Pumped-storage hydroelectricity

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Hydro-storage redirects here. For storage of water for other purposes, see Reservoir.

Diagram of the TVA pumped storage facility at Raccoon Mountain Pumped-Storage Plant

Power spectrum of a pumped-storage hydroelectricity. Green represents power consumed in pumping; red is power generated.

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Pumped storage hydroelectricity is a type of hydroelectric power generation used by some power plants for load balancing. The method stores energy in the form of water, pumped from a lower elevation reservoir to a higher elevation. Low-cost off-peak electric power is used to run the pumps. During periods of high electrical demand, the stored water is released through turbines. Although the losses of the pumping process makes the plant a net consumer of energy overall, the system increases revenue by selling more electricity during periods of peak demand, when electricity prices are highest. Pumped storage is the largest-capacity form of grid energy storage now available.

1 Overview
2 Potential technologies
3 Worldwide list of pumped storage plants
4 References
5 See also
6 External links

[edit] Overview

At times of low electrical demand, excess generation capacity is used to pump water into the higher reservoir. When there is higher demand, water is released back into the lower reservoir through a turbine, generating electricity. Reversible turbine/generator assemblies act as pump and turbine (usually a Francis turbine design). Some facilities use abandoned mines as the lower reservoir, but many use the height difference between two natural bodies of water or artificial reservoirs. Pure pumped-storage plants just shift the water between reservoirs, but combined pump-storage plants also generate their own electricity like conventional hydroelectric plants through natural stream-flow. Plants that do not use pumped-storage are referred to as conventional hydroelectric plants; conventional hydroelectric plants that have significant storage capacity may be able to play a similar role in the electrical grid as pumped storage, by deferring output until needed.

Taking into account evaporation losses from the exposed water surface and conversion losses, approximately 70% to 85% of the electrical energy used to pump the water into the elevated reservoir can be regained. The technique is currently the most cost-effective means of storing large amounts of electrical energy on an operating basis, but capital costs and the presence of appropriate geography are critical decision factors.

The relatively low energy density of pumped storage systems requires either a very large body of water or a large variation in height. For example, 1000 kilograms of water (1 cubic meter) at the top of a 100 meter tower has a potential energy of about 0.272 kW·h. The only way to store a significant amount of energy is by having a large body of water located on a hill relatively near, but as high as possible above, a second body of water. In some places this occurs naturally, in others one or both bodies of water have been man-made.

This system may be economical because it flattens out load variations on the power grid, permitting thermal power stations such as coal-fired plants and nuclear power plants that provide base-load electricity to continue operating at peak efficiency (Base load power plants), while reducing the need for "peaking" power plants that use costly fuels. Capital costs for purpose-built hydrostorage are high, however.

Along with energy management, pumped storage systems help control electrical network frequency and provide reserve generation. Thermal plants are much less able to respond to sudden changes in electrical demand, potentially causing frequency and voltage instability. Pumped storage plants, like other hydroelectric plants, can respond to load changes within seconds.

The upper reservoir (Llyn Stwlan) and dam of the Ffestiniog Pumped Storage Scheme in north Wales. The lower power station has four water turbines which generate 360 MW of electricity within 60 seconds of the need arising. The size of the dam can be judged from the car parked below.

The first use of pumped storage was in the 1890s in Italy and Switzerland. In the 1930s reversible hydroelectric turbines became available. These turbines could operate as both turbine-generators and in reverse as electric motor driven pumps. The latest in large-scale engineering technology are variable speed machines for greater efficiency. These machines generate in synchronisation with the network frequency, but operate asynchronously (independent of the network frequency) as motor-pumps.

A new use for pumped storage is to level the fluctuating output of intermittent power sources. The pumped storage absorbs load at times of high output and low demand, while providing additional peak capacity. In certain jurisdictions, electricity prices may be close to zero or occasionally negative (Ontario in early September, 2006), indicating there is more generation than load available to absorb it; although at present this is rarely due to wind alone, increased wind generation may increase the likelihood of such occurrences. It is particularly likely that pumped storage will become especially important as a balance for very large scale photovoltaic generation.^[1]

In 2000 the United States had 19.5 GW of pumped storage capacity, accounting for 2.5% of baseload generating capacity. PHS generated (net) -5.5 GWh of energy^[2] because more energy is consumed in pumping than is generated; losses occur due to water evaporation, electric turbine/pump efficiency, and friction.

In 1999 the EU had 32 GW capacity of pumped storage out of a total of 188 GW of hydropower and representing 5.5% of total electrical capacity in the EU.

