Wednesday, March 21, 2007

SUNSLATES AND COMPANIES WHO INSTALL THEM




Hello Cape Codders! The reason for this site is to connect folks to the sun.

If we are to be actively seeking ways of energy self-sufficiency we will attempt to exchange information from the latest sources on solar technology.

This peaceful approach seeks to eliminate wars for oil. Renewable Energy shall be the saving grace economies by the Greening of Cape Cod. From our homes, schools, work places, and beyond.



Here is a Cape Cod Salt box with Sun Slates manufactured by Atlantis Energy

Another Hybrid PV setting in New Hampshire!


A Hybrid SUNSLATES/DSS Thermal slide show done by my old friend Joe Morriseey, National Sales Director for Atlantis Energy Company

Tuesday, March 20, 2007

GREEN ENERGY BUILDINGS OVERVIEW


Green Buildings Overview

Green buildings conserve the earth's natural resources through the efficient and intelligent use of energy, materials, water, and the building site. They provide their occupants with comfortable surroundings and healthy indoor environments. When clean energy technologies are incorporated into green buildings, the environmental benefits are even greater.


What are green buildings and why are they important?

A green building is a building that has been constructed or renovated to incorporate design techniques, technologies, and materials that lessen its dependence on fossil fuels and minimize its overall negative environmental impact. Among these reduced impacts are minimal site disruption, lower water consumption, and fewer pollutants released during construction and occupation. Green buildings can be homes, offices, schools, hospitals, and other buildings.

The term “high-performance building” is often used when referring specifically to the energy efficiency and productivity benefits of a building, whereas “green building” refers to the broader environmental considerations of a building, including high-performance aspects. “Green building” will be used here to describe a building with minimal site disruption that is energy-, water-, and resource-efficient; and has good indoor air quality, natural lighting, and acoustics, among other benefits.

One of the greatest benefits of green buildings is their reduced use of electricity and energy, which helps reduce our dependence on fossil fuels. About one-third of all energy consumed in the U.S. is used for heating, cooling, lighting, and appliances in buildings.1 An increase in the adoption of green building practices could potentially reduce this energy consumption significantly. While energy savings in individual green buildings vary widely, a set of Massachusetts projects shows green buildings using 30% less energy than buildings constructed to code.

Additionally, because green buildings are constructed with lower-toxicity materials than regular buildings, occupants of green buildings enjoy healthier indoor environments and higher productivity levels. For more information, see Benefits and Barriers.

How does the green building process work to achieve environmentally-friendly end-results?

Green buildings achieve the best results when they are developed through an integrated design and construction process that ideally begins in the pre-design phase when project goals are set. In this approach, all members of the building team are engaged in the green building elements of the project and work to maximize efficiency throughout different development phases. This integrated process can make a significant difference in the environmental and economic success of a green building project.

Green buildings use a variety of features to reduce their impacts on the environment. These features can broadly be categorized as follows:

Energy Efficiency: Building structures, mechanical and electric systems, heating, and lighting that use minimal energy while providing the same comfort levels as conventional energy systems.

Water Efficiency: Water fixtures, reuse techniques, and other measures that reduce water use while providing the service expected by occupants.

Site Use: Minimization of land used for a building, location near public transportation, erosion prevention, and other techniques that reduce impacts on surrounding land.

Material Use: Recycled, easily regenerated, or efficiently produced materials and building techniques that minimize the materials required for a building.

Indoor Environmental Quality: Use of non-toxic materials, good ventilation, daylighting, and other improvements to the indoor environment that increase occupants’ comfort and productivity.

See Green Building Process and Elements for more information on the integrated design process and elements of green buildings.

Why should people consider building green?

Building green has tangible financial, social, and environmental benefits. The upfront costs of green buildings have been coming down rapidly as more designers and builders gain experience with green design. While today’s upfront costs of building green remain slightly higher on average than standard building costs, these costs are offset by the building’s lifetime operating cost savings. The health and productivity benefits of green buildings for residents, students, and employees are more difficult to quantify financially, but numerous studies show that these benefits are important to consider and projections of cost savings are significant. Environmentally, green buildings reduce usage of their communities’ natural resources and decrease strain on the local energy and water infrastructure. For more information on green building considerations, see Benefits and Barriers.

Where can I find information on green buildings in Massachusetts?

There are a number of resources on Massachusetts green buildings, including Massachusetts Technology Collaborative programs, information from the state government, maps of green building locations in Massachusetts, and a listing of buildings that are certified through the Leadership in Energy and Environmental Design (LEED) rating system of the U.S. Green Building Council. For links to these resources and more, see Green Building in Massachusetts.

What can I do?

