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Posts Tagged ‘Orkney’

The Engineer UK, July 6 2010

Aquamarine Power and AWS Ocean Energy today secured approximately £4.39m to continue development of their wave energy devices.

The WATERS fund (Wave and Tidal Energy: Research, Development and Demonstration Support) has provided Aquamarine Power with more than £3m to develop its 2.4MW Oyster demonstration project in Scotland while AWS Ocean Energy received £1.39m to develop its AWS-III surface-floating wave power device.

Phased installation of the Oyster 2 project will begin at the European Marine Energy Centre (EMEC) in Orkney in Summer 2011. In-depth coverage of Oyster from The Engineer’s 2009 Awards Supplement can be read here.

The Oyster demonstration project will consist of three 800kW hinged flaps, each measuring 26m by 16m. The flaps are moved by the motion of near shore waves, which in turn drive two hydraulic pistons that push high-pressure water onshore to drive a conventional hydro-electric turbine.

Oyster 2 Wave Energy Converter

Aquamarine Power claims each flap will deliver 250 per cent more power than the original Oyster prototype, which was successfully deployed at EMEC in 2009.

The three devices will be linked to a single onshore 2.4MW hydro-electric turbine. The new devices incorporate modifications that are expected to facilitate the production of more energy, be simpler to install and easier to maintain.

AWS Ocean Energy will use its funding to further develop the AWS-III device, a ring-shaped, multi-cell, surface-floating wave power system.

It is claimed that a single utility-scale AWS-III, measuring around 60m in diameter, will be capable of generating up to 2.5MW of continuous power.

Scale testing of the AWS-III on Loch Ness is currently being carried out to provide design data and confirm the AWS-III’s commercial potential.

The £15m WATERS scheme, which is run and administered by Scottish Enterprise, has been designed to support the construction and installation of pre-commercial full-scale wave and tidal stream device prototypes in Scottish waters.

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GAYATHRI VAIDYANATHAN, New York Times, March 2, 2010

Harnessing the ocean waves for emission-free power seems like a tidy concept, but the ocean is anything but tidy. Waves crash from multiple directions on a seemingly random basis, and converting the kinetic energy into electricity is a frontier of alternative energy research that requires grappling with large unknowns.

But with several utility companies and states, and in one case, the U.S. Navy, investing in wave power, or hydrokinetic energy, may not be too far off in the utility mix. At least two companies hope to reach commercial deployments within the next three to five years.

Off the coast of Orkney, Scotland, is the Oyster, a white- and yellow-flapped cylinder, 40 feet tall and firmly locked into the ocean’s bed. With a total of seven moving parts, two of which are pistons, it captures waves as they near the coast. Oyster funnels them into a pipe and carries the power inland to a hydroelectric power generator. The generator has been supplying the United Kingdom’s grid with 315 kilowatts of energy at peak power since October.

A farm of up to 100 Oysters could yield 100 megawatts, according to Aquamarine Power, the Scottish company that developed the technology.

“From an environmental perspective, in the sea you have a very simple machine that uses no oil, no chemicals, no electromagnetic radiation,” said Martin McAdam, CEO of Aquamarine.

The Oyster provides a tiny fraction of the 250 gigawatts of power that the water is capable of providing, including conventional hydroelectric energy by 2030, according to the United Nations. At least 25 gigawatts of that will come from marine renewables, according to Pike Research, a clean technology market research group. The non-conservative estimate is as much as 200 gigawatts. And 2015 will be the benchmark year to determine which of these estimates will be true.

The field of hydrokinetic power has a number of companies such as Aquamarine, all with unique designs and funded by utility companies, government grants and venture capitalists. If at least 50% of these projects come online by 2015, marine power could supply 2.7 gigawatts to the mix, according to Pike Research. A gigawatt is the electrical output of a large nuclear power plant.

‘PowerBuoy’ joins the Marines

There are six marine renewable technologies currently under development that aim to take advantage of ocean waves, tides, rivers, ocean currents, differences in ocean temperatures with depth, and osmosis.

“The energy landscape is going to be a mix of different energy sources, with an increasing proportion coming from renewables,” said Charles Dunleavy, CEO of Ocean Power Technologies, a New Jersey-based research group also developing wave energy. “We aim to be a very big part of this.”

