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Tidal power
Wave power
Wind power

Wave power refers to the energy of ocean surface waves and the capture of that energy to do useful work - including electricity generation, desalination, and the pumping of water (into reservoirs). Renewable energy is Energy generated from Natural resources mdashsuch as Sunlight, Wind, Rain, tides and geothermal Biomass refers to living and recently dead Biological material that can be used as fuel or for industrial production Geothermal power (from the Greek roots geo, meaning earth and therme, meaning heat is energy generated by heat stored in the earth or the collection Hydroelectricity is electricity generated by Hydropower, ie the production of power through use of the gravitational force of falling water Solar energy is the Light and radiant heat from the Sun that powers Earth 's Climate and Weather and sustains Life Tidal power, sometimes called tidal energy, is a form of Hydropower that converts the energy of Tides into electricity or other useful forms of power Wind Power is the conversion of wind energy into a useful form such as electricity using Wind turbines At the end of 2007 worldwide capacity of wind-powered generators was Ocean surface waves are Surface waves that occur on the Free surface of the Ocean. In Physics, mechanical work is the amount of Energy transferred by a Force. Electricity generation is the process of converting non-electrical Energy to Electricity. Desalination, desalinization, or desalinisation refers to any of several processes that remove excess salt and other Minerals from Water Wave power is a form of renewable energy. Renewable energy is Energy generated from Natural resources mdashsuch as Sunlight, Wind, Rain, tides and geothermal Though often co-mingled, wave power is distinct from the diurnal flux of tidal power and the steady gyre of ocean currents. In the various subfields of Physics, there exist two common usages of the term flux, both with rigorous mathematical frameworks Tidal power, sometimes called tidal energy, is a form of Hydropower that converts the energy of Tides into electricity or other useful forms of power An ocean current is continuous directed movement of Ocean water. Wave power generation is not a widely employed technology, and no commercial wave farm has yet been established. A wave farm or wave power farm is a collection of machines in the same location and used for the Generation of Wave power Electricity.

On December 18, 2007, Pacific Gas and Electric Company announced its support for plans to build America's first commercial wave power plant off the coast of Northern California. For the 1970s rock music band see Pacific Gas & Electric (band. The United States of America —commonly referred to as the [1] The plant will consist of eight buoys, 2 1/2 miles offshore, each buoy generating electricity as it rises and falls with the waves. The plant is scheduled to begin operating in 2012, generating a maximum of 2 megawatts of electricity. Each megawatt can power about 750 homes.

The world's first commercial wave farm is based in Portugal,[2] at the Aguçadora Wave Park, which consists of three 750 kW Pelamis devices. The Pelamis Wave Energy Converter is a technology that uses the motion of Ocean surface waves to create electricity Other plans for wave farms include a 3MW array of four 750 kW Pelamis devices in the Orkneys, off northern Scotland, and the 20MW Wave hub development off the north coast of Cornwall, England. Orkney (also known as the Orkney Islands or incorrectly the Orkneys) is an Archipelago in northern Scotland, situated 10 miles (16 km north Scotland ( Gaelic: Alba) is a Country in northwest Europethat occupies the northern third of the island of Great Britain. The Wave hub project is a Wave power research project The project will be developed approximately 10 miles off Hayle, the north coast of Cornwall, UK Cornwall ( Kernow ˈkɛɹnɔʊ is the most southwesterly county of England, on the Peninsula that lies to the west of the River Tamar England is a Country which is part of the United Kingdom. Its inhabitants account for more than 83% of the total UK population whilst its mainland

The north and south temperate zones have the best sites for capturing wave power. The prevailing westerlies in these zones blow strongest in winter. The Westerlies or the Prevailing Westerlies are the prevailing winds in the Middle latitudes between 30 and 60 degrees Latitude, blowing from

Contents

Physical concepts

When an object bobs up and down on a ripple in a pond, it experiences an elliptical trajectory.
When an object bobs up and down on a ripple in a pond, it experiences an elliptical trajectory.
Motion of a particle in an ocean wave. A = At deep water. The orbital motion of fluid particles decreases rapidly with increasing depth below the surface. B = At shallow water (ocean floor is now at B). The elliptical movement of a fluid particle flattens with decreasing depth. 1 = Propagation direction. 2 = Wave crest. 3 = Wave trough.
Motion of a particle in an ocean wave.
A = At deep water. The orbital motion of fluid particles decreases rapidly with increasing depth below the surface. In Physics, an orbit is the gravitationally curved path of one object around a point or another body for example the gravitational orbit of a planet around a star
B = At shallow water (ocean floor is now at B). The elliptical movement of a fluid particle flattens with decreasing depth.
1 = Propagation direction.
2 = Wave crest.
3 = Wave trough.
See Energy, Power and Work for more information on these important physical concepts. In Physics and other Sciences energy (from the Greek grc ἐνέργεια - Energeia, "activity operation" from grc ἐνεργός In Physics, power (symbol P) is the rate at which work is performed or energy is transmitted or the amount of energy required or expended for In Physics, mechanical work is the amount of Energy transferred by a Force. Physics (Greek Physis - φύσις in everyday terms is the Science of Matter and its motion.