There are many ways to get involved in a green building project, whether you are an owner, community member, designer, engineer, or other building team member. To learn how to plan and design a green building, incorporate elements of green building into an existing building, or assess costs and benefits, visit the How to Get Involved section.



Source:
http://www.masstech.org/RenewableEnergy/small_renewables.htm

Massachusetts Renewable Energy Tax Incentives

Note: See below for similar information on federal incentives.

The commonwealth of Massachusetts offers a number of tax incentives that are designed to promote the development and use of renewable energy resources. This is a brief summary of those incentives. This summary is not intended to replace consultations with your lawyer, tax preparer or the Department of Revenue who can provide a complete explanation of these incentives and their availability.

  1. State Income Tax Credit

    Massachusetts provides an income tax credit for individuals who install renewable energy systems (solar or wind-powered) in their residences. The credit is 15% of the net expenditure (including installation) for the system, or $1,000, whichever is less. The credit does not apply to commercial users (M.G.L. C. 62, sec. 6(d)).

    For Additional Information: Click here for the ( for 2005) Massachusetts Tax Form Schedule EC.

  2. State Sales Tax Exemption

    State law exempts from the state sales tax, the sale of equipment directly relating to any solar, wind, or heat pump system to be used as a primary or auxiliary power system for heating or otherwise supplying the energy needs of a person's principal residence in the state. [The exemption does not apply to commercial users (M.G.L. c. 64H, sec. 6(dd).)]

    Click here for the Massachusetts Tax Form ST-12.

  3. Local Property Tax Exemption

    A taxpayer who installs a solar or wind-powered system for heating or otherwise supplying the energy needs of his/her residence or business is eligible for an exemption from local property tax. The exemption is good for twenty years from the date of installation. (M.G.L. ch. 59, sec. 5, cl. 45).

    Please note that this exemption applies to the value-added to the property by the system and is not an exemption for the full amount of the property tax bill.

  4. Corporate Income Tax Deduction

    A business which purchases a qualifying solar or wind-powered "climatic control unit" or "water heating unit" is allowed to deduct from its net income, for state tax purposes, any costs incurred from installing the unit, provided the installation is located in Massachusetts and is used exclusively in the trade or business of the corporation (M.G.L. c.63, sec. 38H.).

    Please note that if you qualify for this deduction you may also qualify for the excise tax benefit described in M.G.L. c.63, sec. 38H(f).

  5. Alternative Energy and Energy Conservation Patent Deduction (Personal and Corporate)

    Any Massachusetts resident who has applied for, or holds a patent for an alternative energy or energy conservation system or device, may petition the Commissioner of Energy Resources for determination that such patent is "....of economic value, practicable, and necessary for the convenience and welfare of the Commonwealth." If the Commissioner approves such a patent, any income received from the sale, lease or other transfer of such patent, including royalty income, and any sale, lease or other transfer of property or materials manufactured in the Commonwealth subject to such patent, shall be deducted from state personal income tax or corporate excise tax. Said deduction shall extend for a period no longer than five years from the date of issuance of the U.S. patent or the date of approval by the Commissioner of Energy Resources, whichever expires first (M.G.L. c.62, sec. 2(a)(2)(G), and c.63, sec.30 (3)).

  6. Hydropower-Property Tax Exemption

    Hydropower facilities are exempt from local property tax for a period of twenty years from the date of completion of the construction of such facility, if construction of the facility commences after January 1, 1979. To qualify for this exemption, the owner of the plant must agree to pay the host community at least 5% of the plants gross income for the preceding calendar year in lieu of taxes.

    The exemption applies to all real property (land and buildings) and tangible property (turbines and other equipment) necessary for the production of hydropower (M.G.L. ch.59, sec. 5, cl. (45A)).

For further information, contact:

Department of Revenue
P.O. Box 701
Boston, MA 02204
800-392-6089
- or - Division of Energy Resources
Legal Department
100 Cambridge St., Suite 1020
Boston, MA 02114
617-727-4732
E-mail: DOER.Energy@State.MA.US

Federal Renewable Energy Incentives

Note: See above for similar information on Massachusetts state incentives.

The federal government offers a number of tax and other financial incentives that are designed to promote the development and use of renewable energy resources. This is a brief summary of those incentives. This summary is not intended to replace consultations with your lawyer, tax preparer or the Internal Revenue Service who can provide a complete explanation of these incentives and their availability.

Federal Financial and Tax Incentives for Homeowners

As of December 2001, there were no federal income tax incentives for homeowners who purchase renewable energy equipment. However, rebates from electric utilities for residential solar systems are exempt from federal taxation. Also, special mortgage provisions may be secured from federal HUD, Freddie Mac, and Fannie Mae for solar water heating and photovoltaic systems. Please check with these lenders for details.

