CO₂ equivalent.

¹The Impact of Municipal Solid Waste Management on Greenhouse Gas Emissions In the United States, by K.A. Weitz, Research Triangle Institute, S.A. Thorneloe, U.S. Environmental Protection Agency, and M. Zannes, IWSA, 2001 discusses the overall contribution, including Waste to Energy's part, in reduction of greenhouse gas emissions from proper solid waste management practices. The analysis concludes that emissions of 11 million metric tons carbon dioxide emissions were avoided on an annual basis by the use of Waste to Energy technologies.

²The conversion of carbon equivalent to CO₂ equivalent is based on the ration of the molecular weight of carbon to the molecular weight of CO₂, or a factor of 3.67.

³1 metric ton = 1.1 standard or short ton

⁴The Impact of Municipal Solid Waste Management on Greenhouse Gas Emissions In the United States, Ibid. The analysis calculated that 11 million metric tons of carbon dioxide emissions were avoided by the disposal and electricity generation from 33 million tons of trash managed by Waste to Energy in one year. The Integrated Waste Services Association reported that 33 million tons of trash was managed in 2002 by Waste to Energy technology in the United States.

⁵The average energy conversion rate of Waste to Energy plants is estimated by facility operators and vendors associated with the Integrated Waste Services Association (IWSA), the national trade group for the Waste to Energy industry.

Anaerobic Digesters, Flare Gas Recovery, Landfill Gas to Energy, Vapor Recovery, Waste to Fuel and other Methane Recovery technologies generate "free" (after cost of system) Biomethane and Synthesis Gas fuels that can be used to fuel our client's onsite cogeneration and trigeneration plants.  

Our Waste to Energy and Waste to Fuel systems significantly reduces your facility's emissions (such as NOx , SOx, H2S, CO , CO2 and other Hazardous Air Pollutants/Greenhouse Gas Emissions) and convert these valuable emissions from an environmental problem into a new cash revenue stream and profit center.

Waste To Clean Energy
www.WasteToCleanEnergy.com

Waste to Energy Project Development

Sewage Sludge
www.SewageSludge.com

We Turn Your City or County's Sewage Sludge Problems  
into Profits and Green Energy!

Renewable Energy Ventures provides solutions for your Sewage Sludge problems and other organic waste streams with one or more of the following: Anaerobic Digester, Anaerobic Lagoon, Biogas Recovery, BioMethane, Biomass Gasification, Biosolids to Energy, Landfill Gas To Energy and Sewage Sludge "problems into profits"  project development services.

Renewable Energy Ventures provides the following power and energy project development services:

• Project Engineering Feasibility & Economic Analysis Studies  

• Engineering, Procurement and Construction

• Environmental Engineering & Permitting 

• Project Funding & Financing Options; including Equity Investment, Debt Financing, Lease and Municipal Lease

• Shared/Guaranteed Savings Program with No Capital Investment from Qualified Clients 

• Project Commissioning 

• 3rd Party Ownership and Project Development

• Long-term Service Agreements

• Operations & Maintenance 

• Green Tag (Renewable Energy Credit, Carbon Dioxide Credits, Emission Reduction Credits) Brokerage Services; Application and Permitting.

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According to the United Nations: "It is estimated that Greenhouse Gas Emissions  trading markets could be worth $2 Trillion by 2012."

http://www.unep.org/Documents.Multilingual/Default.asp?DocumentID=433&ArticleID=4792&l=en

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Biomethane and Synthesis Gas; the Perfect Renewable Fuels!

As Biomethane is a near perfect fuel, and since Biomethane represents the best of all biofuels in terms of Recycling Carbon, and has the highest Net Energy Balance, and as Biomethane technologies such as Anaerobic Digesters and Biomass Gasification development increases and becomes even more commonplace, one of the fundamental questions is: what is the size of the potential biomass resource supply in the U.S.?

In April 2005, the DOE and the U.S. Department of Agriculture (USDA) co-published a report assessing the potential of the land resources in the U.S. for producing sustainable biomass: Biomass as Feedstock for a Bioenergy and Bioproducts Industry: The Technical Feasibility of a Billion-Ton Annual Supply. Looking at forestland and agricultural land, the two largest potential biomass sources, this study estimates that the U.S. can sustainably produce up to 1.3 billion tons of biomass feedstock by mid-century. This would be enough feedstock to produce 60 billion gallons of B100 Biodiesel and E100 Ethanol with today's technologies.

This study doesn't address the opportunities for Biomethane production from biomass feedstock or Biomass Gasification technologies. Some recent estimates indicate that Biomethane could replace up to 50% of present natural gas consumption in the U.S. and in some countries, such as Iceland, Biomethane already provides 100% of the natural gas requirements.

There are many assumptions in the Billion Ton Study report that impact these estimates, but we believe the estimates reasonably reflect the potential availability and impact of biomass resources.

Of the total estimated resource, the study suggests that forestlands in the contiguous United States can produce approximately 368 million dry tons annually. This projection includes 52 million dry tons of fuelwood harvested from forests and woodlands, 145 million dry tons of residues from wood processing mills and pulp and paper mills, 47 million dry tons of urban wood residues including construction and demolition debris, 64 million dry tons of residues from logging and site clearing operations, and 60 million dry tons of biomass from fuel treatment operations.

Biomass to Biofuels

By "converting" biomass wastes – such as municipal solid waste, sewage sludge, crop residues, energy crops, and manure – into biofuels, this will resolve the energy, environmental and political problems in an economical and environmentally sound manner - that will produce over one million new jobs.

According to Jeff Seisler, Director of the European Natural Gas Vehicle Association, "Biomethane has an outstanding potential as a multifaceted solution to multifaceted social problems: urban and agricultural waste management, water purification, and clean air. Urban and agricultural waste can be processed into usable methane, as can the sewage during the water purification process. Cleaning and compressing the gas for use in vehicles then provides cleaner air than petroleum-consuming vehicles."

Continuing, Mr. Seisler states about Biomethane; "this environmental 'closed loop waste-to-energy-to-fuel used in vehicles that again truck the next load of waste to the energy processing plants-substitutes fossil fuels with a renewable resource and reduces greenhouse gases 100% as compared to over gasoline vehicles (on a well-to-wheel basis).

According to Peter Boisen Chairman, of ENGVA, "various well respected European research institutes now estimate more than three times better fuel output per hectare of land used than if going for ethanol or biodiesel. Sweden currently has a 51% Biomethane share, and Switzerland 37%. France, Norway, Germany and Austria use smaller amounts for vehicles. Iceland, completely without natural gas, uses 100% biomethane in its NGVs," Boisen says.  Continuing, Boisen adds, "China, India, Korea, the Ukraine, Spain and Italy are other examples of countries now starting up projects where Biomethane will be used as a vehicle fuel." 

"With the energy efficiency of the gas production process at 50% to 70% it's hard to think of a more socially acceptable and economic energy value for the transportation sector," Boisen says.

"Governments need to get out of their liquid fuel paradigm to refocus and balance their policies and communications to support the development of a Biomethane infrastructure. In Europe Biomethane has the potential to replace 20% of the petroleum consumed in the transport sector by 2030."

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BIOMETHANE NEEDED NOW

FOR OUR CLIENTS IN: 

TEXAS, NEW YORK, PENNSYLVANIA, 
MASSACHUSETTS & CALIFORNIA

CLIENTS NEED TO PLACE BIOMETHANE UNDER CONTRACT
AS SOON AS POSSIBLE & WILLING TO SIGN LONG TERM CONTRACTS.

BIOMETHANE can be produced anywhere in the Continental U.S., 
we can take care of transportation to our clients.  

Send email with details regarding Biomethane supply and 
Biomethane Producer's contact information to: 

info@Biomethane.com

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What is Biomethane?

Biomethane is "renewable natural gas" made from organic sources - which starts out as "biogas" but then is cleaned up in a process called "Biogas to Biomethane" which removes the impurities in biogas such as carbon dioxide, siloxanes and hydrogen sulfides (H2S).

Biomethane is soon to be re-classified from the category of "Low Carbon Fuels" to "Super Low Carbon Fuel" due to it being the greenest of all biofuels!

"Cleaned-up" and ready for use in an onsite cogeneration or trigeneration power plant, the Biomethane could also be sold to a pipeline company and completely replace the "natural gas" that is typically transported to markets via the vast underground pipeline system.

Biomethane will some day replace the "methane" that is sold by natural gas utility companies.

Biomethane has an unlimited supply, whereas the methane sold by gas companies has a limited supply.  Biomethane is renewable, whereas the methane sold by your gas utility company is not renewable. Biomethane recovery, use and production generates "Greentags" or a "Renewable Energy Credit" for the owners and is GOOD for our environment.

As previously mentioned, Biomethane is "naturally" produced from organic materials as they decay.  Sources of Biomethane include; landfills, POTW's/Wastewaster Treatment Systems, and every tree or agricultural product that is no longer living.  Biomethane is also generated from animal operations where manure can be collected and the Biomethane is generated from anaerobic digesters where the manure decomposes.

Biomethane, after installation of the Biomethane equipment is essentially free, as opposed to buying natural gas, presently costing around $10.00/mmbtu. 

Methanogenesis is the production of CH4 and CO2 by biological processes that are carried out by methanogens.

Unlike the price of natural gas, which has been very unstable, and wildly fluctuating from $5.50 to as much as $17.00/mmbtu this past year, Biomethane prices will tend to be more stable over the years. As more and more Biomethane is produced, and produced in reliable and sustainable methods that can fuel our energy needs now and for.

Why Switch to Compressed Natural Gas?

• 90% cleaner emissions than the average gasoline or diesel-fueled vehicle. Yes, diesel truck engines can be replaced with "clean combustion" natural gas engines!

• Tailpipe emissions from Natural Gas Vehicles often cleaner than the ambient air!

• 25% less Greenhouse Gas Emissions compare to Gasoline, even more compared with diesel!

• 50% less Nitrogen Oxides compared to Gasoline - even more when compared to diesel!

• Compressed Natural Gas vehicles Cost FAR LESS than Gasoline or Diesel-fueled vehicles!  Natural Gas Vehicles save about 40% over the Cost of Gasoline-fueled vehicles and as much as 50% over the Cost of Diesel-fueled vehicles!

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We provide biomethane project development services that may include renewable energy capital and project finance for quality companies, with quality products or services, that have a quality management team.

Our Investment Criteria Includes the Following:

Capital for funding the growth of existing businesses, including:

• management–led buyouts

• acquisition financings

• minority recapitalizations.

What We Look For:

1.  Superior Management Teams: 

The present management team must have a proven record of achievement, exceptional ability, unyielding determination, and unquestionable integrity.

We believe it is best to leave control with current the present owners and/or management team so that they can focus on their products/services, customers, employees and shareholders well for the long term.

2.  Investment Size: $5 million to $25 million of equity capital. 

We may partner with other investors or venture capital firms larger transactions.

3.  EBITDA: Near–profitable to $10 million.

4.  Growth: Historical growth of at least 20% per year which is sustainable into the future.

5.  Market Size: Growing rapidly or large enough to allow company to achieve $100 million in revenues.

6.  Industry: Renewable energy projects with preference for Biofuels (Biomethane or B100 Biodiesel) and solar projects

7.  Location: U.S. and Canada

We seek to make investments for at least 6 to 7 years and provide "patient capital" for sustained growth and to assist our portfolio companies in succeeding. 

The companies (investment banks, investors and venture capital) we have relationships with initial equity investment size presently ranges from $5 million to $25 million.

PLEASE NOTE:  We will NOT consider any investment in any of the following: 

• startups

• publicly traded companies 

• real estate developments of any kind 

• project finance or funding opportunities 

• oil and gas exploration companies (oil and gas production companies acceptable)

• troubled companies 

• turnarounds

• any company where senior management is departing.

