Capstopne's Intepretation of the Stimuls BIl

This is from the Ca[pstone Website



-Editor


Stimulus Package Signed by President Obama On February 17, President Obama signed the American Recovery and Reinvestment Act (H.R.1) into law.



The package contains a number of measures designed to promote clean energy and energy efficiency, many of which could be beneficial to deployment of Capstone’s products and the continued development of our technology. For example, the Stimulus provides:


Grants in lieu of the 10 percent investment tax credit (ITC) on microturbines and combined heat and power (CHP);
$3.2 billion in block grants to states and local governments to spend on energy efficiency and $3,1 billion to fund state energy programs;
$16.8 billion in funding for DOE to fund Research and Development of clean energy and efficiency technologies, among other programs;
Bonus depreciation of capital equipment;
$11 billion to fund clean energy and energy efficiency upgrades at federal buildings.




The following summary contains more details on the individual energy provisions in the Stimulus package that could be beneficial to Capstone’s business.


Overview of Energy Provisions in the Stimulus Bill

• Clean Energy Grants: Purchasers of microturbines and CHP systems can now elect to receive grants in lieu of the ITC for projects placed in service during 2009 and 2010 (or after 2010 if commenced in 2009-2010).


• The Act also allows facilities included in Section 45 (biomass, biodiesel, landfill gas, et al) to take a 30 percent refundable ITC in lieu of the Production Tax Credit (PTC) for projects placed in service on or before 2013.


• Energy Efficiency and Conservation Block Grants: Appropriates $3.2 billion for Energy Efficiency and Conservation Block Grants as authorized in the Energy Independence and Security Act of 2007. This funding goes to state and local governments to make investments in energy efficiency, including the application and implementation of energy distribution technologies that significantly increase energy efficiency.
  Repeals Penalty for Financing Section 48 Technologies (Microturbines and CHP, et al): Allows businesses and individuals to qualify for the full amount of the tax credit, even if projects are financed with local development bonds or other subsidized energy financing.
  


• Green and Efficient Federal Buildings: The Act includes $5.5 billion to be deposited into the Federal Buildings Fund for expenditures to construct, repair and make alterations on federal buildings to increase energy efficiency, including installing solar energy equipment. In addition, $4.5 billion is available for measures necessary to convert Government Services Administration facilities to green buildings. The act also provides $1 billion for non-recurring maintenance on Veterans Affairs medical facilities, including energy projects.


• State Energy Program: $3.1 billion dollars will be made available to the Secretary of Energy to award grants to states. The award of this funding is conditioned upon a notification to the Secretary of Energy by the governor that the state has obtained the necessary assurances to adopt certain utility regulatory polices to encourage utility-sponsored energy efficiency improvements and updated energy efficient building codes. In order to take advantage of existing institutional structures, a state is also encouraged to use federal funds to existing energy efficiency and renewable energy programs.
  Loan Guarantee Program: Establishes a temporary, low-cost loan guarantee program by DOE for renewable energy systems and electric power transmission projects that begin construction by September 30, 2011. The Act makes available $6 billion for use by this program, which is estimated to support more than $60 billion in loans for these projects.
  Manufacturing Investment Credit: Provides a 30 percent investment tax credit for facilities engaged in the manufacture of advanced energy property, including microturbines. Projects must be certified by the Treasury, in consultation with the Secretary of Energy, through competitive bidding. .Extend Bonus Depreciation: Allows businesses to recover 50 percent of the cost of capital investment in the first year in order to spur upfront expenditures in 2009 and 2010.
  Energy Department Funding: Appropriates $16.8 billion to energy efficiency and renewable energy, including $2.5 billion for applied R&D, demonstration and deployment projects. There will be $800 million for projects related to biomass and $400 million for geothermal projects which, according to the U.S. Clean Heat and Power Association, could also include funding for sections 451, 452 and 471 (these provisions were stripped from the House version). These provisions could entail a DOE grant program for CHP projects.
  


• New Clean Renewable Energy Bonds (“New CREBs”): Provides an additional $1.6 billion for local governments and municipalities to finance facilities that generate electricity from renewable energy (biogas, biodiesel, landfill gas, et al) sources.