Federal Financial and Tax Incentives for Businesses, Municipal Entities, and Not-for-Profit Entities

At the federal level, numerous tax incentives, deductions, and credits are available to businesses, municipalities and not-for-profit entities. Special financing arrangements and mortgages are offered by some federal agencies to help finance the cost of renewable energy systems. Owners or lessees of renewable energy property may be also be entitled to special depreciation rates as well as special treatment of taxes on bonds and leases.

Below is a partial list intended for use as a general overview and introduction. Please consult with a tax professional or the responsible government agency for more information.

  1. Production Tax Credit

    Recently extended through 2004, residential and business generators of renewable power may be entitled to a credit of 1.5 cents per kWh of energy produced by qualified sources, including new wind, closed-loop biomass, and poultry waste facilities. See 26 USC section 45.

  2. Modified Accelerated Cost Recovery System

    Section 168 (e)(3)(b)of the Internal Revenue Code provides a specific depreciation deduction for solar, wind, and geothermal property.

  3. Business Investment Tax Credit

    26 U.S.C.A. 48 (a) allows deduction of up to 10% of cost for investing in, purchasing, or constructing qualifying energy property for business use.

  4. Tax Exemptions for Grants and Subsidies

    Funds awarded for projects as part of federal programs may be exempt from taxation.

  5. Federal Funding Sources

    The U.S. Department of Energy (DOE) and other federal agencies will from time to time, issue Requests for Proposals (RFPs) in the Commerce Business Daily and will award funds for specific projects when funds are available.

  6. Renewable Energy Production Incentive

    Local governmental entities and State entities may apply for an incentive payment from the Department of Energy for electricity produced and sold by new qualifying renewable energy generation facilities. Not-for-profit electric cooperatives which began or begin operations between October 1, 1993 and September 30, 2003 are also eligible. Annual incentive payments may total 1.5 cents per kilowatt-hour.


Windpower

What is Windpower?
Wind turbines produce windpower by harnessing the wind's energy. Wind turbines have two or three airfoil blades (typically more than 80 feet long) that are mounted to a rotor, which is attached to a main shaft. When wind blows over the airfoils, the "lift" that is created causes the rotor to turn like an airplane propeller. The rotor drives a generator, usually via a gearbox, that produces electricity. The faster the wind speed and the longer the blades the more electricity the turbine generates. Wind turbines are placed on towers, typically more than 100 feet high, to capitalize on more dependable and faster winds.

Costs and Benefits of WindPower:
The cost of windpower has declined steadily in recent years making it relatively competitive with traditional power technologies. Nonetheless, challenging mountain terrain and high population density in New England make it difficult to find suitable wind turbine locations. As a result, wind energy has traditionally been slightly more expensive here than in other parts of the country. However, this is changing as more wind systems are built and operated in the region.

Wind is a local and inexhaustible resource. The money consumers pay for windpower supports local jobs and industry, instead of leaving the region to pay for imported fuels.

Windpower has many environmental advantages. There are no air or water emissions; thus wind energy does not contribute to global warming, acid rain or air pollution. Wind turbines do create some noise from the gearbox and the rotating blades. The noise level decreases quickly as distance from the turbine increases. Careful placement of wind systems can mitigate noise concerns. Furthermore, large modern turbines are much quieter than earlier models.

To learn more about wind power technology, visit the National Renewable Energy Laboratory or the American Wind Energy Association.

Community Wind Fact-Sheet Series
The UMass Amherst Renewable Energy Research Lab, in collaboration with the Massachusetts Technology Collaborative's Renewable Energy Trust Fund, offers a series of fact sheets about wind power on the community scale.

Model Zoning By-Laws
DOER and EOEA have developed model wind zoning by-laws to assist Massachusetts cities and towns in establishing reasonable standards for wind power development.

Small Wind Systems:
If you are interested in a wind power system for your own house, farm, or business, you can download here a new guidebook prepared by the US Department of Energy with assistance from DOER: Small Wind Electric Systems - a Massachusetts Consumer's Guide.

For additional information on small wind systems, visit this federal web page: http://www1.eere.energy.gov/windandhydro/wind_technologies.html or the American Wind Energy Association web page: http://www.awea.org/smallwind/.

Windpower in Massachusetts

Because windpower sites require strong, reliable winds, the best locations for windpower in Massachusetts are along the immediate coastline; offshore in the eastern part of the state, and on exposed mountain ridges and hilltops in central and western Massachusetts.

