Below are some basic answers to frequently asked questions and concerns about the impact of wind farms on local communities. However, do not stop your inquiry here. Seek out as much information from quality sources as you can.

Do wind farms impact property values?
What sounds do wind turbines make?
What benefit does a wind farm have for me if I don’t have any turbines on my land?
Do wind turbines shed ice?
How does wind power affect birds and bats?
Will I like the look of the wind turbines in my community?
What does wind power cost?

Q: Do wind farms impact property values?
A: Wind farms do not adversely impact surrounding property values. What’s more, in most locations, property values in the view shed of a wind farm increase faster than in comparable areas. These findings come from two studies:

• An economic development agency in Washington State commissioned an independent economic consultant to study 19 wind farms.
• The Renewable Energy Policy Project, a government funded research group, studied 10 wind farms.

In addition, land on which wind turbines are sited increase in value due to revenue potential.

Sources: Economic Development Group of Kittitas County / EcoNorthwest / Renewable Energy Policy Project

Q: What sounds do wind turbines make?
A: Today, an operating wind energy project at a distance of 750 to 1,000 feet emits sounds at a level comparable to a kitchen refrigerator or a moderately quiet room.

Wind turbines make a whooshing sound as the blades travel through the air. When standing directly under a wind turbine, you may hear a hum made by the generator and/or gearbox. Because wind turbines only produce sound when appropriate wind conditions are experienced, the wind makes sound as well, and the sound of an operating wind turbine is masked more than 800 to 900 feet away. Thus, with appropriate setbacks enacted through local regulatory authorities, wind turbine sound emissions should not affect neighboring residents.

Sources: New York State Energy Research and Development Authority Wind Toolkit / University of Massachusetts, Renewable Energy Research Laboratory / American Wind Energy Association

Q: What benefit does a wind farm have for me if I don’t have wind turbines on my land?
A: A wind farm generates substantial value for a local community, including:

• Revenues to Towns: Property taxes or payments in lieu of taxes.
• Revenues to Farming and Ranching Landowners: Providing significant and stable revenues to local farmers and ranchers.
• Short Term Construction Benefits: Taken as an example, the construction of 50 wind turbines will produce roughly 60 full-time and part-time jobs and create a significant demand for local construction materials and services. It is First Wind’s policy to subcontract locally for construction to the greatest extent possible.
• Long Term Operations and Maintenance: Operation and maintenance of 50 wind turbines will produce approximately 4-6 long term service jobs. It is First Wind’s policy to hire and train locally to the greatest extent possible.
• Electricity Supply: America’s energy demand continues to increase, and wind energy provides a way to meet a significant portion of this increase without the drawbacks of other types of power generation:
  • Coal plants produce significant amounts of pollutants, including carbon dioxide (greenhouse gas), SO₂ (acid rain), NO_x (acid rain and smog), particulate matter (asthma and other air pollution related illnesses), carbon monoxide, and mercury (contamination of fish and water supplies).
  • Natural gas-fired plants, while cleaner than coal and oil, are often not cost competitive due to large and sudden fuel price increases.
  • Large-scale hydroelectric projects have significant human and natural environmental consequences because of the flooding of large areas of land.

Q: Do wind turbines shed ice?
A: Wind turbines shut down during icing events due to either imbalance detection or the icing of the control anemometer (the control anemometer tells the turbine how fast the wind is moving). Any ice buildup tends to shed while the turbine is at rest or while it is starting up (that is, moving at slower than operational speed). Due to this, and the fact that the ice sheds in thin, non-aerodynamic pieces that break apart as they fall, setting the turbines back from roads and residences are sufficient to protect the public from ice shed.

The best way to discover whether there have been any injuries caused by wind turbine ice shed is to review insurance claims. To date, there has not been one insurance claim for injury due to ice shed.

Sources: Energy Insurance Brokers / South Bay Risk Management and Insurance Services / Garrad Hassan

Q: How does wind power affect birds and bats?
A: First Wind conducts extensive, multi-season environmental reviews of each potential project site to determine its impact on local wildlife. While we make every effort to minimize the impact of our wind turbines on birds and bats, it is impossible to ensure no bird or bat will be affected. When compared to other causes of death to birds and bats, however, we believe the benefits to the overall wildlife environment outweighs the risk. In fact, recent data shows wind turbines account for less than 0.003% of all annual bird fatalities in the U.S.