[edit] Potential technologies

The use of underground reservoirs as lower dams has been investigated. Salt mines could be used, although ongoing and unwanted dissolution of salt could be a problem. If they prove affordable, underground systems might greatly expand the number of pumped storage sites. Saturated brine is about 20% more dense than fresh water.

A new concept in pumped storage is to utilise wind turbines to drive water pumps directly, in effect an 'Energy Storing Wind Dam'. This could provide a more efficient process and usefully smooth out the variabilities of energy captured from the wind.

[edit] Worldwide list of pumped storage plants

Argentina

Rio Grande-Cerro Pelado Hydroelectric Complex (1986), 750 MW

Australia

Bendeela (1977), 80 MW
Kangaroo Valley (1977), 160 MW
Tumut Three, (1973), 1,500 MW
Wivenhoe Power Station, 510 MW

Austria

Häusling (1988), 360 MW
Lünerseewerk (1958), 232 MW
Kraftwerksgruppe Fragant, 100 MW
Kühtai (1981), 250 MW
Malta-Hauptstufe (1979), 730 MW
Rodundwerk I (1952), 198 MW
Rodundwerk II (1976), 276 MW
Roßhag (1972), 231 MW
Silz (1981), 500 MW

Belgium

Coo, (1979), 1100 MW

Bulgaria

PAVEC Chaira, (1998), 864 MW
PAVEC Belmeken (197?), 375 MW
PAVEC Orfey, (1975), 160 MW
PAVEC Peshtera, (1959), 128 MW
PAVEC Batak, (1958), 48 MW
PABEC Vacha, (1973), 20 MW

Canada

Sir Adam Beck Hydroelectric Power Stations, (1957) near Niagara Falls, reversible Deriaz turbines, 174 MW

China

Guangzhou, (2000), 2,400 MW - (World's largest)^[3]
Tianhuangping (2001), 1,800 MW

Croatia

CHE Fužine (1957) 4.6 MW
RHE Lepenica (1985), 1.14/1.25 MW^[4]
RHE Velebit (1984), 276/240MW^[5]

Czech Republic

Dalešice, (1978), 480 MW
Dlouhé Stráně, (1996), 650 MW
Štěchovice, (1947), 45 MW

France

Grand Maison (1997), 1,070 MW
La Coche (1976), 285 MW
Le Cheylas (1979), 485 MW
Montézic (1983), 920 MW
Rance (1966), 240 MW hybrid pumped water-tidal plant
Revin (1976), 800 MW
Super Bissorte (1978), 720 MW

Germany

Erzhausen (1964), 220 MW
Geesthacht (Hamburg) (1958), 120 MW
Goldisthal (2002), 1,060 MW
Happurg (1958), 160 MW
Hohenwarte II (1966), 320 MW
Koepchenwerk (1989), 153 MW
Langenprozelten (1976), 160 MW
Markersbach (1981), 1,050 MW
Niederwartha, Dresden (1958), 120 MW
Waldeck II (1973), 440 MW

India

Bhira(Maharashtra) pump storage unit 150 MW
Kadamparai, Near Coimbatore, Tamil Nadu,(4*100)MW
Nagarjuna Sagar PH, Andhra Pradesh, 810 MW (1 x 110 MW + 7 x 100 MW)
Purulia Pumped Storage Project, Ayodhya Hills, Purulia, West Bengal, 900 MW
Srisailam Left Bank PH, Andhra Pradesh, 900 MW (6 x 150 MW)
Tehri dam, Uttranchal, 1000 MW (under construction)

Iran

Siah Bisheh, Iran, (1996), 1,140 MW

Ireland

Turlough Hill (1974), 292 MW

Italy

Chiotas (1981), 1,184 MW
Lago Delio (1971), 1,040 MW
Piastra Edolo (1982), 1,020 MW
Presenzano (1992), 1,000 MW

Japan

Imaichi (1991), 1,050 MW
Kannagawa (2005), 2,700 MW
Kazunogawa (2001), 1,600 MW
Kisenyama, 466 MW
Matanoagawa (1999), 1,200 MW
Midono, 122 MW
Niikappu, 200 MW
Okawachi (1995), 1,280 MW
Okutataragi (1998), 1,932 MW
Okuyoshino, 1,206 MW
Shin-Takasegawa, 1,280 MW
Shiobara, 900 MW
Takami, 200 MW
Tamahara (1986), 1,200 MW
Yagisawa, 240 MW
Yanbaru, Okinawa (1999), 30 MW (First high-head seawater pumped storage in the world) Hitachi