• Qualified Energy Conservation Bonds: Authorizes $2.4 billion in bonds to finance state, municipal and tribal government programs that reduce greenhouse gas emissions.


• Green Collar Jobs: Appropriates $500 million to fund job training programs in energy efficiency and renewable energy.


• Smart Grid: Provides up to 50 percent reimbursement to electric utilities or other parties that carry out smart‐grid demonstration projects.
  Renewable Energy for Water Treatment Plants: Appropriates $2.4 billion in grants that could be used to put renewable energy in wastewater treatment plants.


• Department of Defense Energy and Efficiency Programs: The act provides $300 million to the DOD for the purpose of research, testing and evaluation of projects to energy generation, transmission and efficiency. The bill provides an additional $100 million for Navy and Marine Corps facilities to fund energy efficiency and alternative energy projects.


• The Defense Health Program will also receive $400 million to invest in energy efficiency projects and to improve, repair and modernize military medical facilities in the United States and its territories. There is also an additional $120 million appropriated for the Energy Conservation Investment Program for military construction defense-wide

Geothermal and Solar Recovery Act Funding - Close but no Cigar

The Administration is trying to publicize funding for Geothermal and Solar Recovery Act Funding projects: So far, it is putting the funds in the hands of government, not business, and these institutions are inceted to make the programs last as long as possible, not to be profitbale. When I Read these Funding Opportunities, it seems to me that 16 of the 18 opportunities are for research and development or demonstrations of technology we already know works.

• Yes, we will learn new things
• Yes, contractors who put up the demonstrations will earn money for the one project; maybe they will even get more contracts.
• Yes Solar manufacturing plants, even thinfilm plants will be built

It is a hit near the target, but sorry sir, no cigar.

Geothermal

A Geothermal mapping program is a good idea, but lets generate some economy NOW by granting energy companies money to build plants in the places we already know they will work, like they Texas Gulf Coast, Northern California. Make them pay the money back over the next 2o years, putting the money back into a fund to pay for the next generation of research.

Then, after the EMS Technology Emerges the geothermal wells can be built there as well. Don't worry, we will need ALL the energy.

Solar

We can't make solar energy cost effective by simply ramping up manufacturing of today's solar panels. PV technology is about to move from the model T to the Ferrari ( or at least the Mustang) stage. We shouldn't ramp up the Model T production line.

What we can do today is give more and better direct-to-consumer incentives for putting the stuff we have out now. The solar industry can then stay alive until the new technology rolls out.

I don't mind buying the Model T today if I can get it cheap. and It will still get me to the store and back in the future, and at least I will learn how to drive a car before the Ferrari gets here.

Let's put the money out there into ongoing, production that will produce energy for 20 years, not into the hands of institutions who are not, by nature, inceted to produce economy.

-Editor

Here is the DOE Article

Recovery Act Announcement: President Obama Announces Over $467 Million in Recovery Act Funding for Geothermal and Solar Energy Projects
May 27, 2009

President Obama today announced over $467 million from the American Reinvestment and Recovery Act to expand and accelerate the development, deployment, and use of geothermal and solar energy throughout the United States.

The funding announced today represents a substantial down payment that will help the solar and geothermal industries overcome technical barriers, demonstrate new technologies, and provide support for clean energy jobs for years to come.

Today's announcement supports the Obama Administration's strategy to increase American economic competiveness, while supporting jobs and moving toward a clean energy economy.
"We have a choice. We can remain the world's leading importer of oil, or we can become the world's leading exporter of clean energy," said President Obama. "We can hand over the jobs of the future to our competitors, or we can confront what they have already recognized as the great opportunity of our time: the nation that leads the world in creating new sources of clean energy will be the nation that leads the 21st century global economy. That's the nation I want America to be."

"We have an ambitious agenda to put millions of people to work by investing in clean energy technology like solar and geothermal energy," Energy Secretary Steven Chu said. "These technologies represent two pieces of a broad energy portfolio that will help us aggressively fight climate change and renew our position as a global leader in clean energy jobs."

Geothermal Energy

Geothermal energy is a clean source of renewable energy that harnesses heat from the Earth for heating applications and electricity generation; geothermal plants can operate around the clock to provide significant uninterrupted "base load" electricity, or the minimum amount a power utility must provide to its customers.

