Energy Tower DowndraftEnergy tower (downdraft)
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This article is about electricity power generation by downdraft created by evaporation of water sprayed at the top of a tall hollow cylinder. For other uses, see Energy tower (disambiguation).
Sharav Sluice Energy TowerThe energy tower is a device for producing electrical power. The brainchild of Dr. Phillip Carlson, expanded by Professor Dan Zaslavsky from the Technion. Energy towers spray water on hot air at the top of the tower, making the cooled air fall through the tower and drive a turbine at the tower's bottom.
working principle of the Energy Tower Downdraft (Sharav Sluice Energy Tower)
1 Concept summary
4 Potential Problems
5 See also
7 External links
An energy tower (also known as a downdraft energy tower because the air flows down the tower) is a tall (1,000 meters) wide (400 meters) hollow cylinder with a water spray system at the top. Pumps lift the water to the top of the tower and then spray the water inside the tower. This cools the hot air hovering at the top. The cooled air, now denser than the outside warmer air, falls through the cylinder, spinning a turbine at the bottom. The turbine drives a generator which produces the electricity.
The greater the temperature difference between the air and water, the greater the energy efficiency. Therefore, downdraft energy towers should work best in a hot dry climate. Energy towers require large quantities of water. Salt water is acceptable, although care must be taken to prevent corrosion.
The energy that is extracted from the air is ultimately derived from the Sun, so this can be considered a form of solar power. Unusually, this form of solar power also works at night, because air retains some of the day's heat after dark. However, power generation by the Energy tower is affected by the weather: it slows down each time the ambient humidity increases (such as during a rainstorm), or the temperature falls.
An related approach is the solar updraft tower, which heats air in glass enclosures at ground level and sends the heated air up a tower to drive a turbine at the top. Updraft towers don't pump water, which increases their efficiency, but do require large amounts of land for the collectors. Land acquisition and collector construction costs for updraft towers must be compared to pumping infrastructure costs for downdraft collectors. Operationally, maintaining the collector structures for updraft towers must be compared to pumping costs and pump infrastructure maintenance.
Zaslavsky, et al., estimate that depending on the site and financing costs, costs would be in the range of 1-4 cents per kwh, well below alternative energy sources other than hydro. Pumping the water requires about 50% of the turbine's output. Zaslavsky claims that the Energy Tower would achieve up to 70-80%  of the Carnot limit. If the conversion efficiency turns out to be much lower it is expected to have an adverse impact on projections made for Cost of Energy.
Projections made by Altmann and by Czisch about conversion efficiency and about Cost of Energy (cents/kWh) are based only on model calculations, no data on a working pilot plant have ever been collected.
Actual measurements on the 50kW Manzanares pilot solar updraft tower found a conversion efficiency of 0.53%, although SBP believe that this could be increased to 1.3% in a large and improved 100MW unit. This amounts to about 10% of the theoretical limit for the Carnot cycle. It is not unreasonable to expect a similar low conversion efficiency for the Energy tower, in view of the fact that it is based on a similar principle as the solar updraft tower.
Currently, no known physical implementation of an energy tower exists. However, there are people who say that making a tower to test its capacity can be much easier. This is now being tested in the Netherlands.
If salt water is used, corrosion rates can be very high. Not only would the tower and the turbines be subjected to the salty humid air, but structures nearby could be affected.
The technology requires a hot and arid climate, and at the same time access to large amounts of water. Such locations include the coast of West Africa, Western Australia, northern Chile, Namibia, the Red Sea, Persian Gulf, and the Gulf of California. Most of these regions are remote and thinly populated, and would require power to be transported over long distances to where it is needed. Alternatively, such plants could provide captive power for nearby industrial uses such as desalination plants, aluminium production via the Hall-Héroult process, or to generate hydrogen for ammonia production.
Large industrial consumers often locate near cheap sources of electricity. However, many of these desert regions also lack necessary infrastructure, increasing capital requirements and overall risk.
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^ US3,894,393 (PDF version) (1975-07-15) Carlson; Phillip R., Power generation through controlled convection (aeroelectric power generation).
^ Zaslavsky, Dan; Rami Guetta et al. (December 2001). "Energy Towers for Producing Electricity and Desalinated Water without a Collector"PDF (435 KiB). Technion Israel, Israel - India Steering Committee. Retrieved on 2007-03-15.
^ Altman, Talia; Dan Zaslavsky, Rami Guetta and Gregor Czisch (May 2006). "Evaluation of the potential of electricity and desalinated water supply by using technology of "Energy Towers" for Australia, America and Africa". http://www.ecmwf.int/about/special_projects/czisch_enrgy-towers-global-potential/report_2006_extended.pdf. Retrieved on 2007-03-18.
^ Altmann, T.; Y. Carmel, R. Guetta, D. Zaslavsky, Y. Doytsher (June 2005). "Assessment of an "Energy Tower" potential in Australia using a mathematical model and GIS" (PDF). Solar Energy (Elsevier Ltd.) 78 (6): 799–808. doi:10.1016/j.solener.2004.08.025. http://envgis.technion.ac.il/publications/energy%20tower%20potential.pdf. Retrieved on 2007-03-12.
^ Czisch, Gregor (June 2005). "Evaluation of the global potential of energy towers". http://www.ecmwf.int/about/special_projects/czisch_enrgy-towers-global-potential/. Retrieved on 2007-03-13.
^ Czisch, Gregor (September 2001). "Aeroelectric Oasis System". Global Renewable Energy Potential, Approaches to its Use. http://www.iset.uni-kassel.de/abt/w3-w/folien/magdeb030901/folie_26.html. Retrieved on 2007-03-13.
^ Gutman, Per-Olof; Eran Horesh, Rami Guetta, Michael Borshchevsky (2003-04-29). "Control of the Aero-Electric Power Station - an exciting QFT application for the 21st century". International Journal of Robust and Nonlinear Control (John Wiley & Sons, Ltd.) 13 (7): 619–636. doi:10.1002/rnc.828.
^ Mills D (2004). "Advances in solar thermal electricity technology". Solar Energy 76 (1-3): 19–31. doi:10.1016/S0038-092X(03)00102-6.
^ Zaslavsky, Dan (2006). "Energy Towers". PhysicaPlus - Online magazine of the Israel Physical Society (Israel Physical Society) (7). http://physicaplus.org.il/zope/home/en/1124811264/1137833043_en. Retrieved on 2007-03-13.
^ Zwirn, Michael J. (January 1997). Energy Towers: Pros and Cons of the Arubot Sharav Alternative Energy Proposal. Arava Institute for Environmental Studies. Retrieved on 2006-12-22.
Zaslavsky, Dan (November, 1996). "Solar Energy Without a Collector". The 3rd Sabin Conference.
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