Hull: Wind Turbine at Hull High School The Town of Hull's 660 kilowatt (kW) wind turbine (right) became operational on December 17, 2001, becoming one of Greater Boston's biggest alternative energy projects. The turbine generates 1.5 million kilowatt-hours (kWh) per year. Situated on Windmill Point, the single turbine stands 150 feet tall, making it the largest commercial wind turbine on the East Coast. The Town expects the turbine to save at least $50,000 in its first year of operation, enough to cover the cost of street lighting for the town.

Hull has an established history with windpower. In 1984, the School Department received a grant from DOER for installation of a wind turbine at Hull High School. The Enertech 40 kW wind turbine became operational in the spring of 1985. By 1995, the turbine produced over 80,000 kWh per year, saving the School Department more than $8,500 annually. However, weather damage incapacitated the turbine forcing the Town to seek funding for the new 660 kW turbine.

For more information about the Hull turbine, contact the Hull Municipal Light Plant at 781-925-0051 or log on to the official website, www.hullwind.org.

Mount Tom/Holyoke: Mount Tom in Holyoke is home to the second largest wind turbine in the Commonwealth. The 250 kW turbine is owned by the University of Massachusetts (UMASS) and used primarily for research and educational purposes. The University's Renewable Energy Research Laboratory (RERL) acquired the turbine from a California wind farm. After being modified for cold weather operation, the turbine was installed in late 1994. RERL conducts ongoing research on both the turbine components and the automated turbine control systems.

For more information about the Mount Tom turbine and other RERL projects, log on to www.ecs.umass.edu/mie/labs/rerl or contact Jim Manwell, Director, at 413-545-4359.

Beverly: Since 1997, the City of Beverly has benefited from the 10kW Bergey wind turbine installed at Beverly High School. A group of Beverly fifth graders acquired the turbine in 1995 with a private donation. The turbine was replaced in July 1999 with a similar model, donated by DOER.

The wind turbine, together with Beverly High School's solar panel array, save the City of Beverly an average of $10,500 per year. Both renewable energy projects are maintained in cooperation with Solar Now Inc., which offers tours of both projects to interested students, citizens and others.

For more information about the Beverly High School wind turbine, log on to www.solarnow.org/beverly.htm or contact Carmel Valianti-Smith, Solar Now Education Director, at 978-927-9786.

Princeton: Princeton Municipal Light Department (PMLD) operates the oldest windpower plant in Massachusetts. Located in central Massachusetts, the Town of Princeton installed eight Enertech wind turbines in 1984 on a hilltop near Mt. Wachusett. Each turbine has a rated power of 40 kW and stands 100 feet high. The entire facility produces approximately 250,000 kWh per year, enough to supply the annual energy needs of over 40 households.

In June 2002, PMLD replaced one of the older turbines with a new 50kW Atlantic Orient turbine. DOER assisted in securing funding for the turbine through the US Department of Energy (DOE). Princeton is currently considering the replacement of all eight existing turbines with two new turbines, each with greater than one-MegaWatt (MW) capacity.

For more information about the Princeton windpower systems, log on to www.pmld.com.

Great Island, Westport: Great Island is a private island that is home to a 1.5 kW Bergey wind turbine. The turbine is used for residential purposes only.

Wind Program Funding in Massachusetts

Massachusetts Renewable Energy Trust (MRET): Managed by the Massachusetts Technology Park Corporation, MRET was established by the 1997 Electric Restructuring Act, and provides funding for renewable energy projects throughout the state. Funds are collected through the Renewable Energy Charge on ratepayers' bills. For more information on MRET, log on to its website at www.masstech.org/RenewableEnergy/index.htm.

The following program ended June 30, 2003: The Wind Energy Predevelopment Support Program, sponsored by the University of Massachusetts, through its Renewable Energy Research Laboratory (RERL), facilitated the introduction of more wind energy in the Commonwealth of Massachusetts, for communities, farms, and small-businesses. The program loaned wind-monitoring equipment and provides assistance at all stages of pre-development, including wind resource monitoring, site evaluation, permitting, RFP development and bid evaluation. DOER and the US Department of Energy provided funds to UMASS through the Strategic Environtechnology Partnership (STEP) program.

Wind Power in New England

Searsburg, Vermont: The Searsburg Wind Power Project is a 6 MW facility located in southern Vermont. Commissioned in July 1997, the wind project serves the annual electricity needs of 2,000 average Vermont households. Additionally, the Searsburg Wind Project serves a valuable educational resource, providing information on wind energy generation in cold weather and environmentally sensitive area. The US Department of Energy and the Electric Power Research Institute provided funding for roughly one-third of the $11 million project cost.

For more information, log on to www.northeastwind.com/searsburg%20project.htm.

Barre, Vermont: Northern Power Systems owns and maintains a 100kW wind turbine in Barre, Vermont.

