Ocean thermal energy conversion - Revision history

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Kjstenho at 20:50, 3 September 2015

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	[[Category:Done 2015-08-21]]		[[Category: Done 2015-09-06]]
	<onlyinclude>'''Ocean thermal energy conversion''' or simply '''OTEC''' is the process of using the ocean itself as a [[solar collector]]. This technology is still highly theoretical, and utilizes the slight [[temperature]] gradient between the warm surface of the ocean and the cooler water deeper down.</onlyinclude> This technology operates in a similar way that [[solar pond]]s do but on a much larger scale. Although there is a temperature gradient, the overall temperature difference with depth is fairly small. In waters deeper than 1000 [[meter]]s the temperature change might only amount to [[celsius\|20°C]].<ref name=boyle>G. Boyle. ''Renewable Energy: Power for a Sustainable Future'', 2nd ed. Oxford, UK: Oxford University Press, 2004.</ref> Because of this very slight temperature gradient the [[efficiency]] of these systems are likely to be extremely low - only about 2%.<ref name=wolfson/>		<onlyinclude>'''Ocean thermal energy conversion''' or simply '''OTEC''' is the process of using the ocean itself as a [[solar collector]]. This [[technology]] is still highly theoretical, and utilizes the slight [[temperature]] gradient between the warm surface of the ocean and the cooler water deeper down.</onlyinclude> This technology operates in a similar way that [[solar pond]]s do but on a much larger scale. Although there is a temperature gradient, the overall temperature difference with depth is fairly small. In waters deeper than 1000 [[meter]]s the temperature change might only amount to [[celsius\|20°C]].<ref name=boyle>G. Boyle. ''Renewable Energy: Power for a Sustainable Future'', 2nd ed. Oxford, UK: Oxford University Press, 2004.</ref> Because of this very slight temperature gradient the [[efficiency]] of these systems are likely to be extremely low - only about 2%.<ref name=wolfson/>

	Although the technology is still fairly theoretical there have been more large scale experiments recently. These large scale experiments have taken place in the Pacific ocean and have had moderate success. Even though the tests have been partially successful, the engineering required to make these technologies viable is still a ways off in the future. The amount of [[water]] that needs to be pumped is a major issue, as a single OTEC station producing [[watt\|10 MW]] of [[electricity]] would need to pump around 500 [[cubic meter]]s of water per [[second]].<ref name=boyle/>		Although the technology is still fairly theoretical there have been more large scale experiments recently. These large scale experiments have taken place in the Pacific ocean and have had moderate success. Even though the tests have been partially successful, the engineering required to make these technologies viable is still a ways off in the future. The amount of [[water]] that needs to be pumped is a major issue, as a single OTEC station producing [[watt\|10 MW]] of [[electricity]] would need to pump around 500 [[cubic meter]]s of water per [[second]].<ref name=boyle/>
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	[[File:Otec_Closed_Diagram_in_English.JPG\|400px\|framed\|center\|Figure 1. A diagram showing how an OTEC facility uses ocean water to generate electricity.<ref>Wikimedia Commons. (August 13, 2015). ''OTEC Closed'' [Online]. Available: https://upload.wikimedia.org/wikipedia/commons/b/bd/Otec_Closed_Diagram_in_English.JPG</ref>]]		[[File:Otec_Closed_Diagram_in_English.JPG\|400px\|framed\|center\|Figure 1. A diagram showing how an OTEC facility uses ocean water to generate electricity.<ref>Wikimedia Commons. (August 13, 2015). ''OTEC Closed'' [Online]. Available: https://upload.wikimedia.org/wikipedia/commons/b/bd/Otec_Closed_Diagram_in_English.JPG</ref>]]

	OTEC power plants operate like any other thermal [[power plant]], however they require the use of an [[organic Rankine cycle]]. In these plants, warm surface sea water heats up some fluid with a low boiling point. The fluid needs a low boiling point because the surface water itself isn't very warm, so generally [[ammonia]] is used (which has a boiling point of -33 °C at [[atmospheric pressure]]). The warm water heats this fluid, turning it into a gas that drives a turbine to [[electricity generation\|generate electricity]]. This vapour then comes into contact with a cold reservoir, chilled with cold water from below the ocean surface. This condenses the vapour and the process begins again.<ref name=boyle/>		OTEC power plants operate like any other thermal [[power plant]], however they require the use of an [[organic Rankine cycle]]. In these plants, warm surface sea water heats up some [[fluid]] with a low [[boiling point]]. The fluid needs a low boiling point because the surface water itself isn't very warm, so generally [[ammonia]] is used (which has a boiling point of -33 °C at [[atmospheric pressure]]). The warm water heats this fluid, turning it into a [[gas]] that drives a [[turbine]] to [[electricity generation\|generate electricity]]. This vapour then comes into contact with a cold [[reservoir]], chilled with cold water from below the ocean surface. This condenses the vapour and the process begins again.<ref name=boyle/>