• The Recovery Act makes a $350 million new investment in this technology, dwarfing previous government commitments.

Recovery Act funding will support projects in four crucial areas: geothermal demonstration projects;

1. Enhanced Geothermal Systems (EGS) research and development;
2. innovative exploration techniques;
3. A National Geothermal Data System,
4. Resource Assessment and Classification System.

Geothermal Demonstration Projects ($140 Million)

• Funding will support demonstrations of cutting-edge technologies to advance geothermal energy in new geographic areas, as well as geothermal energy production from oil and natural gas fields, geopressured fields, and low to moderate temperature geothermal resources.

Enhanced Geothermal Systems Technology Research and Development ($80 Million)

• Funding will support research of EGS technology to allow geothermal power generation across the country.
• Conventional geothermal energy systems must be located near easily-accessible geothermal water resources, limiting its nationwide use.
• EGS makes use of available heat resources through engineered reservoirs, which can then be tapped to produce electricity.

While the long-term goal of EGS is to generate cost competitive clean electricity, enabling research and development is needed to demonstrate the technology's readiness in the near-term.

Innovative Exploration Techniques ($100 Million)

• Funding will support projects that include exploration, siting, drilling, and characterization of a series of exploration wells utilizing innovative exploration techniques.
• Exploration of geothermal energy resources can carry a high upfront risk. By investing in and validating innovative exploration technologies and methods, DOE can help reduce the level of upfront risk for the private sector, allowing for increased investment and discovery of new geothermal resources.

National Geothermal Data System, Resource Assessment, and Classification System ($30 Million)

• The long-term success of geothermal energy technologies depends upon a detailed characterization of geothermal energy resources nationwide.
• In 2008, the United States Geological Survey (USGS) conducted an assessment of high temperature resource potential in the Western United States.
• To fully leverage new low-temperature, geopressured, co-production, and EGS technologies, DOE will support a nationwide assessment of geothermal resources, working through the USGS and other partners.
• Second, DOE will support the development of a nationwide data system to make resource data available to academia, researchers, and the private sector.
• Finally, DOE will support the development of a geothermal resource classification system for use in determining site potential.

Solar Energy

• Solar energy is a rapidly expanding industry with a double-digit annual growth rate in the United States. DOE is focused on supporting the U.S. industry's scaling up of manufacturing, production, and distribution so the technology can become cost competitive with conventional sources of energy.
• DOE will provide $117.6 million in Recovery Act funding to accelerate widespread commercialization of clean solar energy technologies across America.
• These activities will leverage partnerships that include DOE's national laboratories, universities, local government, and the private sector, to strengthen the U.S. solar industry and make it a leader in international markets.

Photovoltaic Technology Development ($51.5 Million)

• DOE will expand investment in advanced photovoltaic concepts and high impact technologies, with the aim of making solar energy cost-competitive with conventional sources of electricity and to strengthen the competitiveness and capabilities of domestic manufacturers.

Solar Energy Deployment ($40.5 Million)

• Projects in this area will focus on non-technical barriers to solar energy deployment, including grid connection, market barriers to solar energy adoption in cities, and the shortage of trained solar energy installers.
• Combined with new technology development, these deployment activities will help clear the path for wider adoption of solar energy in residential, commercial, and municipal environments.

Concentrating Solar Power Research and Development ($25.6 Million)

• This work will focus on improving the reliability of concentrating solar power technologies and enhancing the capabilities of DOE National Laboratories to provide test and evaluation support to the solar industry.

For information on these and other Funding Opportunities under the Recovery Act, visit the U.S. Department of Energy's Recovery And Reinvestment Act page on Funding Opportunities.

The Rest from Energy Efficiecny and Renewsbel Energy, Department of Energy ( DOE )

MERCED, Calif. -- A new study suggests converting biomass to electricity rather than ethanol for transportation produces fewer greenhouse gas emissions and offers more “miles per acre.”

Researchers from Stanford University and the University of California, Merced, studied the lifecycle of plant-based electricity, or “bioelectricity,” and ethanol technologies to determine which delivered more miles of transportation with fewer environmental impacts.