Waves are generated by wind passing over the sea: as long as the waves propagate slower than the wind speed just above the waves, there is an energy transfer from the wind to the most energetic waves. Both air pressure differences between the upwind and the lee side of a wave crest, as well as friction on the water surface by the wind shear stress cause the growth of the waves. A crest is the point on a Wave with the greatest positive value or upward displacement in a Cycle. A shear stress, denoted \tau\ ( Tau) is defined as a stress which is applied Parallel or tangential to a face of a material [3] The wave height increases with increasing wind speed, duration since the wind started to blow, and of the fetch (the distance of open water that the wind has blown over), see Ocean surface wave. Ocean surface waves are Surface waves that occur on the Free surface of the Ocean.

In general, large waves are more powerful. Specifically, wave power is determined by wave height, wave speed, wavelength, and water density.

Wave size is determined by wind speed and fetch (the distance over which the wind excites the waves) and by the depth and topography of the seafloor (which can focus or disperse the energy of the waves). A given wind speed has a matching practical limit over which time or distance will not produce larger waves. This limit is called a "fully developed sea. "

Oscillatory motion is highest at the surface and diminishes exponentially with depth. Ocean surface waves are Surface waves that occur on the Free surface of the Ocean. However, for standing waves (clapotis) near a reflecting coast, wave energy is also present as pressure oscillations at great depth, producing microseisms. A standing wave, also known as a stationary wave, is a Wave that remains in a constant position In Hydrodynamics, the clapotis (from "lapping of water" is a non-breaking Standing wave pattern caused for example by the reflection of a traveling surface [3] These pressure fluctuations at greater depth are too small to be interesting from the point of view of wave power.

The waves propagate on the ocean surface, and the wave energy is also transported horizontally with the group velocity. The group velocity of a Wave is the Velocity with which the variations in the shape of the wave's amplitude (known as the modulation or envelope The mean transport rate of the wave energy through a vertical plane of unit width, parallel to a wave crest, is called the wave energy flux (or wave power, which must not be confused with the actual power generated by a wave power device). A crest is the point on a Wave with the greatest positive value or upward displacement in a Cycle. In the various subfields of Physics, there exist two common usages of the term flux, both with rigorous mathematical frameworks In deep water, if the water depth is larger than half the wavelength, the wave energy flux is:

P = \frac{\rho g^2}{64\pi} H_{m0}^2 T \approx \left(0.5 \frac{\text{kW}}{\text{m}^3 \cdot \text{s}} \right) H_{m0}^2\; T,

see below ,where:

The above formula states that wave power is proportional to the wave period and to the square of the wave height. In Algebra, the square of a number is that number multiplied by itself When the significant wave height is given in meter, and the wave period in second, the result is the wave power in kW (kilo watt) per meter wavefront length. [5][6]

In major storms, the largest waves offshore are about 15 meters high and have a period of about 15 seconds. According to the above deep-water formula, such waves carry about 3. 2 MW/m of power across each meter of wavefront. At moderate conditions, for a wave height of about 3 m and a wave period of 8 seconds, a wave power location will have an average flux much less than this: about 70 kW/m.

An effective wave power device captures as much as possible of the wave energy flux. As a result the waves will be of lower height in the region behind the wave power device.

Wave energy and wave energy flux

In a sea state, the energy per unit area of gravity waves on the water surface is proportional to the wave height squared, according to linear wave theory:[3][4]

E=\frac{1}{16}\rho g H_{m0}^2,

where E is the mean wave energy per unit horizontal area (J/m2), the sum of kinetic energy and potential energy. A sea state includes the height, Period, and character of waves on the surface of a large body of water In Physics and other Sciences energy (from the Greek grc ἐνέργεια - Energeia, "activity operation" from grc ἐνεργός In Fluid dynamics, gravity waves are waves generated in a Fluid medium or at the interface between two media (e The kinetic energy of an object is the extra Energy which it possesses due to its motion Potential energy can be thought of as Energy stored within a physical system The potential energy is equal to the kinetic energy,[3] both contributing half to the wave energy E, as can be expected from the equipartition theorem. In classical Statistical mechanics, the equipartition theorem is a general formula that relates the Temperature of a system with its average energies