If you have a business and financing need that meet the criteria above, we would be pleased for you to contact us regarding your financing need. Please send a complete executive summary to us at: info@Biomethane.com

The following information on this site represents some of our past/present interests in the renewable energy sector.

Biomethane
www.Biomethane.com

We develop renewable energy projects, and specialize in solar power and energy project development. Our company provides the total, turnkey solar energy system "in-house" as well as with affiliates and strategic partners.  This means our capabilities and core competencies include solar project:

• project identification

• project analysis

• design/engineering

• finance (through investors and joint venture partners)

• installation or construction

• ownership (with PPA)

• operations

• maintenance and service or our solar energy systems

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When It Comes to Energy Independence,
Biomethane, Not Coal, is America's "Ace in the Hole"
and One of the Greenest of All Biofuels

It's Time to Start Building Our Country's Biomethane Infrastructure &
Producing Biomethane, the Cleanest/Greenest Biofuel!

By:  Monty Goodell, MBA
Biomethane Technologies
www.Biomethane.com

Biomethane, NOT Coal, is America's True "Ace in the Hole" when it comes to our energy future, economics, the environment, sustainability and America's “Energy Independence.” And biomethane is also receiving recognition as one of the greenest of all biofuels.   

For years now, the coal industry has been touting "coal is America's 'Ace in the Hole'" when they discuss the abundance of our coal reserves here in the U.S. and the role they hope coal will play in America's energy future.

But coal is far from being the “Ace in the Hole” the coal lobby would have everyone believe.  That’s due to the proverbial “black eye” not to mention the “black lungs” and other problems that are inherent with “dirty coal.”  

While there may be a place for coal in America's energy future, coal must become "clean" for America to value it as a possible energy resource. Plans or building 18 new Coal fired power plants were cancelled in Texas last year due to the fact that coal isn't clean, and utilities aren't interested in investing the extra costs for building power plants that use "Clean Coal Technology" or "Integrated Gasification Combined Cycle" power plants that also now need to include "Carbon Capture and Sequestration" technologies to remove the carbon dioxide emissions from the stacks. Plans for many other coal fired power plants are being cancelled. And even now, owners of coal fired power plants (pulverized coal) are switching from coal, to biomass, and biomass gasification technologies, as the writing is on the wall.

Unless our society relishes the thoughts of moving back to the caves, and using candles, and foregoing our modern-day comforts, we need to move forward with renewable energy technologies such as biomethane, as the alternative is power shortages and blackouts.

We believe biomethane represents the best and greenest of all biofuels. There are no supply problems with biomethane, and we have a virtually unlimited supply for using biomethane wherever natural gas is presently used as a fuel.

It should be pointed out that biomethane is chemically no different than natural gas from the "fossil fuel" form of natural gas or CH4.

However, one important distinction between biomethane and the fossil-fuel variety of natural gas, is that the production and use of biomethane is “carbon neutral” in that the greenhouse gas emissions from biomethane use do not add any new net greenhouse gas emissions.

Biomethane starts out as “biogas” but must be cleaned and purified before it can be used as a renewable fuel.  The process of cleaning and purifying the biogas is called “biogas to biomethane.”  The impurities that are found in biogas include hydrogen sulfides, siloxanes, and carbon dioxide. When the impurities are removed from biogas, it is then referred to as biomethane and available for use as a clean fuel, just as the fossil-fuel form of natural gas is used. 

Biomethane reserves and supplies, unlike fossil-fuel natural gas, are virtually unlimited. Biomethane is produced from many sources including anaerobic digesters, wastewater treatment systems, landfills and most agricultural and forestry operations. Last year, the first Biomethane NGV refueling station was opened in Eugendorf, Austria.  Like a gas station provides gasoline for cars, the the NGV Biomethane station in Eugendorf provides biomethane for NGVs (Natural Gas Vehicles).  Presently, the station provides a blend of biomethane and natural gas.  Eventually, they hope to provide 100% biomethane for natural gas vehicles.  Companies and researchers in Germany and Austria have determined that “Cellulosic Biomethane” is the greenest of all biofuels, and the least expensive biofuel to produce.  Germany and Austria are now planting vast amounts of a form of Kentucky Bluegrass which will be harvested for use in producing “Cellulosic Biomethane,” through anaerobic digesters and fermentation.

Researchers from around the world, starting in Austria, are finding that grasses such as Kentucky Bluegrass are easily converted into biomethane as well as organic fertilizer. Cellulosic Biomethane production doesn’t require the fermentation of sugars or starches - as the first generation of liquid biofuels – requiring grains and oilseeds from food crops. As the Austrian Cellulosic Biomethane project shows, biomethane can be produced from a cellulosic biomass feedstock like grass. Yield estimates from the Austrian Cellulosic Biomethane research indicate that one natural gas vehicle can travel 10,000 to 15,000 miles on just one acre of Kentucky Bluegrass that was processed into biomethane.

At a Jan. 8, 2009 public workshop held by the California Natural Gas Vehicle Coalition, they documented the superior benefits and potential of biomethane as a clean, renewable energy resource.  The California Natural Gas Vehicle Coalition stated that Biomethane should be classified as a "Super Ultra Low Carbon fuel."  Super Ultra Low Carbon fuel is defined as providing at least an 82 percent reduction in greenhouse gas emissions - based on the California Air Resource Board’s analysis of biomethane from landfill gas.

Biomethane has a carbon dioxide emissions intensity of only 11 as compared with:

                                                                        67.9 for natural gas
                                                                        95.8 for diesel
                                                                        96.7 for gasoline

Biomethane can displace and substitute the equivalent of 29% percent of all petroleum diesel transportation fuel used - almost immediately.

According to the California Energy Commission and the Biomass Collaborative, landfills, wastewater treatment, and dairy waste sources - which are "developable today" and can start producing Biomethane almost immediately, with low investment/high returns, could yield 121 billion cubic feet of Biomethane. At $8.00/mmbtu, that's a $1 billion market opportunity in California alone.  The 121 billion cubic feet of Biomethane equals about 860 million gallons of petroleum diesel. California alone uses about 3 billion gallons of diesel annually for transportation. Emerging biomass gasification and Biomethanation technologies could more than double Biomethane supplies.

Biomethane - like natural gas from "fossil fuels" - can be compressed or liquefied. And using "Compressed Biomethane" is a significantly better choice as a transportation fuel than traditional "natural gas."

Biomethane is the "natural, natural gas" and is far better for the environment and the economy than natural gas. Biomethane, when "vented" to the environment, is 21 times more hazardous to the climate than carbon dioxide emissions which are the only emissions (and water vaport) from compressed natural gas vehicles' engines when used as a fuel.

Again, we are reminded that Biomethane is the same chemical compound as natural gas: CH4, and completely replaces and substitutes for natural gas. Engines, turbines, boilers and every other natural gas appliance can use Biomethane without any adjustments or modifications - just like natural gas.

Biomethane supplies, as opposed to natural gas supplies from the fossil fuel industry, are available in an unlimited supply.

Moving forward with a “Biomethane Infrastructure” is the direction our country needs to be moving as one of our fuel choices as we become energy-independent.  Every MCF of Biomethane that we use displaces about 8 gallons of gasoline and creates jobs that will never be outsourced or downsized.

(Some of the above information from the California Natural Gas Vehicle Coalition.)

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Please Support H.R. 1158, The Biogas Production Incentive Act of 2009 
to Help Create our Nation's Biomethane Infrastructure 
& Biomethane Reserves

SUMMARY:  The Biogas Production Incentive Act of 2009 if enacted, will amend the Internal Revenue Code to allow a business-related tax credit for the production, sale, or use of biogas. Defines biogas as a gas that is derived by processing qualified energy feedstock (i.e., manure of agricultural livestock and other organic agricultural or food industry byproduct waste material) in an anaerobic digester and that contains at least 52% methane and carbon dioxide and trace gases. Provides an increased credit for biogas produced from qualified cellulosic energy feedstock.


Dear Senator or Representative ________

I am writing to you in support of HR 1158, the Biogas Production Incentive Act of 2009 and recommend that Congress develops and passes this much needed legislation that provides a $4.27 per MMBTU tax credit for the production of Biogas – also known as "Renewable Natural Gas," "Renewable Biogas" or "Biomethane."

            H.R. 1158, the Biogas Production Incentive Act would establish this tax credit that will help jumpstart this vital industry.  Renewable biogas and biomethane have been heralded by many as being the greenest of all biofuels.  Biomethane has a carbon dioxide emissions intensity of only 11 as compared with 67.9 for natural gas, 95.8 for diesel and 96.7 for gasoline.  Biomethane can displace and substitute the equivalent of 29% percent of all petroleum diesel transportation fuel used - almost immediately.  The California Natural Gas Vehicle Coalition stated that Biomethane should be classified as a "Super Ultra Low Carbon fuel."  Super Ultra Low Carbon fuel is defined as providing at least an 82 percent reduction in greenhouse gas emissions - based on the California Air Resource Board’s analysis of biomethane from landfill gas.

The U.S. Congress has wisely supported the expanded use of domestic renewable resources through a variety of tax incentives and other programs.  Up to this point, Congress has focused primarily on measures that support the production of renewable liquid transportation fuels or electricity.  In the U.S., however, natural gas represents 23 percent of the energy consumed.

            Natural gas is the fuel of choice to provide residential and commercial heat for space and hot water in most applications and is used to produce steam in a variety of commercial and industrial applications. Natural gas is also the fuel that provides the energy to manufacture many industrial products including aluminum, steel, glass, chemicals, fertilizer, and ethanol.  

            Incentivizing the production of renewable natural gas or "Biomethane" from sources that include animal manure, landfills, renewable biomass and agricultural wastes will support expanding the role of renewables into this existing energy sector, where little opportunity exists today.   It will also create another business investment prospect for renewable project developers and the potential to expand rural economies while supporting existing industrial jobs and dramatically reducing carbon emissions.     

Please consider the following:

•           Renewable Biomethane is a versatile form of bio-energy. It can be used directly at the site of production, or placed in the pipeline to support a variety of residential commercial or industrial applications.

•           Renewable Biomethane produced from renewable sources including animal manure, landfills, renewable biomass and agricultural wastes can be produced at high efficiencies ranging from 60–70 percent.  Additionally, all of the technology components to produce renewable gas from this variety of sources exist today.

•           Renewable Biomethane can be delivered to customers via the existing U.S. pipeline infrastructure.

•           Renewable Biomethane can provide a renewable option for many heavy industries, which could save existing industrial jobs in a carbon constrained economy - while creating new rural green jobs to produce Renewable Biomethane.

•           Renewable Biomethane production in digesters provides the agricultural sector additional environmental benefits by improving waste management and nutrient control. 

We believe this is a fiscally responsible proposal that will provide the following benefits:              

•           Jump-start new biomethane gas production

•           Begin the creation of the biomethane infrastructure and biomethane industry

•           Increase biomethane “reserves”

•           Creation of green jobs

•           Expand the rural economy and increase revenues for farming and agricultural operations

•           Increase energy independence

•           Reduce greenhouse gas emissions.

Thank you for your support and consideration of this legislation.

Sincerely,

_______________________
Signature and address

Please write to your Representative and Senators, and ask them to support H.R. 1158 and the $4.27 per MMBTU tax credit for the production of Biomethane/Renewable Natural Gas, using the above letter as a suggested letter you are welcome to use as your own.

Thank you!  

For more information on Biomethane, see www.Biomethane.com

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We help clients with tax credits when they use renewable energy technologies
such as the Synthesis Gas produced from Biomass Gasification plants.
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Section 45 Tax Credits
Renewable Energy Tax Credits

Our renewable energy project development expertise has made us a leading authority of helping our clients with Section 45 Tax Credits.  Our company and our attorneys are skilled in the areas of renewable energy project finance and tax issues relating to renewable energy projects. We are able to assist our clients in connection with Section 45 tax credit project finance.