Orland, Maine: Atlantic Orient Corporation owns and maintains a 50kW wind turbine in Orland, Maine.

Block Island, Rhode Island: Block Island, Rhode Island is home to several residential 10kW Bergey wind turbines.

Newport, Rhode Island: The historic Rose Island Lighthouse is powered, in part, by a 1.5 kW Bergey wind turbine. The turbine reduces the facility's use of its diesel generator from 120 hours a month to less than ten hours a month. Because Rose Island Lighthouse is a National Historic Site, the wind turbine complies with strict noise and visual impact standards. The Newport School District utilizes the project as a teaching facility for their environmental studies program.

For more information, log on to www.roseislandlighthouse.org.

Links:


Biomass

Biomass is a class of renewable fuels that includes woody and herbaceous crops and residues, solid waste, sewage, and liquid fuels (such as alcohol and biodiesel) derived from agricultural products.

Woody biomass comes from forest thinnings and residues. For example, the MDC forest at the Quabbin Reservoir is routinely thinned to promote healthy growth. The harvested logs are then sent to wood burning power plants in Maine, Vermont and Massachusetts. Outstanding examples of wood burning power plants include the 58-megawatt McNeil Station of the Burlington (VT) Electric Department and the 18-megawatt Pinetree Resources plant in Westminster, MA. Modern day forest practices are quite positive. For example, today, more than two-thirds of Massachusetts is covered with forests -- that's up from 30% 150 years ago.

Agricultural biomass, such as soybeans and rapeseed, provide the resource for the manufacture of biodiesel fuels. A successful replacement for conventional diesel fuel, biodiesel reduces particulate emissions from diesel-fuel vehicles. Research has also shown that biodiesel can be manufactured from food wastes such as frying oils and animal fats.

Another agricultural product -- corn -- has become a staple for the production of ethanol and ETBE, an additive used in reformulated gasoline that reduces carbon monoxide.

Methane, a natural by-product of wastewater treatment and landfill decomposition processes, can be captured and used to generate electricity. The use of woody biomass and the harnessing of methane emissions, when used to replace fossil fuels, are powerful counteractants to the production of greenhouse gases.

DOER is working with Massachusetts Bay Transportation Authority and private industry to study and expedite the introduction of biodiesel as a fuel additive to conventional diesel fuels in older urban buses. The goal is to provide near-term relief from the black smoke emissions characteristic of these buses.

DOER is also working with the Massachusetts Bureau of Waste Prevention, and the U.S. Environmental Protection Agency to develop programs to capture and use methane from landfills and to plant fast growing trees on landfills; two processes that counteract greenhouse gas emissions.

  • The Woody Biomass Supply in Massachusetts: A Literature-Based Estimate is an externally produced report from the Supply Subcommittee of the Massachusetts Biomass Energy Working Group, a statewide stakeholder group convened by DOER in June 1991. This report is intended to be a first-order snapshot of the Massachusetts woody biomass supply that could serve as a feedstock for bio-energy development and other projects in the state. The most significant finding of the report is that the current annual growth of new wood in the forests of Massachusetts exceeds the amount removed by almost two million tons. In addition, more than two million tons of woody residue are produced as waste by various industries in the state. In sum, there is significant potential for using biomass for energy production, as well as for bio-refining and other useful production.

For more information on this topic, please contact us at 617-727-4732, or by e-mail at DOER.Energy@State.MA.US.


Landfill Gas Recovery Program

DOER is working with the Environmental Protection Agency's Landfill Gas Outreach Program (LMOP), the CONEG Northeast Regional Biomass Program, the Mass Dapartment of Environmental Protection's Solid Waste Bureau and the Mass Department of Public Utilities' siting board to evaluate the potential for C02 mitigation through the capture of and energy recovery of methane gas from landfills.

Small landfills (less than 1 million tons) are not required to install landfill gas (LFG) control systems, because economies of scale are not available to viably capture LFG.

Since methane is 20 times as powerful a greenhouse gas precursor as C02, extending controls to such small landfills which make up 80% of the total number of landfills in the Commonwealth can be an important determinant in health protection.

Under study is a plan to allow future power plant developers to contribute to a fund that reduces the cost of LFG capture from small landfills, thereby overcoming the economic penalty of small size. EPA is funding two companion studies: (1) collecting data on Massachusetts landfills characteristics and (2) evaluating policy options for administering a Methane-mitigation fund.

Note: On October 5, 1999, the State awarded a $100,000 grant to Braintree Electric Light Department to fund a fuel cell using landfill gas.

For more information on this, or our other biofuels efforts, please contact us at 617-727-4732, or by e-mail at DOER.Energy@State.MA.US.