They concluded battery-powered vehicles that used electricity derived from biomass provided an average of 80 percent more miles of transportation per crop acre than internal combustion engine vehicles running on ethanol made from corn or switchgrass.

"The internal combustion engine just isn't very efficient, especially when compared to electric vehicles," Co-author Eliott Campbell of U.C. Merced said in a statement last week. "

Even the best ethanol-producing technologies with hybrid vehicles aren't enough to overcome this." A small SUV with an internal combustion engine can travel roughly 9,000 highway miles on the net energy produced from an acre of switchgrass, compared to nearly 14,000 highway miles for a small SUV powered by bioelectricity.

Electric cars fueled by bioelectricity avoid twice as many greenhouse gas emissions as ethanol-powered internal combustion engine vehicles, according to the study.
"We found that converting biomass to electricity rather than ethanol makes the most sense for two policy-relevant issues: transportation and climate," Co-author David Lobell of Stanford's Program on Food Security and the Environment said in a statement.

"But we also need to compare these options for other issues like

• water consumption,
• air pollution
• economic costs."

In addition to Lobell and Campbell, the research team included Chris Field, a Stanford professor and director of the department of global ecology at the Carnegie Institution.

The trio’s study appeared in the May 8 issue of the journal Science.

Source: Greenbiz.com

Onsite Power Purchase Agreements

This is a repost of an great article
By Lindsay Audin from June 2008

-Editor

In an effort to reduce greenhouse gas (GHG) emissions and give their organizations some green credibility, many facility executives are incorporating on- site renewable or high-efficiency sources of power into their operations. Federal income tax credits (available until the end of 2008) and state and utility-sponsored rebates, grants or low-interest loans are lowering the net cost for such on-site systems.

Many facility executive are also purchasing renewable energy credits (RECs) or carbon offsets (also called Verified Emission Reductions, or VERs) that pay others to produce renewable energy elsewhere. Together, these processes help to minimize an organization’s carbon footprint.

Financial incentives and novel contractual arrangements are opening new doors to such options, but finding the right paths may still be a challenge. With the major presidential candidates supporting some form of carbon regulation, many organizations are getting up-to-speed on these renewable energy opportunities to avoid being caught short after the November election.

While improving an organization’s environmental posture is now seen in most boardrooms as a plus, some are realizing that on-site power systems may also help stabilize the future cost of their power. The cost of a customer-owned green power system is limited to the initial capital outlay and ongoing maintenance, and is thus immune to volatile energy pricing.

If a third party owns the on-site green power system, the price of its power may be discounted off that of the utility under a long-term contract, typically called a power purchase agreement (PPA). In such cases, little or no upfront customer investment is involved and bottom-line savings appear from Day One.

What’s a PPA?

The term “PPA” applies to a contractual arrangement wherein a customer buys power from a non-utility supplier. Utilities have PPAs with their wholesale power suppliers, and customers buying power from non-utility suppliers do so through PPAs with retail power marketers. Customers may also have a PPA with a supplier providing power to their facilities from a supplier-owned generator at the customer’s site.

PPAs for both renewable and small-scale cogeneration plants grew rapidly after the California power debacle in 2000-01, with generous funding from both that state and several others.

While power from cogeneration units is not usually considered “green,” unless its energy source is renewable, such as landfill gas, such systems provide power more efficiently by making use of waste heat that is normally discarded during power production. As a result, they may reduce greenhouse gas emissions compared to utility-based power.

Many types of facilities are using PPAs, including

• factories,
• industrial parks,
• institutions,
• big box stores,
• government buildings
• apartment buildings.

With the growth of the LEED rating system, which offers points for renewable energy and higher energy efficiency, the commercial real estate community has also become engaged.

From the customer standpoint, the major selling point of such contracts is that the very high first cost of clean on-site generation, PV panels, for example, is avoided, along with the internal financing hassles that often block facility-related projects.