Our experience in Section 45 tax credits has helped us structure optimal renewable energy project solutions that match our clients unique economic and tax goals and requirements, which include regulatory constraints and regulatory compliance for most any state. 

Section 45 tax credits generate $.021 cents per kwh of electricity produced by the taxpayer and sold to an unrelated person or company. Section 45 tax credits are available for renewable electricity produced from certain renewable energy projects including, closed-loop biomass, open-loop biomass, geothermal power plants, solar energy, small irrigation power, municipal solid waste, and qualified hydro power production, refined coal and wind power generation.

See one of our following sites at: 

www.Section45TaxCredits.com   or  www.RenewableEnergyTaxCredits.com  

for more information or call:  (832) 758 - 0027 for more information

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Biomethane
www.Biomethane.com
The "Renewable Natural Gas"

The Unlimited Potential for Biomethane and Renewable Natural Gas 

• Sweden is now leading Europe and the rest of the world in the pursuit of cellulosic biomethane.

• According to recent studies by researchers, professors and universities in Sweden, cellulosic biomethane is significantly more economic and less energy intensive to produce today than any biofuel (i.e. E100 Ethanol, B100 Biodiesel, Dimethyl Ether, etc.).
  

• If the U.S. were to similarly emphasize the production of cellulosic biomethane as Sweden is now doing, the U.S. could significantly increase the supply of Biomethane - a renewable, clean fuel with an unlimited supply. 

• Biomethane can be produced from landfill gas, sewage and animal and crop waste. Besides supplementing our existing natural gas supplies, Biomethane would provide huge greenhouse gas emissions reductions.
    

• Based on an analysis conducted for the Department of Energy in the 1990's, it appears that at least 1¼ quadrillion BTUs of methane could reasonably be produced using exiting landfill gas to energy sites, wastewater treatment systems and animal waste sources (Concentrated Animal Feeding Operations) alone. 

• If the Biomethane produces in the U.S. were used for natural gas vehicles, it would displace approximately 10 billion gallons of gasoline, per year!  This is 10 times the amount (1 billion gallons of gasoline) per year projected for natural gas (the fossil fuel) in the Annual DOE outlook.

Regarding Greenhouse Gas Emissions and 
Biomethane/Renewable Natural Gas vs. Gasoline

• Gasoline produces about 110% more Greenhouse Gas Emissions than Biomethane which would have otherwise been flared or vented to the atmosphere.

• In the U.S., it is now feasible to capture and use about 1.25 quadrillion Btu's of Biomethane from landfills, animal waste and POTWs (wastewater treatment systems) alone.  This is equivalent to about 6% of all of the natural gas presently used in the U.S.

• If this Biomethane were used as a transportation fuel in natural gas vehicles, the Biomethane would displace 10 billion gallons of gasoline per year!
  

Other Benefits and Incentives of Biomethane: 
The Federal Biogas/Biomethane Tax Credit:

Equal to 2.0 cents per KWH (approximately $5.66 per MMBtu) for electricity produced on-site from Biomethane.

All other uses of biogas and Biomethane in vehicles and producing electricity off-site) do not presently qualify for the Federal Biogas/Biomethane Tax Credit.

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What is "Pipeline Quality" or "Pipeline Quality Gas"?

The "raw" biogas that is produced from Anaerobic Digesters and Landfill Gas To Energy projects cannot be sold to natural gas pipelines or used in internal combustion engines due to the high number of contaminants, impurities and other chemicals in the biogas.

Raw biogas, in order to become "Biomethane" or Pipeline Quality Gas, must for from "Biogas to Biomethane" wherein the impurities and contaminants of the biogas are removed.  This process of biogas purification to biomethane is also called "Gas Sweetening."  The impurities and contaminants of biogas that need to be removed to then have Biomethane or Pipeline Quality Gas include;  carbon dioxide (CO2), water, hydrogen sulfide (H2S) and Siloxane.  Some of the Biogas to Biomethane technologies include; iron sponge, water scrubbing, membrane separation, pressure swing adsorption (PSA), and mixing with higher quality gases.

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Sewage Sludge
www.SewageSludge.com

We Turn Your City or County's Sewage Sludge 
Problems  into Profits and Green Energy

Sewage Sludge problems are a thing of the past!  and other organic waste streams with one or more of the following: Anaerobic Digester, Anaerobic Lagoon, Biogas Recovery, BioMethane, Biomass Gasification, Biosolids to Energy, Landfill Gas To Energy and Sewage Sludge "problems into profits"  project development services.  We provide the following power and energy project development services:

• Project Engineering Feasibility & Economic Analysis Studies  

• Engineering, Procurement and Construction

• Environmental Engineering & Permitting 

• Project Funding & Financing Options; including Equity Investment, Debt Financing, Lease and Municipal Lease

• Shared/Guaranteed Savings Program with No Capital Investment from Qualified Clients 

• Project Commissioning 

• 3rd Party Ownership and Project Development

• Long-term Service Agreements

• Operations & Maintenance 

• Green Tag (Renewable Energy Credit, Carbon Dioxide Credits, Emission Reduction Credits) Brokerage Services; Application and Permitting
  

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Biomethane: the Perfect Renewable Fuel!
Biomethane Far Better than B100 Biodiesel or E100 Ethanol

As Biomethane is a near perfect fuel, and since Biomethane represents the best of all biofuels in terms of Recycling Carbon, and has the highest Net Energy Balance, and as Biomethane technologies such as Anaerobic Digesters and Biomass Gasification development increases and becomes even more commonplace, one of the fundamental questions is: what is the size of the potential biomass resource supply in the U.S.?

In April 2005, the DOE and the U.S. Department of Agriculture (USDA) co-published a report assessing the potential of the land resources in the U.S. for producing sustainable biomass: Biomass as Feedstock for a Bioenergy and Bioproducts Industry: The Technical Feasibility of a Billion-Ton Annual Supply. Looking at forestland and agricultural land, the two largest potential biomass sources, this study estimates that the U.S. can sustainably produce up to 1.3 billion tons of biomass feedstock by mid-century. This would be enough feedstock to produce 60 billion gallons of B100 Biodiesel and E100 Ethanol with today's technologies.

This study doesn't address the opportunities for Biomethane production from biomass feedstock or Biomass Gasification technologies. Some recent estimates indicate that Biomethane could replace up to 50% of present natural gas consumption in the U.S. and in some countries, such as Iceland, Biomethane already provides 100% of the natural gas requirements.

There are many assumptions in the Billion Ton Study report that impact these estimates, but we believe the estimates reasonably reflect the potential availability and impact of biomass resources.

Of the total estimated resource, the study suggests that forestlands in the contiguous United States can produce approximately 368 million dry tons annually. This projection includes 52 million dry tons of fuelwood harvested from forests and woodlands, 145 million dry tons of residues from wood processing mills and pulp and paper mills, 47 million dry tons of urban wood residues including construction and demolition debris, 64 million dry tons of residues from logging and site clearing operations, and 60 million dry tons of biomass from fuel treatment operations.

Biomass to Biofuels

By "converting" biomass wastes – such as municipal solid waste, sewage sludge, crop residues, energy crops, and manure – into biofuels, this will resolve the energy, environmental and political problems in an economical and environmentally sound manner - that will produce over one million new jobs.

According to Jeff Seisler, Director of the European Natural Gas Vehicle Association, "Biomethane has an outstanding potential as a multifaceted solution to multifaceted social problems: urban and agricultural waste management, water purification, and clean air. Urban and agricultural waste can be processed into usable methane, as can the sewage during the water purification process. Cleaning and compressing the gas for use in vehicles then provides cleaner air than petroleum-consuming vehicles."

Continuing, Mr. Seisler states about Biomethane; "this environmental 'closed loop waste-to-energy-to-fuel used in vehicles that again truck the next load of waste to the energy processing plants-substitutes fossil fuels with a renewable resource and reduces greenhouse gases 100% as compared to over gasoline vehicles (on a well-to-wheel basis).

According to Peter Boisen Chairman, of ENGVA, "various well respected European research institutes now estimate more than three times better fuel output per hectare of land used than if going for ethanol or biodiesel. Sweden currently has a 51% Biomethane share, and Switzerland 37%. France, Norway, Germany and Austria use smaller amounts for vehicles. Iceland, completely without natural gas, uses 100% biomethane in its NGVs," Boisen says.  Continuing, Boisen adds, "China, India, Korea, the Ukraine, Spain and Italy are other examples of countries now starting up projects where Biomethane will be used as a vehicle fuel." 

"With the energy efficiency of the gas production process at 50% to 70% it's hard to think of a more socially acceptable and economic energy value for the transportation sector," Boisen says.

"Governments need to get out of their liquid fuel paradigm to refocus and balance their policies and communications to support the development of a Biomethane infrastructure. In Europe Biomethane has the potential to replace 20% of the petroleum consumed in the transport sector by 2030."

Thursday, 29 June 2006
Sacramento, California USA and Sweden 

In a ceremony held at the Ministry of the Environment in Stockholm, representatives of the Kingdom of Sweden and the State of California signed an agreement pledging the two governments and their related industries to work together to develop bioenergy, with a particular emphasis on Biomethane. 

“Through a strong working relationship between its industry and government, Sweden is showing how bioenergy can be developed in a cost-effective manner that benefits its economy and environment. We are extremely pleased to have signed this Memorandum of Understanding (MOU) that will provide a basis for intensified collaboration between Swedish and California officials to develop a thriving bioenergy industry in California,” said Joe Desmond, Undersecretary for the California Resources Agency.

In particular, Sweden has been a global leader in terms of converting biowaste, largely agricultural material and residues, into usable Biomethane. This gas is then used to either generate electricity, residential heating, or as a transportation fuel.

More than 8,000 vehicles in Sweden are powered by a combination of natural gas and Biomethane. The vehicles include transit buses, refuse trucks, and more than 10 different models of passenger cars. There are more than 25 Biomethane production facilities in Sweden and 65 filling stations. The Swedish Biomethane industry has been growing at an annual rate of about 20 percent over the last five years.

According to the Swedish Gas Association, more than 50 percent of the methane used to power Sweden’s natural gas vehicles now comes from biological sources, up from 45% last year. Natural gas vehicle sales in Sweden are increasing at the rate of 25% per annum. 

Sweden was motivated to develop its Biomethane industry because it has no natural gas reserves, to more efficiently manage its waste, and to meet its obligations under the Kyoto Accord. Since Biomethane is developed from methane sources that would normally release into the atmosphere, it’s considered one of the most climate friendly fuels. Methane (and Biomethane) is 21 times more reactive as a greenhouse gas than carbon dioxide (CO2). Sweden is currently meetings its objectives and schedule as outlined in the Kyoto accord.

Biomethane is developed by heating up and breaking down biomaterials in an (Anaerobic Digesters) digester. Among other raw materials, Swedish operators feed their Anaerobic Digesters with slaughterhouse waste, swine manure, and even grassy crops. After the materials breakdown over a 20 day period, technology is then used to remove the impurities and produce Biomethane. Once cleaned-up, Biomethane is 98 percent methane and easily meets the Swedish and California pipeline standards.

The Memorandum of Understanding can be accessed on the California Resources Agency Web site: http://resources.ca.gov/press_documents/CaliforniaSwedenBiofuelsMOU.pdf

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Anaerobic Digesters recover valuable and toxic Biomethane from organic materials and prevents the Biomethane - which has a Global Warming Potential that is 21 times more harmful to our climate than Carbon Dioxide Emissions - from entering the atmosphere.  

Biomethane, which we also refer to as "Renewable Natural Gas" is used as a renewable fuel for our cogeneration and trigeneration power plants. Alternatively, we may sell the Biomethane to a customer and transport it to them from our Anaerobic Digesters via natural gas pipelines.

We believe Anaerobic Digesters and Biomethane represent exciting opportunities for generating renewable natural gas and profits - for multiple reasons:

1.  Anaerobic Digesters take an existing liability and waste (Biomethane) and convert it into an asset and " profit generator."

