EnergyExtracting maximum energy from currents
In the long sprint to find new sources of clean, low-cost power, slow and steady may win the race — the slow-moving water of currents and tides, that is. Just as wind turbines tap into the energy of flowing air to generate electricity, hydrokinetic devices produce power from moving masses of water.
Harnessing the water's motion to generate power // Source: noaa.gov
In the long sprint to find new sources of clean, low-cost power, slow and steady may win the race — the slow-moving water of currents and tides, that is. Just as wind turbines tap into the energy of flowing air to generate electricity, hydrokinetic devices produce power from moving masses of water.
An AIP release reports that in a paper appearing in American Institute of Physics (AIP) Publishing’s Journal of Renewable and Sustainable Energy, Ramon Fernandez-Feria, a professor of fluid mechanics at Universidad de Málaga in Spain, and his colleagues Joaquin Ortega-Casanova and Daniel Cebrián, performed a computer simulation to determine the optimum configuration of one such system to enable it to extract the maximum amount of energy from any given current.
The system, developed by a Norwegian company called Tidal Sails AS, consists of a string of submerged blades or sails, connected via wire ropes, angled into the oncoming current. The rushing current generates large lift forces in the sails, and as they are pushed along through a continuous loop, they drive a generator to produce electricity.
A small-scale version of the Tidal Sails device is already in operation at a test facility constructed in a stream outside Haugesund, Norway. The pilot project has a power-producing capacity of twenty-eight kilowatts; a full-scale version could generate several megawatts of power.
Installing several such units in a tidal stream, the company says, could generate as much as 100 gigawatts of electricity per year.
In their analysis, the researchers found that the maximum amount of power could be generated using blades with a chord length (the width of the blade at a given distance along its length) equal to the separation between each individual blade, that are positioned at about a 79 degree angle relative to the oncoming current, and that move at a speed about one and half times faster than the current.
“The next step would be to refine the design of the device with further hydrodynamic numerical simulations, complemented with small-scale experiments,” Fernandez-Feria said. “For instance, trying more efficient aerodynamic blade profiles, and different angles between the string of blades and the current.”
— Read more in Daniel Cebrián etal., “Lift and drag characteristics of a cascade of flat plates in a configuration of interest for a tidal current energy converter: Numerical simulations analysis,” Journal of Renewable and Sustainable Energy 5, no. 4 (23 July 2013) (doi:.org/10.1063/1.4816495