The company has been testing its wave energy device, called the PowerBuoy, in the ocean since 2005. It recently launched another device a mile offshore from the island of Oahu in Hawaii and connected it to the power grid of the U.S. Marine Corps base. It now supplies 40 kilowatts of energy at peak, enough to power about 25 to 30 homes.

“The Navy wants to reduce its reliance on imported fossil fuel; they have a strong need to establish greater energy independence,” said Dunleavy.

The buoy captures the energy from right-sized waves (between 3 and 22 feet tall), which drive a hydraulic pump. The pump converts the motion into electricity in the ocean using a generator embedded into its base. A subsea cable transfers the power to the electrical grid. A buoy farm of 30 acres could yield 10 megawatts of energy, enough to supply 8,000 homes, said Dunleavy.

The structures rise 30 feet above water, and extend 115 feet down. They would not be a problem for commercial trawlers, which are farther offshore, or for ship navigation lanes, said Dunleavy. Recreational boaters, however, may have to watch out.

‘Oyster’ competes with the ‘top end of wind’

In comparison with a system such as the Oyster that brings water ashore to power turbines, creating electricity in the ocean is more efficient, said Dunleavy. “You lose a lot of energy to friction,” he said.

But Aquamarine’s system of having onshore power generation will cut down on maintenance costs, according to McAdam. Operation costs are expected to consume as much as 40% of the budget of operating a marine power plant, according to Pike Research.

Ocean Power is already selling its device for individual commercial use and building larger units of 150 kilowatts off the West Coast of the United States and for the utility company Iberdrola’s unit in Spain.

It is also developing the first wave power station under the Department of Energy’s stimulus program at Reedsport, Ore., according to Dunleavy. The farm, which currently has a 150-kilowatt unit, could grow by nine additional buoys.

And as for price, which is a major concern, Dunleavy said that cost compares with other renewables.

“It is cheaper than solar thermal and photovoltaics, and in the range of biomass,” he said. “It is at the top end of wind.”

The Oyster is also aiming to position itself as an alternative to wind power for utilities. McAdam said that by 2013, his company hopes to be a competitor to offshore wind installations. And by 2015, he hopes to compete with onshore wind.

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Hydro Review, August 18, 2009

aquamarine-power_fb8xa_69Off the north coast of Scotland in waters 10 to 12 meters deep, ocean energy developer Aquamarine Power Ltd. has bolted its Oyster wave energy converter to the ocean floor and expects to be generating power by year’s end.

A team of offshore professionals eased the 194-ton converter into the sea at the European Marine Energy Center in the Orkney Islands. “Getting Oyster into the water and connected to the seabed was always going to be the most difficult step,” said Aquamarine CEO Martin McAdam. “Its completion is a real credit to everyone who has worked hard on planning and executing this major engineering feat on schedule.”

The Oyster is designed to capture energy from near-shore waves. The system includes an oscillating pump fitted with double-acting water pistons. Each wave activates the pump, delivering high-pressure water by pipeline to an onshore turbine that generates electricity. All electrical components of the Oyster are onshore, making it durable enough to withstand Scotland’s rough seas, McAdam said.

Marine constructor Fugro Seacore installed the Oyster converter under a $2.9 million contract.

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MendoCoastCurrent, August 4, 2009

oyster_prototype_device_aquamarine_powerOyster nearshore wave energy technology from Aquamarine Power is in the process of being placed on the seabed in the Atlantic off the coast of the Orkney Islands, Scotland for trials in autumn 2009.

The Oyster is based on a large, hydraulic oscillator fitted with pistons and activated by waves.  The oscillation pumps pressurized water through a pipeline to the shore.  Onshore, conventional hydro-electric generators convert the high-pressure water into electricity.

The concept is based on research from Queen’s University in Belfast. “Oyster’s technology is highly innovative because it relies on simplicity,” says Ronan Doherty, CTO at Aquamarine Power.

“Its offshore component – a highly reliable flap with minimal submerged moving parts – is the key to its success when operating in seas vulnerable to bad weather where maintenance can be very difficult.”  Doherty adds that as there is no underwater generator, electronics or gearbox and all the power generation equipment in onshore, where it is easily accessible.

Oyster technology is best deployed in near-shore regions at depths of 26-52 feet, where wave action tends to be more consistent and less variable in direction. The smaller size of waves near the shore also maximizes the lifetime of the device and the consistency of power generation. Each Oyster has a peak capacity of 300-600 kW but is designed to be deployed in multiple arrays.