2.  Anaerobic Digesters mitigate and reverse climate change and global warming by preventing Biomethane to escape into the atmosphere, which is one of the major causes of climate change and global warming.  

Of all Greenhouse Gas Emissions, Biomethane is 21 times more harmful to the environment than Carbon Dioxide Emissions.

3.  Anaerobic Digesters are vital for renewable energy production and helping our country's drive for energy independence. 

4.  EVERY wastewater treatment plant as well as ALL Concentrated Animal Feeding Operations (CAFO's) - IN EVERY COUNTRY - will soon be installing Anaerobic Digesters to prevent Biomethane from entering the atmosphere and help reverse climate change as well as for use as a renewable fuel. Or, they will be replacing their existing inefficient and inferior mechanical wastewater treatment plants, with our "Natural Wastewater Treatment" plants! 

5.  The country of Sweden is the global leader in Biomethane production.  Sweden has identified the Biomethane opportunities and is converting biowaste derived from agricultural material and residues into usable Biomethane. The Biomethane is used to generate clean, renewable electricity, residential heating, and also as a transportation fuel. Biomass sources make up 45% of Sweden’s Biomethane.  Sweden's Biomethane industry has been growing at an annual rate of around 20% over the last five years.  Biomethane powers more than 8,000 transit buses, garbage trucks, and 10 different models of passenger cars in Sweden. Sweden now has more than 25 Biomethane production facilities and 65 filling stations. The country believes that since Biomethane is developed from natural, organic sources that would have been released into the atmosphere, that Biomethane is considered one of the most climate-friendly fuels. Biomethane is 98% methane and easily meets the Swedish and California pipeline standards.

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We develop renewable energy projects, and specialize in solar power and energy project development. Our company provides the total, turnkey solar energy system "in-house."  This means our capabilities and core competencies include solar project:

Our company provides the total, turnkey solar energy system design/engineering through installation, "in-house."  This means we provide the following; 

• project identification

• project analysis

• design/engineering

• finance (through investors and joint venture partners)

• installation or construction

• ownership (with PPA)

• operations

• maintenance and service or our solar energy systems

We have successfully completed "turnkey" installations of our solar energy systems for clients that include residential, commercial, industrial, and government.  Our present clients and projects include a large pipeline of solar energy systems projects that are now in design &/or under development or construction. Our present projects range in size from:

100 kW to 90 MW

We recently completed a 160 kW solar energy system for a major hotel wherein we self-funded their new "Rooftop PV System" with our Power Purchase Agreement.

Our solar power and energy project development services and capabilities include multiple solar technologies, including;

• Concentrating Solar Power 

• Concentrating Photovoltaic 

• High Concentration Photovoltaic

for utility scale solar power plant applications.

And our Super High Efficiency Solar Cogeneration & Solar Trigeneration Energy Systems:

• Solar Cogeneration Energy Systems  

• Solar Trigeneration Energy Systems

for commercial, government, industrial and municipal clients. 

What are "renewable energy resources?"

"Renewable energy resources" include; 

• Biomethane  

• B100 Biodiesel

• E100 Ethanol

• Hydrogen Fuel

• Solar Power & Energy (for homes and businesses)

• Synthesis Gas

• Utility Scale Solar Power Plants

• Wind Power Generation

What is "carbon free energy?"

"Carbon free energy" is energy that is produced or generated without producing any carbon dioxide emissions.  Even nuclear power plants generate "carbon free energy."Renewable energy technologies that are used in the production and generation of carbon free energy include;

• Anaerobic Digesters

• Biogas Plants

• Biodiesel Refineries

• Biomass Gasification

• Concentrating Photovoltaic

• Concentrating Solar Power

• Decentralized Energy

• Dispersed Generation

• Distributed Generation

• Distributed PV

• EcoGeneration

• Evacuated Tube Collectors

• High Concentration Photovoltaic

• High Voltage Direct Curent

• Hydrogen Fuel Cells

• Molten Carbonate Fuel Cells

• Net Zero Energy

• Net Zero Energy Buildings

• Phosphoric Acid Fuel Cells

• Plasma Gasification

• Solar Absorption Cooling

• Solar Cogeneration  

• Solar Desalination (Clean Water and Clean Power!)

• Solar Electric Power Systems

• Solar Energy Systems

• Solar Heating And Cooling

• Solar Power And Energy

• Solar Thermal Collectors

• Solar Trigeneration

• Thin Film Photovoltaics

• Trigeneration

• Waste To Energy 

• Waste to Fuel 

Energy Efficiency Measures and Energy Conservation Measures such as Automated Demand Response and Demand Side Management and Energy Efficient Lighting, while not "generating" carbon free energy, provides significant increases in efficiencies, thereby reducing the overall need for energy, which may come from central power plants that are very inefficient and generate significant amounts of carbon dioxide emissions.

Even nuclear power plants generate "carbon free energy."   These are just some examples of carbon-free renewable energy. The purpose of all these methods is to combat the increase in greenhouse gas emissions and reduce our impact on the environment as a whole.

Solar Trigeneration^sm
www.SolarTrigeneration.com

We Do Solar Right ^sm

We install our Solar Trigeneration^sm Energy Systems, for qualified commercial businesses, as well as  cities, schools and government facilities with our Zero Up-front Cost program.

For some customers - based on their present location, utility company and electric rate - we are able to reduce their electric rate by 10%. Even more for other customers.  Solar Trigeneration^sm Energy System!

We provide the answers to your questions about solar power and energy!

Does your; business, city, school, or electric utility want a more sustainable solar power and energy solution?

Are you interested in transforming your facility, campus or building(s) to "Net Zero Energy"™ buildings?

Does your city or school have a problem with rising electricity and energy expenses, but not have the financial resources to provide the necessary updates and upgrades to make your buildings more efficient?

Maybe you have already decided to go solar, but you have a lot of questions, and don't know where to start.  Call us, we have the answers to your solar questions.

What is the optimum solar solution?  There are hundreds of companies in the solar power and energy industry.....  Who do you call to help you with these questions to help you make the right decisions?

There's still more questions, that you may not have thought about..... which solar technology do you go with, and what is the return on investment? 

Are there any solar rebates, refunds, tax credits or other incentives available?

What about investors that might be interested in owning/operating and maintaining our solar energy system under a Power Purchase Agreement?

You have numerous questions and need the answers to help in the decision-making process regarding the solar power and energy system you want to install.  These decisions will have a long-lasting impact as the solar energy system that you install at your business or facility will probably be generating clean power for the next 40 to 50 years, if not longer!  So, the decisions that you need to make now regarding your solar energy system will be a decision that will be either a long-term asset or a liability, depending on the equipment you select and who you choose to install it. 

We can help cities, schools and commercial (and large residential) customers make the switch to solar!

And now, with our no up-front cost for our Solar Trigeneration^sm Energy System, we can also transform your building(s) to a "Net Zero Energy Building"™ and many times, actually REDUCE your present energy expenses by 10%, and possibly more!

Examples of buildings/facilities where our Solar Trigeneration^sm Energy Systems would benefit, include; universities, churches, data centers, shopping centers, schools, radio/television stations, food processing, warehouses, new real estate developments and subdivisions, and electric utilities - practically any commercial facility can be upgraded to one of our "pollution free power" systems featuring one of our solar energy systems,  including our Solar Trigeneration^sm system!

Call or email us, we can provide these answers. We are focused on providing the optimum solar energy systems for our clients. This begins with an initial review of your past 12 months energy/electrical bills. The next step would include a site visit which may include a Demand Side Management study and/or a Solar Feasibility Study which determines the optimum solar energy system for your facility or location.  Once the optimum solar solution(s) are determined, we then have a blueprint to proceed that could include our installing one of our Solar Cogeneration™ or Solar Trigeneration^sm energy systems.  Or for a city, real estate development or subdivision, or an electric utility, one of our utility scale power plants which might be a Concentrating Photovoltaic, Concentrating Solar Power or High Concentration Photovoltaic power plants.

What is "Net Zero Energy^sm?"

Net Zero Energy^sm - when applied to a home or commercial building, simply means that the home or buildings generates as much power and energy as they consume, a monthly or annual basis, and with an onsite, renewable energy system, such as our Solar Trigeneration^sm Energy System. 

What is a Net Zero Energy Building^sm?

A Net Zero Energy Building^sm produces as much energy as it uses over the course of a year. Net Zero Energy Buildings^sm are very energy efficient. The remaining low energy needs are typically met with on-site renewable energy. 

First of all, understand that there is no such thing as a "zero energy building!" EVERY building uses energy, or you may as well be in a cave!  

The important considerations are, 

1.  How efficient is the building?  

2.  How much energy does the building use, and how efficiently is it used?  

3.  How much "carbon free energy" or "pollution free power" is generated by the buildings' own onsite renewable energy system?

4.  What are the utility company's prices for the excess power generated and sent to the grid? 
(see: Net Energy Metering)

5.  How difficult is it to interconnect the renewable energy system of the building with the utility company's powerlines/electric grid?   

At the heart of a Net Zero Energy Building^sm is the idea that any building can meet its energy requirements from low-cost, locally available, nonpolluting, renewable sources, like our Solar Trigeneration^sm Energy Systems. Our Solar Trigeneration^sm Energy Systems are the idea whose time has come, to make Net Zero Energy Buildings^sm commonplace.

Solar Trigeneration^sm Energy Systems Provide All of the Cooling, Heating & Power, for Any Size Building, with only the Energy of the Sun. Solar Trigeneration^sm Energy Systems Provide Simultaneous  Cooling, Heating & Power whether it is 12 Noon, or 12 Midnight,  and can do so, WITHOUT Connection to the electric grid!

The Diagram Below Shows How Our Solar Trigeneration^sm Energy System Works, 
for Heating and Cooling a Building (next to the Solar Thermal Collectors, are the PV Panels, that generate the Electricity).

Our Solar Trigeneration^sm Energy System
provides "Cooling, Heating & Power" for your business,
or home with the free energy of the sun!

What is Net Energy Metering?

Net energy metering is used to measure a customer's total electric consumption against that customer's total on-site electric generation.  When a customer's onsite generation of power exceeds the amount that they use, the customer's solar energy system (or other renewable energy system) exports the extra electricity to the grid.  When the power requirements of the customer exceeds their onsite generation of power, the customer imports the electricity they need from electric grid. The customer pays the electric company for any extra power they use over the amount they generate - OR -  the customer receives a credit or refund from the electric company if they exported more power to the grid, than what they consumed.  

Renewable Energy Is Necessary for Net Zero Energy Buildings

Much focus is placed on energy efficiency as the most cost-effective way to reduce energy use in commercial buildings. However, consumption can be reduced only so much. There is a point at which the cost of adding efficiency measures is higher than that of using renewable energy such as thin film photovoltaics and other solar energy systems. 

Aggressive energy efficiency strategies can reduce a building's energy consumption by 50% to 70%. Renewable energy technologies must be used to reach the goal of a net-zero energy building (NZEB).

Supply-Side Technologies

Various supply-side renewable energy technologies are available for Net Zero Energy Buildings. Supply-side technologies, often called energy producers, collect natural energy and transform it into a useful form. Examples of these technologies include PV, solar hot water, wind, hydroelectric, and biofuels.

Ranking of Energy Options

All renewable sources are favorable over conventional energy sources such as coal and natural gas; however, the U.S. Department of Energy recommends the following ranking for these options (the lower numbers are preferable):

This hierarchy is weighted toward renewable technologies within the building footprint and site. Rooftop PV and solar water heating are the most applicable supply-side technologies for Net Zero Energy Buildings. Other supply-side technologies such as parking lot-based wind or solar energy systems may be available.

The goal in developing the ranking was to encourage technologies that:

• Minimize overall environmental impact by encouraging energy-efficient building designs and reducing transportation and conversion losses

• Will be available over the lifetime of the building

• Are widely available and have high replication potential for future Net Zero Energy Buildings.