As the waves propagate, their energy is transported. The energy transport velocity is the group velocity. The group velocity of a Wave is the Velocity with which the variations in the shape of the wave's amplitude (known as the modulation or envelope As a result, the wave energy flux, through a vertical plane of unit width perpendicular to the wave propagation direction, is equal to:[7][3]

P = E\, c_g, \, \

with cg the group velocity (m/s). In the various subfields of Physics, there exist two common usages of the term flux, both with rigorous mathematical frameworks Due to the dispersion relation for water waves under the action of gravity, the group velocity depends on the wavelength λ, or equivalently, on the wave period T. In Fluid dynamics, dispersion of water waves generally refers to Frequency dispersion In Physics wavelength is the distance between repeating units of a propagating Wave of a given Frequency. Frequency is a measure of the number of occurrences of a repeating event per unit Time. Further, the dispersion relation is a function of the water depth h. As a result, the group velocity behaves differently in the limits of deep and shallow water, and at intermediate depths:[3][4]

Deep water corresponds with a water depth larger than half the wavelength, which is the common situation in the sea and ocean. In Physics wavelength is the distance between repeating units of a propagating Wave of a given Frequency. In deep water, longer period waves propagate faster and transport their energy faster. The deep-water group velocity is half the phase velocity. The phase velocity (or phase speed) of a Wave is the rate at which the phase of the wave propagates in space In shallow water, for wavelengths larger than twenty times the water depth, as found quite often near the coast, the group velocity is equal to the phase velocity. When waves travel into areas of shallow water, they begin to be affected by the Ocean bottom [9]

Modern Technology

Wave power devices are generally categorized by the method used to capture the energy of the waves. They can also be categorized by location and power take-off system. Method types are point absorber or buoy; surfacing following or attenuator; terminator, lining perpendicular to wave propagation; oscillating water column; and overtopping. Locations are shoreline, nearshore and offshore. Types of power take-off include: hydraulic ram, elastomeric hose pump, pump-to-shore, hydroelectric turbine, air turbine,[10] and linear electrical generator. A hydraulic ram is a cyclic water pump powered by Hydropower. A peristaltic pump is a type of positive displacement Pump used for pumping a variety of Fluids The fluid is contained within a flexible tube fitted inside a Hydroelectricity is electricity generated by Hydropower, ie the production of power through use of the gravitational force of falling water A linear motor or linear induction motor is essentially a multi-phase Alternating current (AC Electric motor that has had its Stator "unrolled" Some of these designs incorporate parabolic reflectors as a means of increasing the wave energy at the point of capture. A parabolic reflector (or dish or mirror) is a Parabola -shaped reflective device used to collect or distribute Energy such as

These are descriptions of some wave power systems:

Challenges

These are some of the challenges to deploying wave power devices:

Wave farms

2 of 3 P-750 machines in the harbour of Peniche/ Portugal
2 of 3 P-750 machines in the harbour of Peniche/ Portugal
See also: Wave farm

Portugal continues to plan the world's first commercial wave farm, the Aguçadora Wave Park near Póvoa de Varzim, though efforts to install three Pelamis P-750 machines generating 2. A wave farm or wave power farm is a collection of machines in the same location and used for the Generation of Wave power Electricity. Portugal, officially the Portuguese Republic (República Portuguesa is a country on the Iberian Peninsula. Póvoa de Varzim (ˈpɔvuɐ dɨ vɐɾˈzĩ locally ˈpɔβuɐ dɨ bɐɾˈziŋ is a Portuguese city in the Northern Region and sub-region of Greater Porto The Pelamis Wave Energy Converter is a technology that uses the motion of Ocean surface waves to create electricity 25 MW have yet to come to fruition. [23][24] Initial costs are put at 8. 5 million euro. Please update other articles as well to avoid contradiction within Wikipedia e Subject to successful operation, a further 70 million euro is likely to be invested before 2009 on a further 28 machines to generate 72. 5 MW. [25]

Funding for a wave farm in Scotland was announced on February 20, 2007 by the Scottish Executive, at a cost of over 4 million pounds, as part of a £13 million funding packages for marine power in Scotland. Scotland ( Gaelic: Alba) is a Country in northwest Europethat occupies the northern third of the island of Great Britain. The Scottish Government (SG ( Scottish Gaelic: Riaghaltas na h-Alba) is the executive arm of the government of Scotland. The Pound Sterling ( symbol £; ISO code: GBP) subdivided into 100 pence (singular penny) is the Currency The production of renewable energy in Scotland is an issue that has come to the fore in technical economic and political terms during the opening years of the 21st century The farm will be the world's largest with a capacity of 3MW generated by four Pelamis machines. [26]