Photovoltaics: Solar Energy

The Sun Sunlight can be converted directly into electricity by using photovoltaic (PV) cells. PV cells, which are made with semiconductor materials, make electricity with no moving parts, noise, or pollution.

Some of their more common uses are in calculators, watches, on highway warning signs and satellites. PV is also increasingly used to provide electricity for buildings. When the sun isn't shining, PV systems cannot make electricity, but this can be overcome by storing power in batteries during sunny periods or by purchasing backup power from the local electric system.

PV in Massachusetts

Given the diverse weather conditions in New England, many people may have the misconception that PV systems do not work in Massachusetts. Quite the contrary is true. PV modules are relatively unaffected by inclement weather and actually operate better in colder weather. Snow accumulation is also not a problem because the panels are installed at an angle necessary to catch the sun. The angle makes it unlikely that snow will collect on the PV module or if it does, it will be a small amount that melts quickly. Most experts agree that Massachusetts is an excellent location for use of PV.

Cost and Benefits

PV systems are still relatively expensive when compared to conventional power sources. In spite of this, PV can be the lowest cost source of electricity for locations that are not served by the electric grid. Even small purchases can play an important role in expanding the market for PV. As the market increases, the price of PV will continue to come down.

Environment -- Solar energy is environmentally friendly. Since there are no air or water emissions, solar energy does not contribute to the global greenhouse effect, acid rain, or smog. The systems are also quiet, so they can be installed in most locations. PV systems are generally unobtrusive; therefore neighbors are unlikely to object to PV facilities.

Public Schools and Universities

Beverly: One of eight photovoltaic sites created in 1980 as part of President Carter's Photovoltaic Demonstration Project, the PV array at Beverly High School provides the public with the opportunity to study solar energy. The PV system received an overhaul in 1994, when Solar Now, Inc. was created through a grant from Congress to update and manage the site.
Beverly High School PV System

A wind power system was added in 1997 and currently the site provides the city of Beverly with approximately $10,500 worth of energy a year. Solar Now also continues to run both systems while providing valuable educational and economic information to those citizens and businesses interested in solar and wind power. For more information on the Beverly PV System, including a tour of the site, please click here.


Northeastern University PV System

Northeastern University: Located on the roof of the Ell Student Center at Northeastern University in Boston, this PV System was installed in 1995 by Ascension Technology of Waltham. Funding was provided by The Electric Power Research Institute (EPRI), Boston Edison and the US Environmental Protection Agency (EPA). The system generates an average of 2,375 kWh per month.

Community Projects/Residential

Residential Availability: Though still somewhat expensive, PV systems have continued to drop in price as the market continues to expand. In addition, Massachusetts offers tax credits for residents and businesses that install renewable energy systems. For more information on installing a PV system at your home, contact DOER at Energy@State.MA.US. Medford: Making its debut in February 1999, the Medford Solar Project is a joint effort of the Massachusetts Electric Co. (MECo) and Ascension Technologies. It allows MECo Customers in Medford, with south-facing, asphalt-shingled roofs, to put one of two PV systems on their homes and business for half the usual installation price. The first PV system costs $1400 (or $30 a month for 4 years) and is a one panel system that generates 365 kWh/year. The second system includes two PV panels at a price of $2800 (or $60 a month for 4 years) and generates 730 kWh/year or about 5% of total household consumption and saves the consumer about $73 a year on the bill. An added benefit of the PV systems is that each system cuts down on the emissions of carbon dioxide and greenhouse gases because customers are using less energy from the regional grid. Participants are also eligible for the renewable energy tax credits offered by the state. As of August 1999, several residents and businesses have taken advantage of the project. One such business was the Medford Veterinary Clinic, which installed the one-panel PV system. In addition, both the Medford City Hall and High School each received eight panels that were donated by the program. Each system will each produce 2,920 kWh/yr--a savings of $292 per year/per facility. Fairmont House on the Tufts University Campus also received a donation of a two-panel system. Gardner: In 1985, Massachusetts Electric Co. (MECo) began the longest running large-scale test of residential and institutional PV panel installations in the nation. Originally scheduled to last for two years, the project is still running today. The goal of the project is to test the effectiveness of PV systems in residences as a supplemental source of power, as well provide MECo's electric distribution grid with any surplus electricity produced at the system's peak capacity. A cluster of 30 homes on 2 streets had PV Panels installed on their roofs. Of the 30 original houses, 27 still have their PV systems in operation. PV systems are also still up and running at the Levi Heywood Memorial Library, a Burger King restaurant, Mt. Wachusett Community College and Gardner City Hall. Businesses Medford: In 1992, Bradlee's at the Meadow Glenn Mall became one of the first business in the nation to install PV Panels. The system provided electricity for the store's lighting system. Dartmouth: On December 10th 1998, SunPower Station One began operation at BJ's Wholesale Club in North Dartmouth. Funded by Sun Power Electric of Boston in partnership with AllEnergy, the PV System is made up of 52 panels generating 19,500 kW/yr. The electricity is then sold to All-Energy as part of its "green" electricity product called Re-Gen. Over its lifetime, SunPower Station One will help the environment by preventing the following emissions: 1,014 lbs. of nitrogen oxide (which produces smog)3,260 lbs. of sulfur dioxide (which creates acid rain)578,760 lbs. of carbon dioxide (which contributes to global warming) This project is supported in part by funding from the US Department of Energy. The PV panels were manufactured by two Massachusetts companies, ASE Americas, Inc. and Evergreen Solar. Government/Remote Sites Boston Harbor Islands: Between 1984 and 1994, the Massachusetts Photovoltaic Utilization Program installed twelve stand alone PV Systems at the Boston Harbor Islands State Park. Because the islands are not connected to any electric power grid, they are ideal for PV system installation. Among those systems is a 3.2 kW central system on Peddocks Island. This PV System serves five buildings and provides electricity for the Park Rangers and the visitors that come there every year. Alewife and Braintree T Stations: As part of its Alternative Vehicles Program, DOER provided solar charging stations for electric vehicles at the Alewife (Cambridge) and Braintree MBTA parking garages. The PV panels provided enough electricity to recharge the cars while the drivers were at work. This represented a doubly emission free process--no emissions came from driving the cars nor from the generation of electricity used to recharge them at the MBTA Stations. For more information on photovoltaics, please contact us at 617-727-4732, or by e-mail at DOER.Energy@State.MA.US. You can also visit the Solar Boston website at http://www.solarboston.org. Fuel Cells