Solar Trigeneration^sm
www.SolarTrigeneration.com

Now, Your Business Can Have Our Solar Trigeneration™ 
Energy System, installed for No Up-Front Costs!

Through an affiliated partner company, we are now installing our Solar Trigeneration™ Energy Systems, for qualified commercial businesses, nationwide, with Zero up-front costs.

Some customers may even see a decrease in their energy expenses by as much as 10% to 20% with our Zero up-front cost Solar Trigeneration™ Energy System!

To qualify for our no up-front cost Solar Trigeneration Energy Systems, businesses must:

• Have a good credit rating

• Agree to buy all of the energy generated from the Solar Trigeneration™ Energy System through a 20 year Power Purchase Agreement

• Other conditions may apply, depending on location, state or utility company you are presently buying power from.

We expect ALL of our customers will be very happy knowing that the clean, green, renewable power they are using is: 

• More reliable than the electricity from the power company.

• Saving the environment by reducing Greenhouse Gas Emissions and helping reverse Climate Change and Global Warming.

• Generated from their own reliable Solar Power System on their roofs.

• Saving Money!  At today's published electric rates at Southern California Edison, TXU, Reliant and Centerpoint, most of our customers will also enjoy a SAVINGS on their present electric bills by as much as 10% from what they are now paying for their electricity from the electric utility.

• Under warranty.

• At the end of the Power Purchase Agreement, the Solar Trigeneration™ Energy System is then offered for sale to our customers, for $1.00.  And then their energy savings really start to add up as the power and electricity generated from their Solar Trigeneration™ Energy System is free!

Our "Solar Trigeneration^sm" Power and Energy Systems
Generate Carbon Free Energy and Pollution Free Power
Which is Sustainable, Clean, Renewable and Affordable

Solar Energy Systems provides cooler, cleaner, greener power and energy project development services.  Our Solar Energy Systems are an environmentally-friendly and economically-superior choice to expensive natural gas and electricity. Additionally, our renewable energy technologies generate "green tags" or a Renewable Energy Credit.  

We provide Solar Power and Energy systems that we refer to as "EcoGeneration" solutions that produce cooler, cleaner, greener power and energy for our customers and our environment. Unlike most companies, we are equipment supplier/vendor neutral. This means we help our clients select the best equipment for their specific application. This approach provides our customers with superior performance, decreased operating expenses and increased return on investment. 

Our company provides turn-key project solutions that include all or part of the following: 

• Engineering and Economic Feasibility Studies 

• Project Design, Engineering & Permitting

• Project Construction

• Project Funding & Financing Options

• Shared/Guaranteed Savings program with no capital requirements. 

• Project Commissioning 

• Operations & Maintenance 

• Green Tag/Renewable Energy Credit Application, and Marketing

Net Zero Energy Buildings^sm
www.NetZeroEnergyBuildings.com

The Audubon Nature Center Installs Solar Trigeneration  System
Making this one of the World's First "Net Zero Energy Buildings"
at Their New Facility in Los Angeles, California

GRID-FREE SOLAR ENERGY SYSTEM....
NO CONNECTION TO THE ELECTRIC UTILITY!

The Solar Trigeneration  Provides All of their Facility's (5000 sq.ft.)
Cooling, Heating and Power Requirements - at 12 noon or 12 midnite,
WITHOUT ANY CONNECTION to the Electric Utility
with our Solar Trigeneration Energy System!  

The Sun Powers the Audubon Nature Center's Solar Trigeneration  
System at Debs Park in Los Angeles. The Audubon Nature Center's 
building is one of the world's first "Net Zero Energy Buildings." 
The Solar Trigeneration System Consists of a 10 Ton "Solar 
Absorption Cooling" System Matched with a Solar Electric 
Power System and a Solar Water Heating System

By:  Monty Goodell, MBA
www.SolarTrigeneration.com
Los Angeles, California

There is now a better, more efficient, “pollution free power” and "carbon free energy" solution for cooling, heating and powering homes and commercial buildings where solar energy is available. It's called Solar Trigeneration.

Solar Trigeneration is defined as the simultaneous generation of cooling, heating and power with only the free solar energy from the sun providing the "fuel". 

Solar Trigeneration is now a reality at the Audubon Center at Debs Park several miles from downtown Los Angeles and is one of the world's first "Net Zero Energy Buildings." Net Zero Energy Buildings." Net Zero Energy Buildings."

The Audubon Nature Center is totally powered by the sun’s energy and our Solar Trigeneration energy system!

The 5,300 square foot building operates entirely “grid-free” and without any electric connections to the electric grid, or natural gas connections – a truly sustainable power and energy solution. 

Best of all, the Audubon Center doesn’t rely on the over-burdened electric grid or even natural gas.  Therefore, the Audubon Nature Center NEVER receives an electric bill or natural gas bill.... ever!

The Audubon Nature Center's 5,000 square foot office and conference facility is powered by a Solar Trigeneration system that features a 25-kilowatt solar electric power system where the energy is stored in a bank of batteries. The Center is cooled by a 10-ton solar absorption cooling system powered by an array of very efficient solar heat pipe vacuum tube thermal collectors.  The collectors heat the water to temperatures of 200+ degree F stored in a 1,200 gallon insulated tank, another type of inexpensive battery. The Solar Trigeneration system at the Audubon not only provides the air-conditioning in the summer but also heats the building in the winter, and provides the hot water for the kitchen and bathrooms. 

Absorption chillers, and cooling with solar energy with an absorption chiller are not new technologies.  In fact, absorption chiller technology is over 70 years old.  The first refrigerators were powered by propane gas to run the absorption chillers that used ammonia as a refrigerant.  Electricity and the electric compression chiller gained popularity only because of the convenient “plug and play” appliance and relatively cheap electric rates.  Electricity is no longer economically, or environmentally “cheap.”

History of Cogeneration and Trigeneration

Few people realize that the world's first commercial power plant, designed and built by Thomas Edison, was a cogeneration power plant that was first opened on Pearl Street, in Lower Manhattan, New York.  That was in 1882!  Edison not only generated, and sold electricity in the several blocks surrounding his "Pearl Street Station" but he also sold the hot water that was also generated from the cogeneration plant. The fuel Edison used for generating the electricity and hot water (cogeneration) came from "pulverized coal." The Pearl Street Station provided 110 volts of "direct current" power to 59 customers in lower Manhattan, around his Pearl Street laboratory. 

Cogeneration is the simultaneous production of heat and power. 

Trigeneration is the simultaneous production of cooling, heating and power.

Our company, in partnership with the Renewable Energy Institute and our affiliated partners, have perfected "Solar Cogeneration" and "Solar Trigeneration" which are the "heart" of our Net Zero Energy Buildings.

Unlike traditional cogeneration and trigeneration power plants that are fueled by natural gas - and Thomas Edison's cogeneration plant, which was fueled with pulverized coal, our Solar Cogeneration and Solar Trigeneration energy systems are fueled with the energy of the sun!  And, while natural gas is a "cleaner" fuel, it still has its problems in that it is a limited resource and generates greenhouse gas emissions.  Natural gas also have had extreme price swings and has a history of price volatility.  Natural gas prices have gone from a high of $17.00/mmbtu to a recent low of under $3.00/mmbtu.  

Regarding pulverized coal, yes, it's cheap in terms of the cost of generating electricity, but too many people forget about the "externalities" of pulverized coal that is not reflected in the "cheap" costs of generating electricity from pulverized coal.  These costs not accounted for are the huge environmental cost relating to the use of pulverized coal.  Pound for pound, pulverized coal and coal fired power plants generate more greenhouse gas emissions than any other fossil fuel.  There are also the costs related to the health and safety issues of the miners that mine the coal.  And, the costs to the environment in terms of the ever-increasing amounts of mercury that are "dumped" into the environment from coal fired power plants, is also not reflected in the "cheap" price of generating power from pulverized coal.

Unlike the problems inherently found with the use of fossil fuels, Solar Cogeneration and Solar Trigeneration have no such problems. 

And talk about "cheap" costs of generating power and energy, there is nothing cheaper than free!!!!  

The owners of the Audubon Nature Center never receive any monthly natural gas or electric bills!

And the owners of the Audubon Nature Center will never have to account for their greenhouse gas emissions, or comply with the ever-increasing regulations related to greenhouse gas emissions and the pending Cap and Trade laws..... thanks to our  Solar Trigeneration energy system!

Solar Trigeneration is an EcoGeneration solution.  EcoGeneration refers to a power and energy system that uses the “natural” energy or fuel that is available for a specific site or location. Such energy or fuel includes, solar, wind, BioMethane, geothermal, and ocean power, including ocean tidal and ocean thermal energy conversion. For example, in the desert areas of the Southwestern U.S. , there is an abundance of solar energy. Therefore, home-owners and business owners in this part of the country should seriously consider an EcoGeneration system (“ecogen system”) that optimizes the opportunities available through solar energy

Today, the cause of the summer peak electric demand, electric supply problems, and black-outs, are the result of the energy crisis in California, primarily attributed to the air conditioning load. Over 40 percent of the electricity generated every day goes is used for air conditioning.  At this time of year, the electric utilities are forced to turn on all of their power plants to generate the “peak” demands required by the customers, primarily for air-conditioning.  This means that all of the efficient power plants, the inefficient power plants, along with all of the “peaking” power plants have to run to generate the electricity needed. The high cost of meeting the peak demand is passed on to the consumers with rates of $.20+ per kWh during the summer months. For fixed income seniors living in desert communities, they are already forced to conserve on energy, food, water, and other necessities of life. 

Greater Demands on California’s Limited Electric Supply, Lack of New Electric Power Supplies, and This Summer’s Heat Wave are Compounding the Problem Leading to the “Perfect Electric Storm”

Many people will remember the movie “The Perfect Storm” from several years ago, when several storms came together in the northeastern part of the U.S. to produce a deadly and catastrophic “perfect” storm. Today, a different type of “perfect storm” is brewing in California. The storm that’s looming on the horizon in California is a “perfect electric storm” wherein the supply of electricity from the electric utility company’s power plants are unable to keep-up with the demand – meaning a black-out, or loss of electricity, like the black-outs from previous years, and like the northeastern black-out from 2003.

The most likely time of year for a black-out in California, unfortunately, is the summer, when air-conditioners are running at the maximum, and placing the maximum load on California’s electricity supply.  Should such a black-out occur in the desert areas of California, where daily high temperatures routinely reach 110 degrees and higher, and where a significant percentage of the population is comprised of retired and senior citizens, and should the black-out be prolonged, a number of deaths will be the likely outcome. People, and especially the elderly, simply cannot tolerate prolonged high temperatures

How Do We Prevent the “Perfect Electric Storm” from Occurring in California and Other Regions in the U.S.?

Another major concern is how do we prevent the “Perfect Electric Storm” from happening, like the Northeast Blackout several summers ago, especially for people living in the desert?  California ’s energy authorities are warning of a possible energy crisis during the hot summer months, due to the excessive and prolonged summer temperatures where demand increases by over 40 percent.  Compounding the problem is the rising demand for electricity due to population growth and the limited transmission capacity in some areas in the region.  According to the California Energy Commission, the State must build three natural gas-fired 500-megawatt peaking power plants, every year, just to keep up with the growing demands of electricity. Failure to keep up with demand means The problem is getting worse due to the population growth in the Inland Empire , Coachella Valley and Antelope Valley. The projected power gap for the coming summers remains bleak.

Governor Schwarzenegger’s “Million Solar Roofs” program and the passage of the 2005 Federal Energy Act will be the foundation to create a “Perfect Solar Storm” to trigger the Solar Economy throughout California. 

With the threat of California’s seniors and elderly dying from heat exhaustion due to power outages, black-outs, rolling black-outs and the rising costs of electricity and natural gas, combined with the continuing impact of global warming, the perfect solution is to create a Solar Revolution by cooling, heating and powering the desert with solar energy and technologies like Solar Cogeneration or Solar Trigeneration.

