“Mist lift”的意思、由来-开放百科全书

The Mist lift, Mist flow or Steam lift pump is a gas lift technique of lifting water used in a form of Ocean Thermal Energy Conversion (OTEC) where water falls to operate a hydro-electric turbine. The water is pumped from the level it drops to using rising steam which is combined into a multiphase flow.^[1] Independent of energy production, the technique can be used simply as a thermally powered pump used to raise ocean water from depths for unspecified uses.^[2]

Operation

As in other open cycle OTEC schemes, the technique involves boiling seawater under low atmospheric pressure. The scheme can take many forms so for illustration a particular form will be described and a section below will list details of alternate forms.

The prerequisite for mist lift is that a significant thermal gradient exists. Typically warm surface water is expected to be near {{convert|25|C|F}}. Cold water from depth needs to be in the vicinity of {{convert|5|C|F}}.^[3]^[4] A common set of embodiments uses a floating concrete vessel most of which is submerged below the surface. Large volumes of warm surface seawater fall by gravity from a substantial height such as {{convert|100|m|ft}} to generate electricity from a hydro-electric turbine at the base of the structure. "Mist lift" gets its name by the gas lift technique used to pump the water back out of the structure. Due to the partial vacuum within the structure, warm sea water from the surface boils, creating large volumes of rising steam. {{convert|10|m|ft}} to 20 metres up, jets of cold sea water are sprayed upwards into the vapor, rapidly contracting it and thereby creating significantly lower pressure at the top of the structure than at the base. This causes the multi-phase steam-water "mist" to be lifted with great velocity to the top of the structure where it exits.^[1]^[5]

Details of variations

Design issues

Cost evaluation

Mist Lift utilizing thermal temperature differences does not require large pumps and heat exchangers as in other types of OTEC. In closed systems, the expense of the exchangers represents the largest cost of the OTEC plant, with a 100MW plant requiring 200 exchangers the size of 20 foot shipping containers.^[9]

In 2010, Makai Ocean Engineering was contracted to construct computer models to evaluate whether a Mist lift power generation plant would be competitive with the dominant OTEC approaches being pursued by researchers. The study estimated that a Mist lift power generation plant could be 17% to 37% cheaper than a closed cycle plant.^[10] In submerged mist flow plants, close to 40% of the cost is devoted to creating a strong enough pressure vessel.^[2]

References

1. ^¹²{{ citation | country-code = US | patent-number = 4441321| description =patent | title = Compact mist flow power generator | publication-date = 1984-04-10 | inventor-first = Stuart L. | inventor-last = Ridgway }}
2. ^¹²³{{ citation | country-code = US | patent-number = 4603553| description =patent | title = Ballistic cold water pipe | publication-date = 1984-12-11 | inventor-first = Stuart L. | inventor-last = Ridgway }}
3. ^¹{{citation |title=Periodic explosions by positive feedback in a rising foam column |last1= Zener |first1= Clarence |last2= Noriega |first2= Jaime | journal= Proceedings of the National Academy of Sciences |volume=79 |pages= 3384–3386 |url=http://www.pnas.org/content/79/10/3384.full.pdf |format=pdf |date= May 1982 |accessdate= June 2012 |doi=10.1073/pnas.79.10.3384|bibcode=1982PNAS...79.3384Z |pmc=346420 }}
4. ^¹{{ citation | country-code = US | patent-number = 4216657 | description =patent | title = Mist flow ocean thermal energy process | publication-date = 1980-08-12 | inventor-first = Stuart L. | inventor-last = Ridgway }}
5. ^¹{{citation|first1=Stuart L.|last1=Ridgway|url=http://www.otecnews.org/articles/mistlift.html|archive-url=https://web.archive.org/web/20051226170157/http://www.otecnews.org/articles/mistlift.html|dead-url=yes|archive-date=26 December 2005|title=Out of Gas? Refuel with Mist lift Ocean Thermal Energy|publisher=OTEC News|date=19 April 2005|accessdate=June 2012}}
6. ^¹{{ citation | country-code = US | patent-number = 6202417 | description =patent | title = Ocean thermal gradient hydraulic power plant | publication-date = 2001-03-20 | inventor-first = Earl J. | inventor-last = Beck }}
7. ^{{citation |last1=Zener|first1=Clarence |last2=Fetkovich |first2=John |title=Foam Solar Sea Power Plant |journal=Science |volume=189 |number=4199 |date=25 July 1975 |pages=294–5 |doi=10.1126/science.189.4199.294 |pmid=17813708|bibcode=1975Sci...189..294Z }}
8. ^{{citation|journal=Journal of Solar Energy Engineering |last1=Lee |first1= C. K. B. |last2= Ridgway |first2= Stuart |title=Vapor/Droplet Coupling and the Mist Flow (OTEC) Cycle |volume=105 |date= May 1983 |url=http://library.greenocean.org/oteclibrary/otecdesigns/mistliftotec/vapor_mistlift_otec.pdf}}
9. ^{{citation|contribution=Comparison Of Aluminum Alloys And Manufacturing Processes Based On Corrosion Performance For Use In OTEC Heat Exchangers|last1=Eldred|first1=M. |last2=Landherr |first2= A. |last3=Chen |first3=I.C. |doi=10.4043/20702-MS | url=http://www.onepetro.org/mslib/servlet/onepetropreview?id=OTC-20702-MS | title= Offshore Technology Conference 2010 (OTC 2010) |publisher= Curran Associates, Inc. | isbn=9781617384264 | date= July 2010 |accessdate= May 28, 2010}}
10. ^{{citation |url=http://www.recovery.gov/Transparency/RecipientReportedData/pages/RecipientProjectSummary508.aspx?AwardIdSur=91379 |title=Recovery.gov award summary: Makai Ocean Engineering July 1 - September 30, 2011. |accessdate=May 2012 |deadurl=yes |archiveurl=https://archive.is/20121214180903/http://www.recovery.gov/Transparency/RecipientReportedData/pages/RecipientProjectSummary508.aspx?AwardIdSur=91379 |archivedate=December 14, 2012 |df= }}

Operation

Details of variations

Design issues

Cost evaluation

References

External links