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State/Fed sites:
· Geothermal Heat Pump Consortium
· US Department of Energy
· International Ground Source Heat Pump Association
· NH Department of Environmental Services
National Renewable Energy Laboratory

Check out state and federal incentives for installing geothermal systems:

Energy Star

Energy Star Homes

Incentives for Geoexchange Systems

Looking for more information about your drinking water well or geothermal well?
The National Ground Water Association

Looking for a geothermal heating system designer?

Allied Consulting

Looking for a qualified builder with geothermal experience?
In NH call:
Cargill Construction

In MA call:
Bill Bachant Builders

For energy, Noble and Greenough goes geothermal
School officials praise system, which harnesses heat generated beneath the surface of the earth
By Sara E. Jacobi, Globe Correspondent  |  September 2, 2007

Noble and Greenough School in Dedham is harnessing the energy beneath the earth's surface to heat and cool one of its buildings.

It is a move that saves money in the long run and coincides with the school's efforts to consider the environment in the way it runs its campus and its classrooms, school officials say.

The school is using geothermal energy -- a source more often associated with shooting geysers or bubbling sulfur pools out west -- to provide heat and air conditioning for its middle school building. The system cost more than a conventional setup, but will save the school $17,000 a year, making up the difference in six years and ringing in savings from then on, the officials say.

The geothermal system involves a series of three wells drilled 6 inches wide and 1,500 feet deep. At this depth, the earth's energy warms the well water to a constant temperature of 50 to 60 degrees. The heated water is pumped out of the wells and into a heat exchanger. In the winter, the heat exchanger takes the heat out of the water, pressurizes the heat to raise its temperature even more, and uses it to warm the cold air in the building. In the summer, the heat exchanger absorbs the excess heat from the air, blows the newly cooled air back into the building, and discharges the unwanted heat back into the earth.

"It's like a big straw we have in the well," said Tom Perry, the director of engineering services for Shawmut Design & Construction, which managed the construction of the project. "It sucks water out and uses it in the building through these ground source heat pumps that either cool or heat."

Students returning Tuesday will hardly notice a change. The ventilators used in the old system will be gone. All that's seen of the well on the surface is a single manhole cover.

"The geothermal wells are underground, so the kids probably won't even notice a difference," said Steve Ginsberg, the school's business manager.

Zaurie Zimmerman, the main consultant on the project, said the middle school building needed a new heating and cooling system and officials decided to go geothermal because the price was right and the technology fit the school's commitment to "go green."

"We said, 'This is such a no-brainer we don't even want to discuss it anymore,' " she said.

This is the school's first geothermal project, and if the process goes well, Zimmerman said they would consider the same procedure for other buildings on campus.

While geothermal heating and cooling systems were first introduced more than 30 years ago, recent improvements in materials, equipment, and installation procedures have made the system more attractive to implement, according to the Geothermal Heat Pump Consortium. Among the buildings in Massachusetts that have gone geothermal are Trinity Church in Boston and the Fessenden School in Newton.

The geothermal system at Noble and Greenough cost $723,000, which was about $100,000 more than a traditional heating, ventilating, and air conditioning system. But the annual savings made the geothermal approach more appealing.
"Retrofitting an existing building is complicated with any system," said Zimmerman, "so when we looked at the two approaches, it was clearly the favorable one."

Aside from any financial reasons, Ginsberg, the business manager, said the installation of the geothermal wells correlates with the environmentally friendly philosophy of the school. Ginsberg said the school has positioned itself on a course to become as "green" as possible.

"As we build, we're going to be very aware of how we could do it the `more green' way," he said.

Other such projects at the school include waterless urinals and double pane glass that's used to trap more heat in the winter so less fuel is needed.

The school also offers many different classes on environmental issues, and one of the school's overall goals is for its students to graduate with a real understanding of why going green is important and what they can do individually to make a difference, he said.