For more information about Solar Energy Systems, such as Solar Cogeneration or Solar Trigeneration, call/email us for more information.

The Audubon Center's new Solar Trigeneration power and energy system
makes this building a "Net Zero Energy Building"

The Audubon's Roof showing the Solar Thermal Collectors, part of the 
Solar Trigeneration power and energy system

The heart of the Audubon's Solar Trigeneration power and energy system
provides "free heating, cooling and domestic hot water," a "net zero energy building."

The hot water from the Solar Thermal Collectors on the roof of the Audubon is pumped here for producing the building's heating, cooling and domestic hot water.  Hot water is stored in the tank on the left for overnight.

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Absorption Chillers 
&
Adsorption Chillers

For Solar Trigeneration Applications

What Absorption Chillers and How Does They Work?

Absorption chillers use heat instead of mechanical energy to provide cooling. A thermal compressor consists of an absorber, a generator, a pump, and a throttling device, and replaces the mechanical vapor compressor.

In the chiller, refrigerant vapor from the evaporator is absorbed by a solution mixture in the absorber. This solution is then pumped to the generator. There the refrigerant re-vaporizes using a waste steam heat source. The refrigerant-depleted solution then returns to the absorber via a throttling device. The two most common refrigerant/ absorbent mixtures used in absorption chillers are water/lithium bromide and ammonia/water.

Compared with mechanical chillers, absorption chillers have a low coefficient of performance (COP = chiller load/heat input). However, absorption chillers can substantially reduce operating costs because they are powered by low-grade waste heat. Vapor compression chillers, by contrast, must be motor- or engine-driven.

Low-pressure, steam-driven absorption chillers are available in capacities ranging from 100 to 1,500 tons. Absorption chillers come in two commercially available designs: single-effect and double-effect. Single-effect machines provide a thermal COP of 0.7 and require about 18 pounds of 15-pound-per-square-inch-gauge (psig) steam per ton-hour of cooling. Double-effect machines are about 40% more efficient, but require a higher grade of thermal input, using about 10 pounds of 100- to 150-psig steam per ton-hour.

In single-effect absorption chillers, all condensing heat cools and condenses in the condenser. From there it is released to the cooling water. A double-effect machine adopts a higher heat efficiency of condensation and divides the generator into a high-temperature and a low-temperature generator.

Actions You Can Take

Determine the cost-effectiveness of displacing a portion of your cooling load with a waste steam absorption chiller by taking the following steps:

• Conduct a plant survey to identify sources and availability of waste steam

• Determine cooling load requirements and the cost of meeting those requirements with existing mechanical chillers or new installations

• Obtain installed cost quotes for a waste steam absorption chiller

• Conduct a life cycle cost analysis to determine if the waste steam absorption chiller meets your company's cost-effectiveness criteria.

Absorption Chillers Refrigeration Cycle

The basic cooling cycle is the same for the absorption and electric chillers. Both systems use a low-temperature liquid refrigerant that absorbs heat from the water to be cooled and converts to a vapor phase (in the evaporator section). The refrigerant vapors are then compressed to a higher pressure (by a compressor or a generator), converted back into a liquid by rejecting heat to the external surroundings (in the condenser section), and then expanded to a low- pressure mixture of liquid and vapor (in the expander section) that goes back to the evaporator section and the cycle is repeated.

The basic difference between the electric chillers and absorption chillers is that an electric chiller uses an electric motor for operating a compressor used for raising the pressure of refrigerant vapors and absorption chillers use the heat for compressing refrigerant vapors to a high-pressure. The rejected heat from the power-generation equipment (e.g. turbines, microturbines, and engines) may be used with an absorption chiller to provide the cooling in a CHP system.

The basic absorption cycle employs two fluids, the absorbate or refrigerant, and the absorbent. The most commonly fluids are water as the refrigerant and lithium bromide as the absorbent. These fluids are separated and recombined in the absorption cycle. In the absorption cycle the low-pressure refrigerant vapor is absorbed into the absorbent releasing a large amount of heat. The liquid refrigerant/absorbent solution is pumped to a high-operating pressure generator using significantly less electricity than that for compressing the refrigerant for an electric chiller. Heat is added at the high-pressure generator from a gas burner, steam, hot water or hot gases. The added heat causes the refrigerant to desorb from the absorbent and vaporize. The vapors flow to a condenser, where heat is rejected and condense to a high-pressure liquid. The liquid is then throttled though an expansion valve to the lower pressure in the evaporator where it evaporates by absorbing heat and provides useful cooling. The remaining liquid absorbent, in the generator passes through a valve, where its pressure is reduced, and then is recombined with the low-pressure refrigerant vapors returning from the evaporator so the cycle can be repeated.

Absorption chillers are used to generate cold water (44°F) that is circulated to air handlers in the distribution system for air conditioning.

"Indirect-fired" absorption chillers use steam, hot water or hot gases steam from a boiler, turbine or engine generator, or fuel cell as their primary power input. Theses chillers can be well suited for integration into a CHP system for buildings by utilizing the rejected heat from the electric generation process, thereby providing high operating efficiencies through use of otherwise wasted energy.

"Direct-fired" systems contain natural gas burners; rejected heat from these chillers can be used to regenerate desiccant dehumidifiers or provide hot water.

Commercially, absorption chillers can be single-effect or multiple-effect. The above schematic refers to a single-effect absorption chiller. Multiple-effect absorption chillers are more efficient and discussed below.

Multiple-Effect Absorption Chillers

In single-effect absorption chillers, the heat released during the chemical process of absorbing refrigerant vapor into the liquid stream, rich in absorbent, is rejected to the environment. In a multiple-effect absorption chiller, some of this energy is used as the driving force to generate more refrigerant vapor. The more vapor generated per unit of heat or fuel input, the greater the cooling capacity and the higher the overall operating efficiency.

Double-effect absorption chillers uses two generators paired with a single condenser, absorber, and evaporator. It requires a higher temperature heat input to operate and therefore they are limited in the type of electrical generation equipment they can be paired with when used in a CHP System.

Triple-effect absorption chillers can achieve even higher efficiencies than the double-effect chillers. These absorption chillers require still higher elevated operating temperatures that can limit choices in materials and refrigerant/absorbent pairs. Triple-effect chillers are under development by manufacturers working in cooperation with the U.S. Department of Energy.

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What is "Copper Indium Gallium Diselenide?"

Copper Indium Gallium diSelenide (CuInSe2) is a material that provides an extremely high absorption of light ( 99%) to be absorbed in the first micron of the material. Copper Indium Gallium diSelenide is projected to be the revolutionary material that some are saying, could put typical "central" power plants and some electric utilities, out of business, as it will be much cheaper for customers to generate their own onsite power with Thin Film Photovoltaics made from these materials.   

When additional small amounts of Gallium is added to Copper Indium diSelenide, this increases its' light-absorbing band gap, thereby making the solar panel more closely match the solar spectrum of the sun.  This, in turn, increases the voltage and the efficiency of the Thin Film Photovoltaics solar panel. 

Solar panels produced with Copper Indium Gallium diSelenide cells have reached efficiencies of more than 20% - which is much higher than the other Thin Film Photovoltaics. 

Copper Indium Gallium diSelenide solar panels create more electricity from the same amount of sunlight than other Thin Film Photovoltaics panels.  This translates into a higher conversion efficiency. 

The conversion efficiency of Copper Indium Gallium diSelenide PV technologies is very stable over time, meaning its power output remains stable over many years, while the power output of many other PV materials can rapidly decline with time. 

What are "Building Integrated Photovoltaics?"

Building Integrated Photovoltaics (BIPV) are solar energy systems that are integrated into a part of the building, that serve as the building's exterior or the building's skin. 

Commercial buildings and facilities (including houses) that integrate their own solar power systems into the building's exteriors, are referred to as "power buildings."

The technology that makes this possible is "Thin Film Photovoltaics."

What are Thin Film Photovoltaics?

Without a doubt, the most exciting technology in the solar power industry is "Thin Film Photovoltaics."  Thin Film Photovoltaics technology represents the next big thing in renewable energy and solar power as it integrates nanotechnologies into the production of solar photovoltaics. 

According to the Department of Energy, the recent technological advances in thin film photovoltaics make this a very exciting time to be in the solar energy industry.  These advances have led to many new developments in the components and manufacturing of thin film photovoltaics. This has made thin film photovoltaics cheaper to manufacture as they are also now easier to install since they are extremely versatile, flexible, bendable, and much lighter.

Thin film photovoltaics  have led many to believe that as much as 50% of our nation's future power will be generated by "power buildings" that integrate "building integrated photovoltaics" or "BIPV" into the building's skin or exterior surfaces, that convert sunlight into "pollution free power" for use in the building.  This also designates these buildings (and homes) as "Net Zero Energy Buildings" and make the option for going grid-free, or not connecting to the grid, a real possibility.

According to the Department of Energy, the market potential for printed electronics will grow into a $47 billion market by 2018.  Thin film photovoltaics represents a significant portion of this market - and based on this heavily researched solar technology, thin film photovoltaics now represents a $20 billion/year industry in the U.S.

The solar PV panels produced under the thin film photovoltaics umbrella have the potential to produce power significantly cheaper power than today’s typical silicon-based PV panels.  The panels are usually made in the form of a monolithic piece of glass, upon which various thin films are deposited, although a number of firms are working on depositing the materials on a substrate, such as stainless steel or plastic.

Types of Thin Film Photovoltaics – there are primarily three types of thin film photovoltaics and include:

1. Amorphous Silicon

2. Cadmium Telluride

3. Copper Indium Gallium Diselenide

Amorphous Silicon had the largest share of the thin film photovoltaics market through 2006. It has been researched for the longest period of time, may be the best understood material of the three and has been commercial for the longest. Cadmium Telluride has the remaining share and is growing despite its highly toxic ingredients.

Thin Film Photovoltaics Advantages over Crystalline Silicon Photovoltaics

• Lower cost of production of the 

• Lower production facility cost per watt - CapEx

• Uses as little as 1/500 of the amount used in standard silicon cells

• Lower energy payback – amount of time until the product produces more energy than was utilized in its manufacture.

• Produces more power/watt

• Superior performance in hot and cloudy climates

• Integrates seemlessly in homes and buildings – see Building Integrated Photovoltaics 

• Produces the lowest cost power

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About Us

We provide renewable energy engineering services and turnkey installations of our solar energy systems for commercial, municipal, government, schools and utility clients with projects located in the U.S., Canada Central America and the Caribbean. In many cases, we may also be able to provide project finance or investment. 

