Wind power is the conversion of kinetic energy of the wind (achieved through rotating propellers), to mechanical energy. This renewable energy source can been seen in action around the world in utility, commercial, or residential scale wind turbines that produce electricity. House or building-scale wind turbines are typically tied into the local electrical supply in an arrangement called net metering, which feeds any excess power generated back to the local utilities.  See all Wind Members

TAKE ACTION: Voice your support for wind power in Vermont! 

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 Vermont Wind: Harvesting Renewable Power in the Green Mountains Video

Wind continues as the most rapidly growing electric generation resource of our time. Many people want to learn more about wind-generated electricity. Watch this 18-minute Vermont Wind video to hear from people who live near turbines, town officials in communities where turbines are located, and experts both in and out of the industry. Hear about the science, data and real experiences so you can be informed about the role wind can play in your community.

Wind Power History and Usage

The modern electricity-generating wind turbine has roots that 
go back thousands of years to the invention of the windmill, which used mechanical energy to grind grain and pump water. Experiments linking wind turbines to electrical generators were performed in the U.S. and Europe in the late 18th Century, and the first megawatt-size (1.25 MW) turbine in the world was installed and connected to the electric grid in Castleton, Vermont in 1941. The Castleton windmill remained the world’s largest until the serial production of wind turbines began in Holland in 1979.

Since then, the power production of the largest wind turbines has increased dramatically (the largest current units can produce 8 megawatts apiece!). With the threat of climate change and a greater understanding of the costs of fossil fuels, wind power is being adopted worldwide. Since 2009, the global wind capacity has doubled, nearing 320 GW in 2013. Wind Power in the US continues to thrive as its wind power capacity reached 61 GW in 2013, nearly twice the amount in 2010. By the end of 2013, America had over 46,000 operating wind turbines across 39 states, supplying 4.1 percent of the country’s total electricity.

detail-wind1Wind Power in Vermont

Here in Vermont, there is strong potential for wind-power electric generation projects. The best sites for wind development in Vermont are those with strong, consistent wind, which are found along the higher elevation ridgelines of our many hills and mountains. This is a perceived challenge to the pristine views and working landscapes many cherish. The reconciliation of Vermonters’ values with our energy future and independence, is being pursued through several community-based wind projects.

Since the installation of the Searsburg Wind Power (6MW) facility, progress includes breaking ground on the Sheffield Wind (40 MW) project, the Vermont Public Service Board approving Green Mountain Power’s Kingdom Community Wind (63 MW) project as well as the Harrison Family’s Georgia Mountain Community Wind (11 MW) project. The Deerfield Wind (34MW) project is another utility-scale project that has been proposed and is being reviewed. Medium and small-scale wind energy systems are also growing, as schools, homeowners, farmers, and businesses like the Bolton Ski Area, Burke Mountain and Dynapower discover the clean, money saving benefits of the power in the wind.

Learn More About Wind Power:

Vermont wind power resources:

National wind power resources:

Websites for current Vermont wind power projects:

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How does commercial-scale wind power keep pollutants out of the air?

Every hour that a wind plant is generating electricity, another power plant – for the most part fossil fuel fired — somewhere else in New England does not need to operate. Demand for electricity varies not only between the seasons, but even minute-to-minute, throughout each and every day. The New England “grid,” which is comprised of the transmission system and the generators supplying the power, is designed to accommodate and adapt to this constantly changing demand. Some base-load plants operate 24 hours a day, but other “peaking” plants are designed to be turned on and off relatively quickly depending on the need for power. This means that if a wind plant is generating power, other plants are not needed and can be turned off. Because most of New England’s peaking generation plants are powered by natural gas, wind can play a vital role in reducing the use of fossil fuels by ramping down those plants. Kingdom Community Wind

Does it matter that the wind doesn’t always blow?

No. Wind generation is very much like the hydroelectric production in that it is an intermittent resource, which means that it does not have to generate power 100 percent of the time. Most electric generating plants are not constantly operating. Some facilities (like nuclear plants) are designed to run most of the time, while others (like gas turbines) are designed to run only when customer demand is at its highest. Renewable resources, in general, run when the “fuel” is available, whether it is the sun, water or wind.

The electric grid adjusts every hour, as customer demand fluctuates. The grid is designed to accommodate the different operating characteristics of all types of generation. Intermittent resources are easily incorporated into the total operation of the grid. The benefit of wind generation is that when the wind is blowing, generation at other plants in New England, most often fossil fuel plants, can be reduced. (For more information, see this Renewable Energy World article and American Wind Energy Association factsheet on variable energy sources and the electric grid) Kingdom Community Wind

Why do commercial-scale turbines need to be located along ridgelines rather than at lower elevations?

Winds are stronger and more persistent at higher elevations, and the fact is, that at lower elevations – even where mountains and other obstructions do not block the wind — the winds are not sufficient enough to generate economically viable power on a commercial scale.

Wind turbines need to be located where the wind is, because high wind speeds result in an exponential increase in a turbine’s electrical output. Vermont wind speeds are higher, and more consistent at higher elevations, making it an ideal location for wind turbines. Kingdom Community Wind

Who should consider installing a residential wind turbine?

A residential wind turbine can be a relatively large investment and may not be suitable for urban or small-lot suburban homes. Except for very small wind turbines (i.e., with rotors one meter or less in diameter) on very small towers, a property size of one acre or more is desirable. Before installing a residential turbine, you must determine whether the wind resource in your area makes a small wind turbine economical. The economics of a wind system are sensitive to the specific site conditions (vegetation, structures nearby or other obstacles) of the location being considered, and to a lesser extent, the cost of purchasing electricity. AWEA

Checking the Vermont Renewable Energy Atlas and contacting a REV member specializing in residential-scale installation work is a great place to begin assessing the potential for wind power at your site, and what size turbine might fit your needs.

What incentives, grants, tax credits and rebates are available to offset the cost of a residential wind installation?

As of March 2009, the federal government offers an investment tax credit for the purchase and installation of qualifying small wind electric systems, worth 30% of the value of the system. For details, please see the Residential Renewable Energy Tax Creditpage in the Database of State Incentives for Renewables and Efficiency (DSIRE) Web site. The federal government also offers a Renewable Electricity Production Tax Credit and Business Energy Investment Tax Credit for larger, utility-scale wind power installations.

In state, there are several avenues of aid available to homeowners, farmers, and small business owners interested in installing wind power. Please see our Incentives page for more information and links to online resources, and consult the Vermont Wind Program.

How does net metering work?

Net metering is a policy that allows homeowners to receive the full retail value for the electricity that their wind energy system produces. The term net metering refers to the method of accounting for the wind energy system’s electricity production. Net metering allows homeowners with wind systems to use any excess electricity they produce to offset their electric bill. As the homeowner’s wind system produces electricity, the kilowatts are first used for any electric usage in the home. If the wind system produces more electricity than the homeowner needs, the extra kilowatts are fed into the utility grid. U.S. Department of Energy

Why should I make my project net metered?

Off-grid systems can provide a solution to generating energy in remote locations without the expense of bringing in power lines. However, the savings on power lines should be balanced against the cost of battery storage systems that must be installed to store what energy is not used directly by the household’s wind installation. With net metering, the energy produced is fed into the gird, and paid for against the utility bill. Additionally, several incentives and rebates require the wind system to be net metered. Learn more about net metering here.

Last updated July, 2014

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