Funding has also been announced for the development of a Wave hub off the north coast of Cornwall, England. The Wave hub project is a Wave power research project The project will be developed approximately 10 miles off Hayle, the north coast of Cornwall, UK The Wave hub will act as giant extension cable, allowing arrays of wave energy generating devices to be connected to the electricity grid. The Wave hub project is a Wave power research project The project will be developed approximately 10 miles off Hayle, the north coast of Cornwall, UK The Wave hub will initially allow 20MW of capacity to be connected with potential expansion to 40MW. The Wave hub project is a Wave power research project The project will be developed approximately 10 miles off Hayle, the north coast of Cornwall, UK Four device manufacturers have so far expressed interest in connecting to the Wave hub. The Wave hub project is a Wave power research project The project will be developed approximately 10 miles off Hayle, the north coast of Cornwall, UK

The scientists have calculated that wave energy gathered by this generator will be enough to power up to 7,500 households. Savings that the Cornwall wave power generator will bring are significant: about 300,000 tons of carbon dioxide in the next 25 years. [27]

Potential

Good wave power locations have a flux of about 50 kilowatts per metre of shoreline. Capturing 20 percent of this, or 10 kilowatts per metre, is plausible. Assuming very large scale deployment of (and investment in) wave power technology, coverage of 5000 kilometres of shoreline (worldwide) is plausible. Therefore, the potential for shoreline-based wave power is about 50 gigawatts. Deep water wave power resources are truly enormous, but perhaps impractical to capture.

Discussion of Salter's Duck

While historic references to the power of waves do exist, the modern scientific pursuit of wave energy was begun in the 1970s by Professor Stephen Salter of the University of Edinburgh, Scotland in response to the Oil Crisis. The University of Edinburgh (Oilthigh Dhùn Èideann founded in 1582 is a renowned centre for teaching and research in Edinburgh, Scotland, UK. Scotland ( Gaelic: Alba) is a Country in northwest Europethat occupies the northern third of the island of Great Britain.

His invention, Salter's Edinburgh Duck, continues to be the machine against which all others are measured. In small scale controlled tests, the Duck's curved cam-like body can stop 90% of wave motion and can convert 90% of that to electricity. [28] While it continues to represent the most efficient use of available material and wave resources, the machine has never gone to sea, primarily because its complex hydraulic system is not well suited to incremental implementation, and the costs and risks of a full-scale test would be high. Most of the designs being tested currently absorb far less of the available wave power, and as a result their Mass to Power Ratios remain far away from the theoretical maximum.

According to sworn testimony before the House of Parliament, The UK Wave Energy program was shut down on March 19, 1982, in a closed meeting,[29] the details of which remain secret. The members of the meeting were recruited largely from the nuclear and fossil fuels industries, and the wave programme manager, Clive Grove-Palmer, was excluded.

An analysis[30] of Salter's Duck resulted in a miscalculation of the estimated cost of energy production by a factor of 10, an error which was only recently identified. Some wave power advocates believe that this error, combined with a general lack of enthusiasm for renewable energy in the 1980s (after oil prices fell), hindered the advancement of wave power technology. [31]

See also

Renewable energy

Renewable energy effectively uses natural resources such as sunlight, wind, rain, tides and geothermal heat, which are naturally replenished. Renewable energy technologies range from solar power, wind power, hydroelectricity/micro hydro, biomass and biofuels for transportation.