• Automated Demand Response

• Biomethane 

• Carbon Dioxide Emissions Consulting

• Carbon Emissions Consulting & Solutions

• Carbon Free Energy

• Clean Energy Parks

• Clean Power Generation

• Concentrated Solar Power

• Concentrating Photovoltaic

• Concentrating Solar Power

• Decentralized Energy

• Demand Side Management

• Distributed Generation

• Evacuated Tube Collectors

• Geothermal Power Plants 

• Greenhouse Gas Emissions consulting

• Ground Source Heat Pumps

• High Concentration Photovoltaic

• Molten Carbonate Fuel Cells

• Onsite Power Generation

• Natural Wastewater Treatment Plants 

• Phosphoric Acid Fuel Cells

• Pollution Free Power

• Power Purchase Agreements

• PPA Funding

• Renewable Energy Capital

• Renewable Energy Centers

• Renewable Energy Credit consulting

• Renewable Energy Funds

• Renewable Energy Investments

• Renewable Energy Parks

• Renewable Energy Technologies

• Solar Cogeneration

• Solar Desalination

• Solar Electric Power Systems

• Solar Energy Systems

• Solar Heating And Cooling

• Solar Power And Energy

• Solar Power Purchase Agreements

• Solar Thermal Collectors

• Solar Trigeneration

• Thin Film Photovoltaics

• Trigeneration

• Waste To Energy 

• Waste to Fuel 

• Wind Farm Development

• Wind Power Generation

 

Solar Electric Power Systems (PV)

Solar electric power systems transform sunlight into electricity. Sunlight is an abundant resource. Every minute the sun bathes the Earth in as much energy as the world consumes in an entire year. Solar cells employ special materials called semiconductors that create electricity when exposed to light. Solar electric systems are quiet and easy to use, and they require no fuel other than sunlight. Because they contain no moving parts, they are durable, reliable, and easy to maintain. How It Works Solar cells, also known as photovoltaic (PV) cells, do the work of making electricity. Several types of solar electric technology are under development, but four—crystalline silicon (a form of refined beach sand), thin films, concentrators, and thermophotovoltaics—are illustrative of the range of technologies. Solar cells are connected to a variety of other components to make a solar electric power system. Crystalline Silicon Crystalline silicon solar cells are used in more than half of all solar electric devices. Like most semiconductor devices, they include a positive layer (on the bottom) and a negative layer (on the top) that create an electrical field inside the cell. When a photon of light strikes a semiconductor, it releases electrons (see animation). The free electrons flow through the solar cell's bottom layer to a connecting wire as direct current (DC) electricity. Some solar cells are made from polycrystalline silicon, which consists of several small silicon crystals. Polycrystalline silicon solar cells are cheaper to produce but somewhat less efficient than single-crystal silicon. A simple silicon solar cell can power a watch or calculator. However, it produces only a tiny amount of electricity. Connected together, solar cells form modules that can generate substantial amounts of power. Modules are the building blocks of solar electric systems, which can produce enough power for a house, a rural medical clinic, or an entire village. Large arrays of solar electric modules can power satellites or provide electricity for utilities. Solar Electric Power System Components In addition to modules, several components are needed to complete a solar electric power system. Many systems include batteries, battery chargers, a backup generator, and a controller so that people in solar-powered homes and buildings can turn on the lights at night or run televisions or appliances on cloudy days. Grid-connected systems don't require batteries or backup generators because they use the grid for backup power. Some remote system applications, such as those used to pump water, do not require a backup power source. Components of a typical standalone PV system using crystalline silicon technology. (Source: Solar Electric Power Association) Solar electric power systems can incorporate inverters or power control units to transform the DC electricity produced by the solar cells into alternating current (AC) to run AC appliances or sell to a utility grid. Complete systems usually include safety disconnects, fuses, and a grounding circuit as well. Thin Films Solar electric thin films are lighter, more resilient, and easier to manufacture than crystalline silicon modules. The best-developed thin-film technology uses amorphous silicon, in which the atoms are not arranged in any particular order as they would be in a crystal. An amorphous silicon film only one micron thick can absorb 90% of the usable solar energy falling on it. Other thin-film materials include cadmium telluride and copper indium diselenide. Substantial cost savings are possible with this technology because thin films require relatively little semiconductor materials. Thin films are produced as large, complete modules, not as individual cells that must be mounted in frames and wired together. They are manufactured by applying extremely thin layers of semiconductor material to a low-cost backing such as glass or plastic. Electrical contacts, antireflective coatings, and protective layers are also applied directly to the backing material. Thin films conform to the shape of the backing, a feature that allows them to be used in such innovative products as flexible solar electric roofing shingles. Concentrators Concentrators use optical lenses (similar to plastic magnifying glasses) or mirrors to concentrate the sunlight that falls on a solar cell. With a concentrator to magnify the light intensity, the solar cell produces more electricity. Today, most solar cells in concentrators are made from crystalline silicon. However, materials such as gallium arsenide and gallium indium phosphide are more efficient than silicon in solar electric concentrators and will likely see more use in the future. These materials are now used in communications satellites and other space applications. Concentrators produce more electricity using less of the expensive semiconductor material than other solar electric systems. A basic concentrator unit consists of a lens to focus the light, a solar cell assembly, a housing element, a secondary concentrator to reflect off-center light rays onto the cell, a mechanism to dissipate excess heat, and various contacts and adhesives. The basic unit can be combined into modules of varying sizes and shapes. Concentrators only work with direct sunlight and operate most effectively in sunny, dry climates. They must be used with tracking systems to keep them pointed toward the sun. Thermophotovoltaics Thermophotovoltaic (TPV) devices convert heat into electricity in much the same way that other PV devices convert light into electricity. The difference is that TPV technology uses semiconductors "tuned" to the longer-wavelength, invisible infrared radiation emitted by warm objects. This technology is cleaner, quieter, and simpler than conventional power generation using steam turbines and generators. TPV converters are relatively maintenance-free because they contain no moving parts. In addition to using solar energy, they can convert heat from any high-temperature heat source, including combustion of a fuel such as natural gas or propane, into electricity. TPV converters produce virtually no carbon monoxide and few emissions. They may be used in the future in gas furnaces that generate their own electricity for self-ignition (during power outages) and in portable generators and battery chargers. Advantages Solar electric systems offer many advantages. Standalone systems can eliminate the need to build expensive new power lines to remote locations. For rural and remote applications, solar electricity can cost less than any other means of producing electricity. Solar electric systems can also connect to existing power lines to boost electricity output during times of high demand such as on hot, sunny days when air conditioners are on. Solar electric systems are flexible. Solar electric modules can stand on the ground or be mounted on rooftops. They can also be built into glass skylights and walls. They can be made to look like roof shingles and can even come equipped with devices to turn their DC output into the same AC utilities deliver to wall sockets. These advances mean individual homeowners and businesses can relieve pressure on local utilities struggling to meet the increasing demand for electricity. More than 30 states offer grid-connected solar electric system owners the chance to save money on their energy bills by feeding any excess power their solar electric system produces into the utility grid—an arrangement called net metering. Solar power systems require minimal maintenance. They run quietly and efficiently without polluting. They are easy to combine with other types of electric generators such as wind, hydro, or natural gas turbines. They can charge batteries to make solar electricity continuously available. For utilities, large-scale solar electric power plants can help meet demand for new power generation, especially in distributed applications. A solar electric power plant is created from multiple arrays that are interconnected electronically. Solar electric plants are easier to site and are quicker to build than conventional power plants. They are also easy to expand incrementally—by adding more modules—as power demand increases. Solar electric power systems are good for the environment. When solar electric technologies displace fossil fuels for pumping water, lighting homes, or running appliances, they reduce the greenhouse gases and pollutants emitted into the atmosphere. The use of solar electric systems is particularly important in developing nations because it can help avert the expected increases in emissions of greenhouse gases caused by the growing demand for electricity in those countries. Solar electric technologies also benefit the U.S. economy by creating jobs in U.S. companies. Exporting solar electric technologies to developing nations expands U.S. markets while protecting the global environment. Disadvantages Although solar electric systems make financial sense in remote areas that lack access to power lines, they are usually more expensive than fossil fuels for grid-connected applications. This disadvantage is significant for utilities considering large-scale solar electric power plants. Although solar electricity costs considerably more than electricity generated by conventional plants, regulatory agencies often require utilities to supply electricity for the lowest cash cost. Utilities view solar electric power plants differently than they view conventional power plants. Solar electric modules produce electricity intermittently—only when the sun shines. Their output varies with the weather and disappears altogether at night. Integrating solar electricity into a utility system requires creative planning. Applications A combination of solar electric arrays and pool-heating solar collectors were used to provide power and heat to the Georgia Tech University Aquatic Center, site of the 1996 Olympic swimming competition. (Credit: Heliocol) Solar electricity has powered satellites since the dawn of the space program. It has run remote communications outposts high in the mountains and turned on the lights, kept medicines cold, and pumped water in rural areas for more than 30 years. Small solar cells are used to power wristwatches, calculators, and other electronic gadgets. More recently, solar electric systems have been used to provide supplemental power to homes and commercial buildings in cities. Solar electric technology has important roles to play in both the developing and developed worlds. From the farmer irrigating his crops in rural Mexico to an innovative lighting system for an Olympic sports arena, solar electric solutions abound. Electric utilities harness solar electricity for distributed applications—near substations or at the end of overloaded power lines, for example, to avoid or defer costly line upgrades. They use solar electricity during hot, sunny periods when the demand for air conditioning stretches conventional power generation to its limit. The Sacramento Municipal Utility District, for example, uses large solar electric arrays as part of its power generation mix. Utilities also rely on solar electricity to power remote, standalone monitoring systems. Consumers and builders are integrating solar electric modules into their homes and offices. Innovative solar electric technologies can replace conventional roofing and facade materials in new buildings. Solar electric roofing shingles, for example, are being used in some new residences. In grid-connected applications, solar electricity supplies some of a consumer's energy needs; the local utility provides the rest. Standalone solar electric systems power a variety of applications far from the reaches of the power grid. These applications include remote communications systems such as television and radio transmitters and receivers, telephone systems, and microwave repeaters. Standalone solar electric power is also used to prevent corrosion of metal pipes, tanks, bridges, and buildings. Many remote residences worldwide use solar electricity as their source of power. For instance, more than 100,000 vacation homes in Scandinavia rely solely on solar electric technology to run lights and appliances. Villages around the world are building solar electric systems to bring electricity to their homes and local industries, often for the first time. To make the maximum use of available resources, village power is typically produced by a hybrid power system that combines solar electricity with diesel backup generators and sometimes another renewable energy technology such wind power. Villages also use standalone solar electric systems for pumping water—an application shared by rural farmers and ranchers in the United States.

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How we make and distribute electricity is changing! 

The electric power generation, transmission and distribution system (the electric "grid") is changing and evolving from the electric grid of the 19th and 20th centuries, which was inefficient, highly-polluting, very expensive and “dumb.”  

The "old" way of generating and distributing energy resembles this slide:

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Monty Goodell, MBA
Founder and Chairman
Renewable Energy Institute

The Renewable Energy Institute (REI) does not take a stand in the debate on global warming, and if there is global warming, is it "anthropogenic" or is it caused by the sun, or the sun's normal cycles.  Or, if there is " climate change," is it "global cooling" caused by the water vapor in the atmosphere? The stand we take is that we need to invest in renewable energy technologies, producing clean, renewable energy that doesn't pollute the planet, and end America's addiction to crude oil from foreign countries where we now spend OVER $1 Billion/day, to buy the oil we need, and some of those suppliers (muslims in foreign countries) take our dollars and make bombs and bullets and send our boys back in body bags. We need to stop this, and put American's back to work, generating "green power and energy" right here at home.

At the Renewable Energy Institute, we are waiting for the "true" scientists who doing the real research, to provide us with the science and answers critically needed to formulate correct policy - and not the phony " scientists" who are following politically-motivated and profit-driven agendas of the United Nations and government leaders. These phony scientists are not interested in conducting real scientific research.  Their very livelihoods are dependent on the government grants to fund their phony research that have pre-determined conclusions before and "research" is conducted.  

Political-interference by governments, governmental agencies, and bureaucrats that hand out billions of tax-payers dollars to phony scientists to conduct "junk science" and research,  expect the conclusions that supports anthropogenic global warming, or climate change. 

When scientists conclude in their research that they find no evidence of anthropogenic climate change or global warming, they are summarily dismissed, and black-balled from their communities and colleagues, and never again receive funding or grants.  Grants and funding by government bureaucrats with politically-driven agendas to "scientists" expecting their pre-determined results and conclusions supporting anthropogenic global warming must stop.

According to the International Energy Agency (IEA), in 2007

• the solar industry received $198 million in subsidies.

• the oil and natural gas industry collected $2.1 Billion in tax-payer subsidies.

• the coal industry coal received $3.2 Billion in tax-payer subsidies.

And since 1960:

• the nuclear industry has received nearly $70 billion in tax-payer incentives and tax-payer subsidies. 

