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Hydroelectric Power

Hydroelectric Power. Prof. Park UTI-111 Essex County College. Hydropower Basics. Hydropower is the renewable energy source that produces the most electricity in the United States. It accounted for 6% of total U.S. electricity generation and 67% of generation from renewables in 2008. .

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Hydroelectric Power

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  1. Hydroelectric Power Prof. Park UTI-111 Essex County College

  2. Hydropower Basics • Hydropower is the renewable energy source that produces the most electricity in the United States. It accounted for 6% of total U.S. electricity generation and 67% of generation from renewables in 2008.

  3. Hydropower Relies on the Water Cycle • Understanding the water cycle is important to understanding hydropower. In the water cycle: • Solar energy heats water on the surface, causing it to evaporate. • This water vapor condenses into clouds and falls back onto the surface as precipitation (rain, snow, etc.). • The water flows through rivers back into the oceans, where it can evaporate and begin the cycle over again.

  4. Mechanical Energy Is Harnessed from Moving Water • The amount of available energy in moving water is determined by its flow or fall. Swiftly flowing water in a big river, like the Columbia River that forms the border between Oregon and Washington, carries a great deal of energy in its flow. Water descending rapidly from a very high point, like Niagara Falls in New York, also has lots of energy in its flow. • In either instance, the water flows through a pipe, or penstock, then pushes against and turns blades in a turbine to spin a generator to produce electricity. In a run-of-the-river system, the force of the current applies the needed pressure, while in a storage system, water is accumulated in reservoirs created by dams, then released as needed to generate electricity.

  5. History of Hydropower • Hydropower is one of the oldest sources of energy. It was used thousands of years ago to turn a paddle wheel for purposes such as grinding grain.  Our Nation's first industrial use of hydropower to generate electricity occurred in 1880, when 16 brush-arc lamps were powered using a water turbine at the Wolverine Chair Factory in Grand Rapids, Michigan. • The first U.S. hydroelectric power plant opened on the Fox River near Appleton, Wisconsin, on September 30, 1882. • Until that time, coal was the only fuel used to produce electricity. Because the source of hydropower is water, hydroelectric power plants must be located on a water source. Therefore, it wasn't until the technology to transmit electricity over long distances was developed that hydropower became widely used. • For more information about hydropower, see Hoover Dam, a hydroelectric facility completed in 1936 on the Colorado River between Arizona and Nevada. this dam created Lake Mead, a 110-mile-long national recreational area that offers water sports and fishing in a desert setting.

  6. Where Hydropower is Generated? • Most U.S. Hydropower Is in the West • Over half of U.S. hydroelectric capacity for electricity generation is concentrated in three States: Washington, California, and Oregon. Approximately 31% of the total U.S. hydropower is generated in Washington, the location of the Nation's largest hydroelectric facility — the Grand Coulee Dam. • Most hydropower is produced at large facilities built by the Federal Government, such as the Grand Coulee Dam. The West has most of the largest dams, but there are numerous smaller facilities operating around the country. • Most Dams Were Not Built for Power • Only a small percentage of all dams in the United States produce electricity. Most dams were constructed solely to provide irrigation and flood control. • Worldwide, an installed capacity of 777 GWe supplied 2998 TWh of hydroelectricity in 2006.[1] This was approximately 20% of the world's electricity, and accounted for about 88% of electricity from renewable sources.[2]

  7. Hydropower & the Environment • Hydropower Is Nonpolluting, but Does Have Environmental Impacts • Hydropower does not pollute the water or the air. However, hydropower facilities can have large environmental impacts by changing the environment and affecting land use, homes, and natural habitats in the dam area.

  8. Hydropower & the Environment • Most hydroelectric power plants have a dam and a reservoir. These structures may obstruct fish migration and affect their populations. Operating a hydroelectric power plant may also change the water temperature and the river's flow. These changes may harm native plants and animals in the river and on land. • Reservoirs may cover people's homes, important natural areas, agricultural land, and archeological sites. So building dams can require relocating people. Methane, a strong greenhouse gas, may also form in some reservoirs and be emitted to the atmosphere.

  9. Hydropower & the Environment • Fish Ladders Help Salmon Reach Their Spawning Grounds • In the Columbia River, along the border of Oregon and Washington, salmon must swim upstream to their spawning grounds to reproduce, but the series of dams gets in their way. Different approaches to fixing this problem have been used, including the construction of "fish ladders" which help the salmon "step up" the dam to the spawning grounds upstream.

  10. Fish Ladder at the Bonneville Dam

  11. Hydropower • Hydropower (also called hydroelectric power) facilities in the United States can generate enough power to supply 28 million households with electricity, the equivalent of nearly 500 million barrels of oil. The total U.S. hydropower capacity—including pumped storage facilities—is about 95,000 megawatts. Researchers are working on advanced turbine technologies that will not only help maximize the use of hydropower, but also minimize adverse environmental effects.

  12. Percentage • 1920: 25% • 1930: 30% • 1940: 35% • 2005: 6.4%

  13. Small and Micro Hydropower • Small Hydro has a capacity of up to 10 10MW. • Micro Hydro produce up to 100 kW of power. • Small scale hydro or micro-hydro power has been increasingly used as renewable energy source, especially in remote areas where other power sources are not viable. • Most small scale hydro power systems make no use of a dam or major water diversion, but rather use water wheels. Many areas of the North Eastern United States have locations along streams where water wheel driven mills once stood. Sites such as these can be renovated and used to generate electricity. • Also, small scale hydro power plants can be combined with other energy sources as a supplement. For example a small scale hydro plant could be used along with a system of solar panels attached to a battery bank. While the solar panels may create more power during the day, when the majority of power is used, the hydro plant will create a smaller, constant flow of power, not dependent on the sunlight.

  14. Hydropower and Environment • Dams Disrupt River Flows • Dams Block Fish and Wildlife Migration • Dams Degrade Temperature and Water Quality • Dams Impact Recreational Values

  15. Dams Disrupt River Flows • The volume, timing and temperature of a river’s flow impact everything from habitat quality to reproductive cues for fish to bankside vegetative growth. Many hydropower dams seasonally divert as much as 95 percent of a river’s water, reducing flows to a mere trickle in some reaches. In addition, generating power can pulse flows downstream and wreak havoc on aquatic communities. Larger dams with reservoirs often retain winter and spring flows that would naturally flush and renew river ecosystems.

  16. Dams Block Fish and Wildlife Migration • Dams block the upstream and downstream migration of fish and other aquatic organisms. Loss of habitat has been a critical factor in the decline of the state’s migratory fish species. Some dams may be retrofitted with fish ladders, although these structures are costly and not completely effective. Dams also block the natural movement of nutrients and sediment that create habitat, nourish banks and replenish beaches.

  17. Dams Degrade Temperature and Water Quality • When dams divert water out of the natural streambed, water temperatures generally rise — often to levels that cannot sustain healthy fisheries or dilute natural or man-made pollutants. Dams can also degrade water quality by reducing the oxygen content of downstream flows and trapping sediment and pollutants in reservoirs.

  18. Dams Impact Recreational Values • Low river flows generally reduce recreational opportunities, harming local tourism-based economies and personal enjoyment of a public resource. Some hydropower dams block public access to rivers altogether and eliminate opportunities to boat or fish.

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