From the supplier view, once project financing has been obtained, a variety of cash flows and benefits may be tapped, including:

• One-time utility or state grants or rebates
• Federal (and maybe state) tax credits
• Sale of emissions credits
• Revenue from sale of power to customer and utility
• Accelerated depreciation.
• In some cases, the supplier is renting a customer’s roof space and
• producing power provided to the customer but sold to the utility. The
• customer pays the utility the usual amount but receives rent or a discount
• from the supplier, who in turn gets paid by the utility for that power at a higher price than it could charge the customer — in some cases, as high as $.48/kWh. The utility is allowed to spread that extra cost among all ratepayers under a regulatory requirement to buy a certain percentage of the power from renewable sources.
  

Avoiding PPA Pitfalls

While such arrangements hold great promise to increase the market share of renewables, a variety of issues require attention before environmentally responsible power begins to flow.

Some problems may be avoided by having an independent consultant or engineer review both the project and its contract before anything is signed. Because all PPAs are not created equal, facility executives should entertain multiple bids to ensure they are getting a good deal. Some financial matters, like sharing of grants or rebates, may be negotiable.

Still, there are other issues for facility executives to consider.

Here are some concerns expressed by those who are considering a PPA:

• Equipment operations and expectations: Power supply may be intermittent, so savings may vary or be less than expected.
• Such systems operate in parallel with utility power so the lights will stay on, but cash flow may “flicker.”
• Project development and execution: Much more may be involved than merely signing a contract. For example, roof repairs or other upgrades may be needed, which are not part of the deal.
• Impacts on the facility and its energy rates: Depending on the type of system, changes to some facility operations may become problematic.
• Utility rates for power still purchased from the local power company may also change.

A California school district recently suspended its efforts to install solar power panels after its electric bills rose. The problem was related to how the local utility calculated rates for large energy users installing such equipment, and an inexperienced contractor who apparently did not understand the tariff.

• Interaction with other power contracts: Where retail electricity is deregulated, some PPAs require that the on-site power supplier be given a say in how the customer buys the rest of its power so that it cannot benefit in ways that control or reduce the on-site supplier’s revenue.
• Some customers balked at the idea of signing a 20-year contract.
  Calculation of rent or savings: While $100,000 in annual rent or a 10 percent discount may initially sound good, the devil may be in the contractual details. A $100,000 fixed annual rent in Year 1 (at present inflation rates) probably won’t be worth $35,000 (in today’s dollars) in Year 20.
• A 10 percent discount may not produce 10 percent savings. The price of power under the PPA may be discounted from a bundled utility electric rate that includes peak demand. The assumption is that the on-site power will reduce utility demand charges, but that may not be the case — for example, with a combined heat and power plant that runs sporadically. If that situation occurs, the facility pays the demand charge to the utility in addition to the contractually specified amount, which includes the demand charge, to the on-site power supplier.
• Termination conditions: If a system fails and must be removed, or the customer sells the building. Such issues should be clearly spelled out in the contract.

Financial backing: More than 30 companies have offered PPAs for on-site power, but many have already gone out of business.

Insurance and bonding may involve major up-front payments for larger systems, and some smaller suppliers have lacked the financial strength to secure such up-front capital, causing projects to falter.

• Credit rating: A customer’s credit and bill payment track record must be good enough to make a lender confident that the customer can handle a 20-year power contract.
• Even owning the building may not be enough to satisfy lenders in some cases.
• Changing technology: While PV power has been around for decades, some aspects of it as applied to buildings are still developing. Some panels and ancillary systems, such as microinverters, either lack the UL label or a track record long enough to pass a lender’s muster. That makes issues of warranty and guarantee iffy. A state-of-the-art design may not elicit a lender’s money on the table.
• Project timing: If things don’t move forward quickly, incentives or tax credits could expire and financing be lost.

The bottom line is that before signing, the deal should be reviewed by a consultant or engineer with experience in handling power contracts and vetting of power suppliers.

RECs and Offsets

Using renewable energy to mitigate one’s GHG emissions need not involve on-site power production. Firms who lease space or don’t want to invest in hardware, may instead buy RECs — also called ‘green tags’ — or carbon offsets.

RECs cover the cost of displacing power generated by fossil fuels with solar, wind, or other renewable power sources. Offsets pay for net reductions in GHG through a variety of methods.