	==Environmental Impacts==		==Environmental Impacts==

J.williams: 1 revision imported

2015-08-26T21:31:54Z

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J.williams at 18:50, 24 August 2015

2015-08-24T18:50:46Z

New page

[[Category:Done 2015-08-21]]
<onlyinclude>'''Ocean thermal energy conversion''' or simply '''OTEC''' is the process of using the ocean itself as a [[solar collector]]. This technology is still highly theoretical, and utilizes the slight [[temperature]] gradient between the warm surface of the ocean and the cooler water deeper down.</onlyinclude> This technology operates in a similar way that [[solar pond]]s do but on a much larger scale. Although there is a temperature gradient, the overall temperature difference with depth is fairly small. In waters deeper than 1000 [[meter]]s the temperature change might only amount to [[celsius|20°C]].<ref name=boyle>G. Boyle. ''Renewable Energy: Power for a Sustainable Future'', 2nd ed. Oxford, UK: Oxford University Press, 2004.</ref> Because of this very slight temperature gradient the [[efficiency]] of these systems are likely to be extremely low - only about 2%.<ref name=wolfson/>

Although the technology is still fairly theoretical there have been more large scale experiments recently. These large scale experiments have taken place in the Pacific ocean and have had moderate success. Even though the tests have been partially successful, the engineering required to make these technologies viable is still a ways off in the future. The amount of [[water]] that needs to be pumped is a major issue, as a single OTEC station producing [[watt|10 MW]] of [[electricity]] would need to pump around 500 [[cubic meter]]s of water per [[second]].<ref name=boyle/>

==How it Works==
OTEC power plants could be built in several different ways, either as platforms similar to [[offshore oil rig]]s or as free floating structures. OTEC plants could also be constructed as large ships that would move throughout tropical oceans to find areas with the largest temperature differences. Practically speaking, it makes the most sense to put OTEC facilities in tropical areas as these regions of the ocean see the largest temperature differences.<ref name=wolfson/>

[[File:Otec_Closed_Diagram_in_English.JPG|400px|framed|center|Figure 1. A diagram showing how an OTEC facility uses ocean water to generate electricity.<ref>Wikimedia Commons. (August 13, 2015). ''OTEC Closed'' [Online]. Available: https://upload.wikimedia.org/wikipedia/commons/b/bd/Otec_Closed_Diagram_in_English.JPG</ref>]]

OTEC power plants operate like any other thermal [[power plant]], however they require the use of an [[organic Rankine cycle]]. In these plants, warm surface sea water heats up some fluid with a low boiling point. The fluid needs a low boiling point because the surface water itself isn't very warm, so generally [[ammonia]] is used (which has a boiling point of -33 °C at [[atmospheric pressure]]). The warm water heats this fluid, turning it into a gas that drives a turbine to [[electricity generation|generate electricity]]. This vapour then comes into contact with a cold reservoir, chilled with cold water from below the ocean surface. This condenses the vapour and the process begins again.<ref name=boyle/>

==Environmental Impacts==
The primary concern with OTEC facilities is the potential harm to marine life that could occur as a result of the mixing of warm and cool ocean waters. This mixing changes the temperature gradient of the ocean in a specific area, disrupting the ecosystem. For example, nutrients that are brought to the surface with the cold deep water could increase the number of fish or lead to [[algae]] blooms.<ref name=wolfson>R. Wolfson. ''Energy, Environment and Climate'', 2nd ed. New York, U.S.A.: Norton, 2012</ref> If these facilities are large scale, the average ocean surface temperature could even be affected and this would lead to changes in the [[weather]], [[climate]], and ocean circulation.<ref name=wolfson/>

==References==
{{reflist}}[[Category:Uploaded]]