The ocean’s waves have enough energy to provide two trillion watts of electricity, according to the Department of Energy’s office of Energy Efficiency and Renewable Energy. Extracting that enormous resource of power, however, has proved to be a herculean challenge.
A new device being developed by U.K.-based Checkmate SeaEnergy could help tap a portion of this wave power. The device, aptly named the Anaconda, is a long, water-filled rubber tube closed at both ends. It currently exists as a small laboratory-scale model, but it could eventually be 200 meters long and seven meters in diameter. At such a size, it will be capable of generating one megawatt of power at about 12 cents a kilowatt-hour, which is competitive with electricity costs from other wave-power technologies.
The one-megawatt Anaconda, which will use about 110 tons of rubber, should be lighter and cheaper than other wave-exploiting designs, says John Chaplin, a civil-engineering professor at the University of Southampton, in the United Kingdom, who is testing the lab-scale device. It is also simpler, with fewer moving parts and hinges, which means less maintenance. Since it is a pliant rubber tube, it should be able to survive severe weather conditions. “We don’t really know how Anaconda works in big waves yet, but intuitively, it seems likely that it’s going to be able to survive big waves,” Chaplin says.
The Anaconda will face plenty of competition from other wave-power devices that have already reached commercial-scale deployment. Scotland-based Pelamis Wave Power’s snakelike device was the first to provide power to the grid when it was installed off the coast of Orkney, Scotland, in 2004. In October 2007, Pelamis deployed three of its 750-kilowatt devices–770-ton, 120-meter-long chains of metal cylinders–off the coast of Portugal. Other companies, such as Finavera Renewables of Vancouver, AWS Ocean Energy of Scotland, and Ocean Power Technologies of Pennington, NJ, are testing bobbing buoy-type devices. In addition, others are developing technology to exploit tidal energy.
The Anaconda floats horizontally just below the ocean’s surface, tethered to the ocean floor at one end, facing oncoming swells, with a turbine attached, at the other. A wave hitting the tube creates a bulge in the water inside. The bulge travels down the tube with a speed that depends on the diameter of the tube, wall thickness, and elasticity of the material, Chaplin says. The tube is designed so that the speed of the bulge is the same as the speed of the wave. The wave travels outside the tube alongside the bulge, making the bulge bigger and bigger, so that it drives the turbine with maximum power.
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