As with the purchase of retail power, all generated electricity goes into the pool. It is therefore not possible to claim that the kWh generated by a distant wind turbine is actually flowing to the busbar of the firm that purchased it.

The end result of buying a REC, however, is that green power is indeed being injected into the pool so that less fossil fuel power is needed to meet the pool-wide load.

While purchasing RECs or offsets will not yield immediate savings, purchasing such credits at today’s prices may provide a hedge against higher REC pricing down the road.

If new regulations require that others, such as utilities or governmental facilities, begin purchasing them, competition is likely to raise their price, a phenomenon already occurring in some areas.

Until GHG reductions become mandatory, RECs and offsets should be seen as voluntary investments in projects that reduce GHG. A variety of firms and organizations act as intermediaries between such projects and customers wishing to support them.

Facilities seeking to become carbon neutral may purchase RECs to balance their use of fossil-fueled electricity, and enough offsets to negate their on-site use of fossil fuels — gasoline used in employee commuting, for example.

The process starts by performing a GHG inventory to determine the quantity of offsets needed to achieve neutrality.

Software or online calculators are available to convert all forms of GHG emissions into their equivalent tons of carbon.

REC and Offset Pricing

RECs are priced in dollars per megawatt-hour and reflect the added environmental value of renewable power over fossil-fueled power (e.g., 2 cents per kWh).

When buying green power, they reflect the differential in cost compared to fossil-based power.

Offsets are priced in dollars per metric ton (2,205 pounds) of avoided carbon dioxide. Unlike a REC, a carbon offset need not represent production of useful renewable energy.

Some offsets work by exchanging one GHG for another: burning methane that would normally leak from a landfill still generates carbon dioxide, but the methane that would have otherwise entered the atmosphere is 20 times more potent, so the overall carbon impact is reduced by about 95 percent.

Pricing of both RECs and offsets is market-based. It has recently become more volatile. Unlike much of the rest of the developed world, the U.S. has no national requirement for businesses to cut carbon emissions.

Because purchases are voluntary, pricing is relatively low.

• Offsets have recently been sold in the U.S. for $5 to $7 per ton.

Pricing in Canada, a signatory to the Kyoto Protocol, has been over US$25 a ton.

To avoid volatility, and perhaps buy while the market is low, some firms seeking to become carbon neutral are making long-term purchases.

Doing so may avoid price jumps if a federal carbon reduction law is enacted. Consider: For comparison purposes, an offset price of $25 per metric ton is roughly equivalent to an increase in fuel oil pricing of about $.30 a gallon.

Another reason behind price volatility is the entry of uncertified offsets that may be offered at startlingly low prices.

Questions have been raised about the reality of their claimed GHG reductions. Some RECs have also been criticized as merely improving the profitability of existing renewable systems like wind farms instead of increasing their capacity and output.

Where RECs are regulated, in states in which utilities are required to buy them, for example, their “additionality” — ability to increase total renewable energy output — is supposed to be verified.

• Because renewable power systems are growing rapidly, however, some RECs purchased today may not result in generation of new green power for up to 18 months.

Failure to eventually do so would involve breach of contract and possible financial damages against the power developer.

For More Information

The Green Power Market Development Group, a project of the non-profit World Resources Institute, helps firms purchase green power through guidance documents that include sample RFPs and contracts.

DOE’s Green Power Network is also helpful. EPA’s Green Power Partnership is a good start for those seeking both the basics of buying green power and recognition for doing so.

The Chicago Climate Exchange, supports trading (buying and selling) of RECs and offsets as commodities.

Carbon calculators.

• For finding out how to determine if an offset program is credible, check out Clean Air–Cool Planet's, Consumers Guide to Carbon Offsets (pdf).
• For a good example of how a company touts its carbon neutrality, see HSBC Bank’s carbon neutrality brochure (pdf).
• Independent certification programs exist for RECs and offsets. Green-e covers RECs, while the top international gauge for carbon offsets is The Gold Standard.
• Don’t be surprised to find the pricing a bit higher for such well-rated renewables.

Lindsay Audin, CEM, LEED AP, is president of EnergyWiz, an energy consulting firm based in Croton, N.Y. He is a contributing editor for Building Operating Management.

The Rest From Facilites Net