Main article: Renewable energy

Ocean energy

Other renewable energy

Other

Patents

References

  1. ^ Nauman, Matt. Renewable energy is Energy generated from Natural resources mdashsuch as Sunlight, Wind, Rain, tides and geothermal The Pelamis Wave Energy Converter is a technology that uses the motion of Ocean surface waves to create electricity A wave farm or wave power farm is a collection of machines in the same location and used for the Generation of Wave power Electricity. Tidal power, sometimes called tidal energy, is a form of Hydropower that converts the energy of Tides into electricity or other useful forms of power The Oceans have a tremendous amount of energy and are close to many if not most concentrated populations Ocean thermal energy conversion ( OTEC) is a method for generating electricity which uses the Temperature difference that exists between deep and shallow waters to Tidal power, sometimes called tidal energy, is a form of Hydropower that converts the energy of Tides into electricity or other useful forms of power Wind Power is the conversion of wind energy into a useful form such as electricity using Wind turbines At the end of 2007 worldwide capacity of wind-powered generators was Solar energy is the Light and radiant heat from the Sun that powers Earth 's Climate and Weather and sustains Life Hydroelectricity is electricity generated by Hydropower, ie the production of power through use of the gravitational force of falling water Geothermal power (from the Greek roots geo, meaning earth and therme, meaning heat is energy generated by heat stored in the earth or the collection Biomass refers to living and recently dead Biological material that can be used as fuel or for industrial production "PG&E to invest in wave energy", San Jose Mercury News, 2007-12-18. The San Jose Mercury News is the major daily Newspaper in San Jose California and Silicon Valley. Year 2007 ( MMVII) was a Common year starting on Monday of the Gregorian calendar in the 21st century. Events 218 BC - Second Punic War: Battle of the Trebia - Hannibal 's Carthaginian forces defeat those of the Retrieved on 2007-12-18. Year 2007 ( MMVII) was a Common year starting on Monday of the Gregorian calendar in the 21st century. Events 218 BC - Second Punic War: Battle of the Trebia - Hannibal 's Carthaginian forces defeat those of the  
  2. ^ Wave power scientist enthused by green energy
  3. ^ a b c d e f Phillips, O. M. (1977). The dynamics of the upper ocean, 2nd edition, Cambridge University Press. ISBN 0 521 29801 6.  
  4. ^ a b c Goda, Y. (2000). Random Seas and Design of Maritime Structures. World Scientific. ISBN 978 981 02 3256 6.  
  5. ^ Wave Power
  6. ^ Technology White Paper on Wave Energy Potential on the U.S. Outer Continental Shelf
  7. ^ Reynolds, O. (1877). Osborne Reynolds ( 23 August, 1842 &ndash 21 February, 1912) was a prominent innovator in the understanding of Fluid dynamics. "On the rate of progression of groups of waves and the rate at which energy is transmitted by waves". Nature 16: 343–44.  
    Lord Rayleigh (J. W. Strutt) (1877). John William Strutt 3rd Baron Rayleigh OM (12 November 1842 &ndash 30 June 1919 was an English Physicist who with William Ramsay, discovered "On progressive waves". Proceedings of the London Mathematical Society 9: 21–26.   Reprinted as Appendix in: Theory of Sound 1, MacMillan, 2nd revised edition, 1894.
  8. ^ For determining the group velocity the angular frequency ω is considered as a function of the wavenumber k, or equivalently, the period T as a function of the wavelength λ.
  9. ^ R. G. Dean and R. A. Dalrymple (1991). Water wave mechanics for engineers and scientists, Advanced Series on Ocean Engineering 2. World Scientific, Singapore. ISBN 978-9810204204.   See page 64–65.
  10. ^ Embedded Shoreline Devices and Uses as Power Generation Sources Kimball, Kelly, November 2003
  11. ^ PNGC Power
  12. ^ Agreement to Develop Wave Power Park in Oregon from www. renewableeneregyaccess. com February 2007
  13. ^ OPT | Ocean Power Technologies
  14. ^ Wave energy contract goes abroad BBC May 2005
  15. ^ Orkney to get 'biggest' wave farm BBC February 2007
  16. ^ Wave Energy: Figueira da Foz, Portugal Finavera Renewables
  17. ^ Wave Energy Device Deployed
  18. ^ CETO Overview Carnegie Corporation
  19. ^ The power of the surf Department of the Environment and Water Resources, Australina Greenhouse Office
  20. ^ Dead Link: http://www.energetech.com.au/content/port.html
  21. ^ Directory:Neo-AeroDynamic - PESWiki
  22. ^ http://www.oceannavitas.com/technology.html/
  23. ^ Sea machine makes waves in Europe BBC March 2006
  24. ^ Wave energy contract goes abroad BBC May 2005
  25. ^ Primeiro parque mundial de ondas na Póvoa de Varzim (Portuguese Newspaper) Jornal de Noticias Lopes, Ricardo David May 2006
  26. ^ Orkney to get 'biggest' wave farm BBC February 2007
  27. ^ Go-ahead for £28m Cornish wave farm
  28. ^ Endinburgh Wave Energy Project
  29. ^ Memorandum submitted by Professor S H Salter, Department of Mechanical Engineering, University of Edinburgh House of Commons, UK Parliament
  30. ^ Water Power Devices
  31. ^ The untimely death of Salter's Duck from GreenLeftOnline July 1992

Sources and external articles

Institutional links

News articles and compilations

Wave climate and forecasts

Demonstration of physical concepts

Company and institutional links with technology descriptions

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