Although still in the early stages of development, Aquamarine Power believes Oyster has great potential. “Our computer modeling of coastlines suitable for this technology shows that Spain, Portugal, Ireland and the UK are ideal candidates in Europe,” says Doherty. “But globally there is huge scope in areas like the Northwest coast of the U.S. and coastlines off South Africa, Australia and Chile.”

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PETER BROWN, EnergyCurrent.com, February 16, 2009

stromnessOn a Monday morning in May last year, the Atlantic tide set a turbine in motion on the seabed off Orkney, and the energy captured was connected to the national grid. It was, said Jim Mather, Scotland’s Minister for Enterprise, Energy and Tourism, a “massive step forward”.

The amount of electricity generated may have been tiny, but for marine engineers the significance was huge. Their industry had stopped paddling and started to swim.

For small companies trying to get wave or tide devices off the drawing board and into the sea, many problems lie in wait. All turbines, whether they sit on the seabed or float, must withstand that once-in-a-century wave that could be a thousand times more powerful than the average. Conditions vary with the seasons and the seabed. A device that works in a fjord might not function in a firth. Rigorous, long-term testing is therefore vital.

“There are parallels with wind,” says Alan Mortimer, head of renewables policy at Scottish Power. “Many different types of turbine were proposed in the early Eighties. They boiled down to a small number of successful concepts. The same needs to happen with marine devices, but the difference is that they need to be full- size just to be tested.

“To get a reasonable number of prototypes into the water costs millions. What these small companies need is capital support.”

That, however, is hard to find. The Wave and Tidal Energy Support Scheme (Wates), which put GBP13.5 million into promising technologies, is now closed. Last year the Scottish Government offered the 10m Saltire Prize for a commercially viable scheme, but the Institution of Mechanical Engineers (IMechE), in its recent report Marine Energy: More Than Just a Drop in the Ocean?, called on the Government to provide another 40m.

This would go towards schemes to be tested at EMEC, the European Marine Energy Centre, which has two supported sites, with grid access, at Orkney. It was there that an Irish company, OpenHydro, made the grid breakthrough last year. “It’s desperately important that we grasp the nettle now,” says William Banks, IMechE’s president. “We have the micro-systems in place and I’d like to see them developed to the macro stage. However, unless we do that step by step, we’ll be in trouble.”

An estimated 50 teams are working around the world on marine energy. The danger is that Britain, and Scotland in particular, could lose the race, even though, as Alex Salmond, Scotland’s First Minister, says, “Scotland has a marine energy resource which is unrivalled in Europe.”

Scotland has a quarter of Europe’s tidal resources and a tenth of its wave potential.

Around 1,000 people work in Scottish marine energy, but that figure could billow. “You’re talking about an exercise that could transform the marine industry into something equivalent to oil and gas,” says Martin McAdam, whose company, Aquamarine Power, is growing fast.

Among his rivals in Scotland are AWS Ocean Energy, based near Inverness, with Archimedes, a submerged wave machine; Hammerfest UK, which wants to develop three 60MW tidal sites and is working with Scottish Power; Pelamis Wave Power, who are based in Edinburgh; and Scotrenewables, based in Orkney, who are currently developing a floating tidal turbine.

Politicians need to be educated about marine energy’s potential, says Banks. Indeed, IMechE has highlighted the need for sustained political leadership if what many see as the biggest problem – that of the grid – is to be solved. Why bring energy onshore if it can’t then reach homes?

“Grids were built to connect large power stations to cities. Now you’re going to have electricity generated all over the countryside. It’s a huge challenge,” says McAdam.

“We have had meetings with Ofgen and the national grid companies and we’re outlining the need to have grids to support at least 3,000MW of energy by 2020. That is definitely possible.” McAdam adds: “A European undersea grid is also being promoted and we’re very supportive of that.”

Such a system would help to overcome a frequent objection to renewables – their fickleness. If waves were strong in Scotland, Finland or France could benefit, and vice versa.

Another challenge is the cost of installation. “At the moment we’re competing with oil and gas for boats,” says McAdam. “We need to move away from using heavy-lift, jack-up vessels.” The answer might be devices that can be floated into position and then weighted down.

The race between suppliers is speeding up. Permission for a 4MW station at Siadar, off Lewis in the Western Isles, has just been granted to Wavegen, based in Inverness, and Npower Renewables. It could power about 1,500 homes, creating 70 jobs.