Many studies on the subject are ongoing, and most remain inconclusive on the full impact of wind power on wildlife. First Wind closely monitors research in this area as part of its environmental reviews. The National Research Council, in a comprehensive review of wind power, recently offered this perspective:

The overall importance of turbine-related deaths for bird populations is unclear. Collisions with wind turbines represent one element of the cumulative anthropogenic impacts on bird populations; other impacts include collisions with tall buildings, communications towers, other structures, and vehicles, as well as other sources of mortality such as predation by house cats (Erickson et al. 2001, 2005).

While estimation of avian fatalities caused by wind-power generation is possible, the data on total bird deaths caused by most anthropogenic sources, including wind turbines, are sparse and less reliable than one would wish, and therefore it is not possible to provide an accurate estimate of the incremental contribution of wind-powered generation to cumulative bird deaths in time and space at current levels of development.

Data on bat fatalities are even sparser. While there have been a few reports of bat kills from other anthropogenic sources (e.g., through collisions with buildings and communications towers), the recent bat fatalities from wind turbines appear to be unprecedentedly high. More data on direct comparisons of turbine types are needed to establish whether and why migratory bats appear to be at the greatest risk of being killed. Clearly, a better understanding of the biology of the populations at risk and analysis of the cumulative effects of wind turbines and other anthropogenic sources on bird and bat mortality are needed.

Having said the above, we provide here estimates summarized by Erickson et al. (2005) and estimates reported by the U.S. Fish and Wildlife Service (2002a). Those sources emphasize the uncertainty in the estimates, but the numbers are so large that they are not obscured even by the uncertainty:

• Collisions with buildings kill 97 to 976 million birds annually
• Collisions with high-tension lines kill at least 130 million birds, perhaps more than 1 billion
• Collisions with communications towers kill between 4 and 5 million based on “conservative estimates,” but could be as high as 50 million
• Cars may kill 80 million birds per year
• Toxic chemicals, including pesticides, kill more than 72 million birds each year
• Domestic cats are estimated to kill hundreds of millions of songbirds and other species each year
• Collisions with wind turbines killed an estimated 20,000 to 37,000 birds per year in 2003, with all but 9,200 of those deaths occurring in California

Erickson et al. (2005) estimates that total cumulative bird mortality in the United States “may easily approach 1 billion birds per year.” Clearly, bird deaths caused by wind turbines are a minute fraction of the total anthropogenic bird deaths—less than 0.003% in 2003 based on the estimates of Erickson et al. (2005).

SOURCE: National Research Council Wind Report 2007
Download the PDF [5 mb]

Q: Will I like the look of the wind turbines in my community?
A: A trip to a wind farm is worth at least a thousand words. Although aesthetics are subjective, anecdotal evidence suggests:

People generally like the look of modern, slowly rotating wind turbines on tubular towers. People are generally more receptive to the visual impact once they have visited a wind farm in person where they gain perspective on the size and distance. On a recent visit to a wind farm in Fenner, New York, a New York landowner said:

“You know, it wasn’t until I actually saw the wind turbines at Fenner that I realized how amazing they are. It’s hard to describe them; they’re magnificent, graceful, inspiring. And you know, I knocked on people’s doors and everyone I spoke to said they really liked them. I was expecting a couple people to have reservations, but no one did!”

This anecdote is not to say that everyone likes the look of wind turbines. It is just to say that many people do and it is important for a person to experience them firsthand.

Q: What does wind power cost?
A: With a moderate to good wind resource, wind power generation is competitive with conventional sources of generation. In the future, as fossil fuel prices increase, it is expected that wind will be cheaper than these sources.

Furthermore:

• Wind can be produced at a known cost, which reduces price volatility in the energy markets, effectively saving utilities’ and ratepayer’s money.
• Wind will reduce the demand on natural gas, which should also reduce prices.
• The price of wind generation continues to go down while the price of conventional fuel continues to go up.
• Wind power does not incur the external costs (costs not included in the market price) of fossil fuel power production, such as air pollution related healthcare costs (i.e., treatment for lung ailments).

Sources: American Wind Energy Association / National Renewable Energy Laboratory / New York Independent System Operator / Harvard School of Public Health