Cooling ponds are used where sufficient land is available, as an alternative to cooling towers or discharging of heated water to a nearby river or coastal bay, a process known as “once-through cooling.” The latter process can cause thermal pollution of the receiving waters.[1][2] Cooling ponds are also sometimes used with air conditioning systems in large buildings as an alternative to cooling towers.[3]
The pond receives thermal energy in the water from the plant’s condensers during the process of energy production and the thermal energy is then dissipated mainly through evaporation and convection.[4][5] Once the water has cooled in the pond, it is reused by the plant. New water is added to the system (“make-up” water) to replace the water lost through evaporation.
A 1970 research study published by the U.S. Environmental Protection Agency reported that cooling ponds have a lower overall electrical cost than cooling towers while providing the same benefits. The study concluded that a cooling pond will work optimally within 5 degrees Fahrenheit of natural water temperature with an area encompassing approximately 4 acres per megawatt of dissipated thermal energy.[4]
Examples
Lake Anna is a cooling pond in Virginia, which provides cooling water for the North Anna Nuclear Generating Station. This pond has recreational uses such as fishing, swimming, boating, camping, and picnicking as well as being a cooling pond for the nuclear plant.[6]
The cooling pond at the Chernobyl Nuclear Power Plant (Pripyat, Ukraine) has abundant wildlife, despite the radiation present in the area. There are some accounts of wels catfish(Silurus glanis) growing up to 350 pounds and having a lifespan of up to 50 years in the area.[7]
The Columbia Energy Center in Pacific, Wisconsin is a coal fired power plant with a capacity of 1000 MW. A dual cooling system is used for heat rejection that consists of a cooling pond and two cooling towers. The pond and towers are connected in a parallel arrangement to help dissipate thermal energy at expedited rates.[8]
In 1994 the reactor at Yongbyon Nuclear Scientific Research Center, North Korea, was under U.S scrutiny and its nuclear fuel rods were taken out of the reactor and placed in the facility's cooling pond.[9] The fuel rods have since been removed.[10]
At the 2.05 MW Ashford A power station Kent, UK, cooling water for the oil-fired engines was obtained from, and returned to, cooling water ponds.[11] The principal cooling mechanism in the ponds was by convection from the water surface.
At the 89 MW Back o’ the’ Bank power station in Bolton UK the cooling water was cooled in 4 spray ponds.[12] The small size of the spray droplets improved the heat transfer, increased evaporation, and led to more effective cooling. Each cooling pond had a capacity of 0.75 million gallons per hour (0.95 m3/s).[12] Make up water was abstracted from the nearby River Tonge. In about 1950 a hyperbolic reinforced concrete cooling tower was built with a capacity of 2.5 million gallons per hour (3.15 m3/s), with cooling range of 15 °F (8.3 °C).[12] However, there were complaints that operation of the cooling tower let to problems with ice in cold weather as water vapour from the tower froze as fine particles.[13]
In 1963 the UK’s Central Electricity Generating Board (CEGB) was researching the possibility of using warmed cooling water from power stations to support fish-farming both for recreational use and for food. At Grove Road power station in London water was cooled in wooden natural draft cooling towers and fell into cooling water ponds. The CEGB introduced carp (Cyprinus carpio), grass carp, silver carp and Tilapia into the cooling water ponds; the fish grew rapidly in the warm water (up to 27 °C).[14]
Zaporizhzhia nuclear power plant, Ukraine, has massive cooling ponds with additional water spray.
See also
Wikimedia Commons has media related to Cooling pond.
^Dunne, Thomas; Leopold, Luna B. (1978). Water in Environmental Planning. New York: W.H. Freeman. p. 722. ISBN 978-0-7167-0079-1.
^Ananthanarayanan, P.N. (2005). Basic Refrigeration and Air Conditioning. McGraw-Hill. p. 218. ISBN 978-0-07-049500-5.
^ a bAn Engineering-Economic Study of Cooling Pond Performance (Report). Washington, DC: U.S. Environmental Protection Agency (EPA). 1970. p. 5. 16130DFX0570. Water Pollution Control Research Series.
^Bengtson, Harlan (21 February 2010). "Power Plant Condenser: Wet Cooling Tower, Pond, Air Cooled". Energy & Power Plants. Troy, New York, US: Bright Hub, Inc. Retrieved 2018-12-30.
^"North Anna Waste Heat Treatment Facility". Dominion Resources, Inc. Archived from the original on 2015-04-06. Retrieved 2015-01-26.
^"Yes, there are giant catfish in Chernobyl's cooling pond – but they're not radiation mutants". Earth Touch News Network. Bethesda, Maryland, US. Retrieved 2018-10-25.
^Joerg, Kirchhoff (1995). "Optimized Combination of a Cooling Pond and Cooling Tower System for Condenser Cooling at a Steam Cycle Power Plant". College of Engineering, University of Wisconsin—Madison. Masters' Thesis.
^Gordon, Michael R. (1994-06-24). "Korean Talks: Looking for Options". New York Times.
^"UN confirms N Korea nuclear halt". Archived from the original on 27 August 2007. Retrieved 30 December 2018., BBC News, 16 July 2007
^"Ashford Electricity Works". Chapman family history. Retrieved 5 June 2020.
^ a b cGarrett, Frederick C., ed. (1959). Garcke's Manual of Electricity Supply vol. 56 1958-59. London: Electrical Press. pp. A-36.
^Bolton News. "Ice from cooling tower". Bolton News. Retrieved 5 June 2020.
^Information, Reed Business (31 January 1963). "Cultivating fish for food and sport". New Scientist. Retrieved 5 June 2020. {{cite web}}: |first1= has generic name (help)