The geothermal system "is a good, practical way to show the school's committed to it -- not just teaching it, but practicing it as well," Ginsberg said. "It's more than just putting in a geothermal well and saying we're doing good things. We're educating future leaders, and that's important to understand."

Zimmerman said that, when compared with other energy saving systems, such as wind turbines or solar panels, geothermal wells cost less to install and have a shorter payback period. Companies interested in "going green" are often dissuaded from purchasing a solar panel system because of how long they'd need to remain in the building to start seeing benefits -- sometimes as long as 25 years, she said.

One criticism of the geothermal process is that the system does not operate with 100 percent renewable energy. Thirty percent of the energy used to run the pumps is electricity, making the school ineligible for federal grant money that's specifically for 100 percent renewable energy sources.

But, Zimmerman said that with the other systems an average person would need federal subsidies to be able to afford them, while the geothermal system is cheaper and more reliable from the beginning.

"Solar panels glisten in the sun," she said. "But they are more like decorations than being cost-effective and saving energy. Geothermal wells are a humble and hard-working system, and there's no reason for people not to consider it."

Sara E. Jacobi can be reached at
© Copyright 2007 The New York Times Company

President Bush Approves One-Year Energy Tax Credit Extension

January 4, 2007

President Bush approved a bill on December 20th that will extend federal tax credits for renewable energy and energy efficiency projects. The wide-ranging Tax Relief and Health Care Act of 2006 extends the production tax credit through 2008 for electricity produced from wind power, geothermal power, biomass, landfill gas, small irrigation power, and trash combustion facilities. It provides a similar one-year tax credit extension for new properties that produce geothermal power or make use of solar energy; for homeowners that purchase solar water heating, solar photovoltaic, or fuel cell systems; for businesses that purchase fiber-optic lighting systems, solar energy systems, or fuel cell power plants; for new energy efficient homes; and for energy efficiency improvements to commercial buildings.

The act extends the Clean Renewable Energy Bonds program through 2008, and increases the total annual amount of tax-credit bonds to $1.2 billion. It extends special tax allowances for cellulosic ethanol facilities to include plants placed in service by 2012. It also extends the research and development tax credit, which encourages businesses to invest in new innovations. See the text of the bill, the White House press release and fact sheet, and the press releases from the Solar Energy Industries Association and the Alliance to Save Energy.

Benefits of Geothermal Heat Pump Systems
U.S. Department of Energy - Energy Efficiency and Renewable Energy
A Consumer's Guide to Energy Efficiency and Renewable Energy

The biggest benefit of GHPs is that they use 25%–50% less electricity than conventional heating or cooling systems. This translates into a GHP using one unit of electricity to move three units of heat from the earth. According to the EPA, geothermal heat pumps can reduce energy consumption—and corresponding emissions—up to 44% compared to air-source heat pumps and up to 72% compared to electric resistance heating with standard air-conditioning equipment. GHPs also improve humidity control by maintaining about 50% relative indoor humidity, making GHPs very effective in humid areas.

Geothermal heat pump systems allow for design flexibility and can be installed in both new and retrofit situations. Because the hardware requires less space than that needed by conventional HVAC systems, the equipment rooms can be greatly scaled down in size, freeing space for productive use. GHP systems also provide excellent "zone" space conditioning, allowing different parts of your home to be heated or cooled to different temperatures.

Because GHP systems have relatively few moving parts, and because those parts are sheltered inside a building, they are durable and highly reliable. The underground piping often carries warranties of 25–50 years, and the heat pumps often last 20 years or more. Since they usually have no outdoor compressors, GHPs are not susceptible to vandalism. On the other hand, the components in the living space are easily accessible, which increases the convenience factor and helps ensure that the upkeep is done on a timely basis.

Because they have no outside condensing units like air conditioners, there's no concern about noise outside the home. A two-speed GHP system is so quiet inside
a house that users do not know it is operating: there are no tell-tale blasts of cold
or hot air.
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