Among the success stories are the three 140-metre, red tubes developed by Pelamis (named after a sea serpent) which already float off the northern Portuguese coast at Aguadoura. More Pelamis turbines are to be installed at EMEC, along with Aquamarine’s wave device Oyster.

Oyster is basically a giant flap which feeds wave energy onshore to be converted to electricity. It has already been made, at a former oil and gas plant at Nigg, north of Inverness. A high- pressure pipeline was completed in December and a hydro-electric station will be installed this spring. In the summer, Oyster will finally be bolted to piles hammered into the seabed.

Unlike wave energy, tidal power needs a channel between two land masses – and in the roaring Pentland Firth, between Caithness and Orkney, Scotland has what has been called “the Saudi Arabia of marine power”, Europe’s largest tidal resource. To exploit it, a GBP2 million contract to build Aquamarine’s tidal power device, Neptune, was awarded last month. It will be tested at EMEC.

Elsewhere, SeaGen, an “underwater windmill” developed by a Bristol company, has just generated 1.2MW near the mouth of Strangford Lough, Northern Ireland.
But the most controversial of Britain’s tidal energy schemes is, of course, in the Severn Estuary, where a barrage could provide around 5% of Britain’s energy. Environmentalists fear irreparable damage to marshes and mudflats, but the Government is known to prefer the barrage to other, smaller options. The decision it takes next year is sure to be eagerly watched in Scotland.

Somewhat overshadowed by the Severn plan is Wave Hub, a project to build a wave-power station 10 miles off St Ives, on Cornwall’s north coast, using both Pelamis and a sea-bed device developed by ORECon of Plymouth. An application to create a safety area around it has just been submitted, part of the meticulous planning that precedes any marine trial.

“We have to have environmentalists looking at the impact on fisheries, flora and fauna,” says McAdam. “And we have to be completely open with the communities we’re going into. But most people realise that climate change and energy security are real things. We want to minimalise our environmental impact and give the country a means of isolating itself from the volatility of oil and gas.”

In theory, marine energy could generate a fifth of the UK’s electricity needs, but that would require a multitude of stations. Bill Banks believes nuclear power will be needed. “But we also need a variety of renewables,” he says. “Marine will take its place along with bio, hydro and wind energy. It’s available, it’s there at the moment, and if we get our act together I think we can lead Europe. We need a synergy of activity.”

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MaritimeJournal.com, February 12, 2009

mj_newsletter_12-2-09_pelamisEdinburgh-based Pelamis Wave Power has won an order from UK renewable energy generator E.On for the next generation Pelamis Wave Energy Converter, known as the P2.

The P2 will be built at the Pelamis Leith Docks facility and trialed at the European Marine Energy Centre (EMEC) in Orkney. This is the first time a major utility has ordered a wave energy converter for installation in the UK and the first time the Pelamis P2 machine will be tested anywhere in the world.

Pelamis already has the world’s first multi-unit wave farm operational some 5km off the north coast of Portugal at Agucadora, where three 750kW machines deliver 2.25MW of electricity to the Portuguese grid. Operator Enersis has issued a letter of intent to Pelamis for a further 20MW of capacity to expand the successful project.

Licenses, consents and funding have been granted for the Orcadian Wave Farm, which will consist of four Pelamis generators supplied to ScottishPower Renewables. This installation, also at EMEC, will utilise existing electrical subsea cables, substation and grid connection.

Funding and consent has also been granted for Wave Hub, a wave energy test facility 15km off the north coast of Cornwall UK which is expected to be commissioned this year. It will consist of four separate berths, each capable of exporting 5MW of wave generated electricity. Ocean Prospect has secured exclusive access to one of the Wave Hub berths for the connection of multiple Pelamis devices.

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MendoCoastCurrent, February 10, 2009

seferry_orkneyE.On is moving forward to install and test a single wave device to be fully operational in 2010. Based around a single 750kW Pelamis P2 device that is currently being built in Edinburgh, it will be installed and tested at the European Marine Energy Centre in Orkney.  

The first year of technology testing will be an extended commissioning period, with the next two years designed to improve the operation of the equipment. It would become the first utility to test a wave energy device at the Orkney centre, which is the only grid-connected marine test site in Europe.

“We recognise much work has to follow before we can be certain marine energy will fulfil its potential,” Amaan Lafayette, Marine Development Manager at E.On, said. “But the success of this device will give us the confidence to move to the next phase of commercialisation, which is larger arrays around the UK coastline.”

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