Diagram courtesy of Massachusetts Electric Co.
Click on image to see a larger view. What is a Fuel Cell?
Originally developed in the late 19th century, fuel cells are electro-chemical devices (similar to batteries) that use a continuous supply of hydrogen to produce electricity. Today's fuel cells typically include a "reformer" which extracts hydrogen from other fuels such as natural gas, landfill gas, or gasoline. Hydrogen can also be obtained through the electrolysis of water, a process that consumes electricity. Fuel cells are available today in sizes that would be appropriate for relatively large electricity consumers, such as schools, hospitals or commercial buildings. Several companies are developing fuel cells for use in homes. Costs and Benefits of Fuel Cells Due to the complexity of the technology and low market demand, electricity from fuel cells costs more than from traditional electricity sources. On the plus side, because fuel cells are quiet and relatively small, they can be installed close to where electricity is needed. This concept of generating electricity where it is needed, called distributed generation, could improve the overall efficiency of our electric system. The environmental impact of fuel cells depends upon the source of the hydrogen. If the hydrogen is produced by electrolysis of water using electricity from a non-polluting source, then the fuel cell does not contribute to the global greenhouse effect, acid rain, or smog. If the hydrogen has been extracted from a fossil fuel, then there will also be low levels of emissions associated with the use of the fuel. Because the emissions are so low, fuel cells are exempt from Massachusetts air quality regulations. Fuel Cell Installations in Massachusetts Braintree: In June 1999, The Braintree Electric Light Department (BELD) began running Massachusetts' first fuel cell that uses landfill gas from the now-closed Town of Braintree Landfill. The fuel cell uses a reformer to extract hydrogen from the methane in the landfill gas. The fuel cell produces 200 kW of electricity, enough to power to 144 homes. DOER provided a $100,000 grant for partial funding of this $1.1 million installation. Additional funding of $200,000 was contributed by the U.S. Department of Energy (DOE).
Click on image for a larger view. Deer Island: In 1997, New England Electric Systems (NEES) began operating a fuel cell at the Deer Island Wastewater Treatment Facility operated by the Massachusetts Water Resource Authority (MWRA) in Boston Harbor. The fuel cell uses a reformer to extract hydrogen from methane gas that is produced by the facility's treatment operations. The fuel cell produces 200 kW of electricity which helps power processes at the Deer Island plant. In addition to the environmental benefits of reducing approximately 40,000 pounds of air pollutants a year, the fuel cell will save the MWRA almost $1 million in energy costs over its lifetime. Natick - Natural Gas Fuel Cell: In 1994, the US Army Natick Research, Development, and Engineering Center (NRDEC) began operating the first fuel cell in New England. The fuel cell runs on natural gas and is part of an $18m 1993 program by the Department of Defense to test and evaluate fuel cells for use as energy sources. As with the Braintree Fuel cell, this fuel cell provides 200kW of electricity to the grid, enough to power 144 homes. For more information on fuel cells, please contact us at 617-727-4732, or by e-mail at DOER.Energy@State.MA.US.