Lithuania

Kruonis Pumped Storage Plant, (1993) Designed - 1,600 MW, installed - 900 MW

Luxembourg

Vianden, (1964), 1,100 MW

Norway

Note that Norway has a high density of hydroelectric power generation, so some of the following locations are simply pumps that never generate power themselves, but transfer water to reservoirs where it can be re-used by existing hydroelectric power stations. This information comes from [1], [2], and [3]

Aurland III, Hordaland, (1979), 270 MW
Breive, Bykle, Aust-Agder
Duge, Rogaland
Hjorteland, Rogaland
Hunnevatn, Rogaland
Jukla, Hordaland, 40 MW
Kastdalen, Hordaland
Mardal, Møre og Romsdal
Monge, Møre og Romsdal
Nygard, Modalen, Hordaland
Saurdal, Rogaland, 640 MW
Skarje, Bykle, Aust-Agder
Skjeggedal, Hordaland
Stølsdal, Rogaland, 17 MW
Tverrvatn, Nordland

Philippines

CBK, 700MW

Poland

Dychów, 79.5 MW
Niedzica, 92.6 MW
Porąbka-Żar, 500 MW
Solina, 200 MW
Żarnowiec, 716 MW
Żydowo, 150 MW

Portugal

Aguieira, 270MW
Alqueva, 260MW
Alto Rabagão, 72MW
Torrão, 144MW
Vilarinho II, 74MW

Russia

Kuban (1968) 15.9/19.2 MW
Zagorsk (1994) 1,200/1,320 MW
Zelenchuk (under construction) 140/150.6 MW

Serbia

Bajina Basta (1982) 614 MW

Slovakia [4]

Čierny Váh 735.16 MW
Liptovská Mara 198 MW
Ružín 60MW
Dobšiná 24 MW

Slovenija

Avče 600 MW

South Africa

Drakensberg, South Africa, (1983) 1,000 MW
Palmiet 400 MW
Ingula 1332KW (Under Construction)

Spain

Aguayo (Cantabria) 339 MW
Aldeadavila (Salamanca) 422 MW (2 X 211 MW) [5]
Moralets-Llauset (Lleida/Huesca) 210 MW [6]
La Muela (Valencia) 628 MW
Sallente-Estany Gento (Lleida) 451 MW [7]
Tajo de la Encantada (Málaga) 360 MW
Tavascan-Montmara (Lleida) 52 MW
Villarino (Salamanca) 810 MW (6 X 135 MW) [8]

Sweden

Juktan, 334 MW ^[6]

Taiwan

Minghu (1985) 1,000 MW
Mingtan (1994) 1,620 MW

Ukraine

Dniestr HPSP (1st construction phase completed and now provides 972 MW, next phases will give up to 2,268 MW)photo
Kaniv HPSP (design stage) 1800 MW [9]
Kyiv HPSP 235.5 MW [10]
Tashlyk HPSP 905 MW/-1325 MW [11]

United Kingdom

Ben Cruachan, Scotland (1965), 440 MW (2 × 120 MW + 2 × 100 MW units)
Dinorwig, Wales (1984), 1728 MW (6 × 288 MW units)
Foyers, Scotland (1975), 305 MW
Ffestiniog, Wales (1963), 360 MW (4 × 90 MW units)

United States

California

Castaic Dam, (1978) 1,566 MW
John S. Eastwood, (1988) 200 MW
San Luis Dam (William R. Gianelli), (1968) 424 MW
Pyramid Lake, (1973) 1,495 MW
Helms, (1984) 1,200 MW
Iowa Hill, (Proposed 2010) 400 MW [12]
Edward C. Hyatt, (1968) 780 MW

Colorado

Cabin Creek (1967), 324 MW
Mount Elbert 200 MW, 1,212 MW

Connecticut

Rocky River, (1929) 31 MW

Georgia

Rocky Mountain Pumped Storage Station 848 MW
Wallace Dam (operated by GA. Power) Lake Oconee/Lake Sinclair 4 x 52 MW reversible units

Hawaii

Koko Crater, Oahu, Hawaii (Proposed)

Massachusetts

Bear Swamp, (1972) 600 MW
Northfield Mountain, (1972) 1,080 MW

Michigan

Ludington, (1973) 1,872 MW

Missouri

Clarence Cannon dam, (1983) 58 MW (pump-back capability tested twice in 1984 and not used since.[13])
Taum Sauk, pure pump-back 450 MW (out of operation as of December, 2005)