Taxpayers have bankrolled the oil and gas industry, and the coal industry for 100 years now, and the nuclear industry for 50 years, to keep these dirty fuels and energy "cheap." Take away the tax-payer incentives and tax dollars, and we believe the real cost of gasoline, would be similar to the gasoline cost in Europe - $7.00 - $8.00/gallon!

In the meantime, our U.S. Military is spending billions of tax-payer dollars each year protecting the Straits of Hormuz where much of the world's crude oil is produced and shipped through the straits' international shipping lanes.  Each day, hundreds of "very large crude carriers" pass through the Straits of Hormuz carrying oil from OPEC and the Middle-East to the U.S. and many other countries. 

Isn't it time we take some of the tax-payer dollars supporting the nuclear, coal and oil and gas industries, and start incentivizing clean, renewable energy technologies that don't pollute or harm the environment in any way?  Isn't it time that America ends its reliance on non-sustainable energy sources and stop over $1 billion every day, to oil suppliers from foreign countries, and start putting this money in "solar on every rooftop?!?

Mercury Emissions from Coal Fired Power Plants Far More Harmful to the Planet and People than Greenhouse Gas Emissions

Regarding the harm being caused to our planet from energy use, far more harm is being done to the planet, as well as to people and plants and animals, particularly fish, from the mercury emissions from coal fired power plants than from the coal fired power plants' greenhouse gas emissions.  We surmise that if any polar bears have died as a result of an environmental problem, it was more likely from the high levels of mercury in their food chain, than from greenhouse gas emissions. 

The Renewable Energy Institute is supporting and advancing renewable energy technologies, as well as reducing and eliminating greenhouse gas emissions and the fossil-fuel problems related to America's oil addiction and ending our dependence on foreign oil.  The renewable energy technologies we support are already deemed to be economic, viable and practical. Solutions such as Solar Trigeneration energy systems (see www.SolarTrigeneration.com for more information) for any kind of facility or building - office buildings, shopping centers, data centers, university campuses, etc. 

Since 2003, a Solar Trigeneration energy system has been providing 100% of the power and energy for a 5,300 sq. ft. office building near downtown Los Angeles, and doing so without any connection to the electric grid, whether its 12 noon or 12 midnite!  

The Renewable Energy Institute is also involved in research and advocacy of "Net Zero Energy" (see: www.NetZeroEnergy.com for more information) and "Net Zero Energy Buildings" (see:  www.NetZeroEnergyBuildings.com for more information).  Net Zero Energy Buildings generate as much (or more) energy than they use, and export their excess power to the grid, which we believe needs to be updated into a "Transmission Superhighway."

Climate Change, Global Warming or Global Cooling?

The past 10 years indicates the opposite of "global warming" has occurred - that the "Earths Fever" has and that global cooling has taken place. 

Weather, on a daily basis, or even an annual basis, is not climate, and climate is not weather. 

"Climate change" is always taking place, from one day to the next, and one week to the next, as well as one year to the next. The planet's climate is an ever-evolving, changing and dynamic process.  

Again, researchers and scientists need to refrain from being political, and stay out of politics, and politicians need to stay out of the way of the scientists and researchers, and let them do their work.  Politicians, government leaders and bureaucrats scientists need true and accurate data and climate research from scientists that do not have a political agenda.

In the meantime, as there may still be 30 years of research before there are conclusive answers concerning anthropogenic climate change, can we "risk" 30 years of our children and grand children's future, should there is a link between climate change and greenhouse gas emissions?  Should we not err on the side of caution?

Hubbert's Peak Oil Predictions Now Proving True?

Marion King Hubbert was a geologist and scientist who worked at Shell Oil company's research lab in Houston, Texas.  Hubbert made several important contributions to geology, geophysics and petroleum geology.  Hubbert is most recognized for the "Hubbert Curve" and " Hubbert Peak Theory" which is now referred to as " Peak Oil. 

Hubbert's life work determined that the world has a finite amount of petroleum that can be produced.  (Similarly, there is a finite amount of coal.) Many scientists and engineers believe we have reached Hubbert's "peak oil" limit.  Hubbert's espouses that when 50% of domestic crude oil production has been reached, that there will be such significant upward demand on prices of the limited supplies of oil production, that the U.S. economy will experience severe economic, social, and political turmoil.

Hubbert's Peak Oil predictions have proven to be true and this is validated as the U.S. in the early 1970's produced about 60% of its' oil demand and imported 40%.  That equation has flipped since then, because our domestic oil production has been on the decline since 1970, so now, due to our declining domestic oil production, we have to import 60% of our oil supplies, to meet our country's oil/energy demands.

The Next Oil Shock Could be the "mother" of All Oil Shocks

How severe our economic calamity and next "oil shock" will depend upon a number of factors, including when this occurs, as well as the following:

1.  the dependence of the individual country upon its own crude oil production to meet its energy needs and to subsidize consumer imports; 

2.  the rate of relative decline in crude oil production; 

3.  the degree of difficulty encountered in replacing missing energy inputs; 

4.  the degree to which our country had prepared in advance for this inevitable geological and economic calamity.

Examples of past "oil shocks" and the economic and political calamities that followed:

United States: Our peak crude oil production of domestic oil occurred in 1970; the first "oil shock" and oil crisis followed in 1973 with the Arab/OPEC Oil Embargo.

Iran: Their peak crude oil production occurred in 1974; They had their islamic revolution 1979 that overturned government and replaced it with radical islam.

Soviet Union: Their peak crude oil production was in 1989; what happened next? 
Their country disintegrated and the collapse of the Soviet Union followed in 1991. 

Indonesia: Their peak crude oil production was in 1991; their financial and government crisis followed in 1997.

Iraq: Iraq's crude oil production was in 1989; they then invaded Kuwait (for their oil) in 1991.

Using Mr. Hubbert's predictions, that beginning around 2000  we would see peak (global) oil production, then, if the country's not weaning themselves off of their oil addiction, and had not begun making the switch to renewable energy, that the negative economic and political calamities would soon follow, including ever-increasing prices of energy that is from fossil fuels. 

Now is the time to begin weaning ourselves off of fossil fuels and making the transition to and increasing the use of renewable energy. If you don't believe in climate change, or global warming, GREAT! Join us in the switch to renewable energy and a fossil-free economy!

America's Clear and Present Danger"

America Has INCREASED its' Dependence on Foreign 
Sources of Energy by 50% Since 1973.

America is even more "addicted" to foreign oil today, than we were in 1973 - 1974 when OPEC, Saudi Arabia and other suppliers from the Middle-East  stopped selling us their fossil fuels, and created a significant blow to our economy.

According to Monty Goodell, Founder and Chairman of the Renewable Energy Institute, "our increased dependence and reliance on foreign energy supplies represents a Clear and Present Danger to our national security, our economy, and the lives and livelihood of every American. Energy - including the energy we use from imported fossil fuels, is the very "lifeblood" of the American economy as it is for every industrialized country.  An economy dies without it's lifeblood of energy. This Clear and Present Danger we face is far more serious than the problems related to greenhouse gas emissions.  And while greenhouse gas emissions are very serious issue, in the long-term, pales in comparison to America's vital national security interests and America's economic stability in the short term.  For this reason alone, America needs to transition away from its addiction to foreign energy supplies. And America's abundant renewable energy resources such as the energy we receive from the sun, and renewable energy technologies such as concentrated solar power (CSP) plants - can supply 100% of America's power requirements with a concentrating solar power plant measuring 75 miles by 75 miles, located in the Southwest U.S.  By generating America's power from concentrating solar power plants, America resolves its' short-term Clear and Present Danger as it relates to importing its energy from foreign countries, and the long-term problems relating to greenhouse gas emissions."

Continuing, Mr. Goodell states that "too many Americans have forgotten what happened to us in 1973, when the Arabs and OPEC brought the United States economy to a screeching halt during the OPEC Oil Embargo.  This happened because they (mainly the country of Saudi Arabia) disagreed with our foreign policy and is the reason why they "turned off the tap" of our need for their oil supplies. When Saudi Arabia and OPEC stopped the vital flow of oil to our country in 1973, they caused an "oil shock" that severely and negatively impacted our economy. 

Mr. Goodell's question for us to ponder is, "do these countries who sell us 60% of our daily energy requirements, like us and our foreign policy, or might they leverage our addiction to their fossil fuels, and turn off the tap to make us adjust or revise our foreign policy??  Like any addict, America's foreign policy may be held hostage to its addiction, and in this case, our addiction to foreign oil, may over-ride our national interests."

Have American's forgotten the gas shortages and long lines at 
their gas stations to get gas during the Arab Oil Embargo of 1973? 

"Apparently so."  Mr. Goodell states that "in 1973, America was 'addicted' and 'over the barrel' of foreign oil to the amount of 40%.  Forty percent of our energy 'needs' in 1973 came from countries - many of which didn't like us then, and I'm afraid, many of them still don't.  The difference between 1973 and today - is that today we receive 50% MORE foreign oil now than we did in 1973.  And now we know about the problems relating to greenhouse gas emissions that we didn't know then.  America needs to change course, and change course now, in terms of its' energy supplies and how we keep America's economy strong, without the threat of being held hostage to a middle-east tyrant or regime, that could once again, turn on us, and turn off our supply of foreign oil." 

Remember ????

"Sadly," Monty Goodell continues, "most Americans have forgotten the long lines of people waiting in their cars - lined up and waiting for gasoline at their nearby gas station, with lines that were many blocks long.  And, after waiting 4-5 hours, many even waiting overnight in many places, to finally take their turn to fill up their car with gasoline, only to find that the gas station had run out of gas." 

"Let me Repeat.... That was 1973 when we imported 40% of our daily energy requirements in the form of crude oil from overseas, and from foreign countries - and many of these from countries that don't like us.

Today, over 35 years later, America has yet to learn the lesson.  We cannot continue our reliance on energy from foreign countries that supply us with 60% of the crude oil that our refineries use as a feedstock for producing gasoline and diesel fuel for our cars and trucks comes from overseas. 

America is "over the barrel" and it's not our barrel, but the barrels of oil that we are addicted by and owned by other countries.  Why have we not learned the lessons we needed to learn in 1973 when we were cut-off from the vital energy supplies we need? 

Countries like China, are growing rapidly, and have an insatiable need for crude oil. China, with their booming economy, is increasingly growing in its clout and control over international supplies of crude oil - whether they do this through their ability to buy as much oil as they need on a daily basis, or whether they simply but American drilling rigs, technology, and explore and produce oil and gas from their own fields. China, is buying large amounts of oil for their country, and causing upward pricing on declining supplies. What happens if Russia, with all of their oil and natural gas, along with China and Venezuela, with or without the help of OPEC, decided to NOT sell oil to us????

To be sure, greenhouse gas emissions are a problem, and to some, greenhouse gas emissions are also a Clear and Present Danger, but not to the extent that it presents an imminent Clear and Present Danger. 

America's reliance for 60% of our energy "needs" coming from foreign suppliers is un-acceptable.

The "driver" to get America to begin reducing and eliminating fossil fuel use should be our nation's national security and the welfare and safety of its citizens. And this can all begin with developing and investing in our own renewable energy resources and renewable energy technologies, let's start by putting solar on every rooftop that has a clear and unobstructed view of the Southern sky. See www.RooftopPV.com  or  www.DistributedPV.com  for more information.  Let's create incentives begin with adopting a national "Feed In Tariff" as Germany did in 1990. 

America, we simply do NOT have the luxury of time on our hands.  We need to end our dependence and reliance on foreign fossil fuels, especially from countries that don't like us! We need to rapidly begin expanding renewable energy resources and renewable energy technologies from our vast and abundant renewable energy resources, such as; solar, solar energy systems, solar cogeneration, solar trigeneration, "solar on every roof," waste to energy, waste to fuel, biomass gasification, B100 Biodiesel, Biomethane, Synthesis Gas, geothermal, E100 Ethanol (from sugar cane and NOT from corn), and wind, where it makes economic sense."   

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