TAX ADVANTAGES

Business Energy Tax Credit / Residential Tax Credits With the signing of the Alternative Energy Bill of 2005, new opportunities were opened for millions of Americans to lessen their dependency on traditional supplies of fossil fuels and electricity.

Never before has it been so affordable to make the investment in energy conservation and production for one's own home or business. Below is a breakout of the tax credits (note: these are true "Credits" against tax liability, rather than just a "deduction" which just lowered the amount of income that could be taxed.) Incentive Type: Corporate Tax Credit Eligible Renewable/Other Technologies: Solar Water Heat, Solar Space Heat, Solar Thermal Electric, Solar Thermal Process Heat, Photovoltaics, Geothermal Electric, Fuel Cells, Solar Hybrid Lighting, Direct Use Geothermal, Microturbines Applicable Sectors: Commercial, Industrial Amount: Currently 10% for geothermal electric and solar; from January 1, 2006 until December 31, 2007, the credit is 30% for solar, solar hybrid lighting, and fuel cells, and 10% for microturbines. The geothermal credit remains at 10%. Maximum Incentive: $550 per 0.5 kW for fuel cells; $200/kW for microturbines; no maximum specified for other technologies Eligible System Size: Microturbines less than 2 MW; fuel cells at least 0.5 kW Authority 1: 26 USC § 48 Authority 2: Energy Policy Act of 2005 (Section 1336 - 1337) Date Enacted: 8/8/2005 Effective Date: 1/1/2006 Expiration Date: 12/31/2007
Summary: A 10% federal energy tax credit is currently available to businesses that invest in or purchase solar or geothermal energy property in the United States. The Energy Policy Act of 2005 (H.R. 6) expands the credit to fuel cells and microturbines installed in 2006 and 2007 and to hybrid solar lighting systems installed on or after January 1, 2006.

For eligible equipment installed from January 1, 2006 through 2007, the credit is set at 30% of expenditures for solar technologies, fuel cells, and solar hybrid lighting; microturbines are eligible for a 10% credit during this two-year period. For equipment installed on or after January 1, 2008, the tax credit for solar energy property and solar hybrid lighting reverts to 10% and expires for fuel cells and microturbines. The geothermal credit remains unchanged -- at 10%.

The credit for fuel cells is capped at $550 per 0.5 kW of capacity. The maximum microturbine credit is $200 per kW of capacity. No maximum is specified for the other technologies.

Solar energy property includes equipment that uses solar energy to generate electricity, to heat or cool (or provide hot water for use in) a structure, or to provide solar process heat. Hybrid solar lighting systems are those that use solar energy to illuminate the inside of a structure using fiber-optic distributed sunlight. Geothermal energy property includes equipment used to produce, distribute, or use energy derived from a geothermal deposit. It does NOT include geothermal heat pumps. For electricity produced by geothermal power, equipment qualifies only up to, but not including, the electrical transmission stage. Energy property does not include public utility property, passive solar systems, pool heating, or equipment used to generate steam for industrial or commercial processes.

To qualify, the original use of the equipment must begin with the taxpayer or it must be constructed by the taxpayer. The equipment must also meet any performance and quality standards in effect at the time the equipment is acquired. The energy property must be operational in the year in which the credit is first taken.

If the project is financed in whole or in part by subsidized energy financing or by tax-exempt private activity bonds, the basis on which the credit is calculated must be reduced. (The formula is described in the tax credit instructions.) Subsidized energy financing means "financing provided under a federal, state, or local program, a principal purpose of which is to provide subsidized financing for projects designed to conserve or produce energy." Therefore, a business must reduce the basis for calculating the credit by the amount of any such incentives received.

Taxpayers can not claim both this business energy tax credit and the credit allowed under 26 USC §45 (Renewable Energy Production Tax Credit) for the taxable year or any prior taxable year. Residential Tax Credits
Solar Photovoltaic and Hot Water Systems
The new provision also offers tax credits to individuals for residential solar energy systems. For solar hot water systems, the allowable tax credit is 30% of the qualified solar system expenditures up to a maximum tax credit limitation of $2,000.
For solar photovoltaic (PV) systems, the allowable tax credit is 30% of the qualified PV system expenditures up to a maximum tax credit limitation of $2,000.
To be eligible for the solar hot water system tax credit, the system must be certified by the Solar Rating and Certification Corporation (SRCC) and produce 50% or more of the hot water needed by the residence. There is no qualification provided for PV systems. Individuals may claim tax credits for either or both types of solar systems. The incentives apply to equipment placed in service during 2006-2007.