“Telescoping can” wave energy device beats test predictions by 20%
Scotland’s AWS Energy has reported results some 20% better than predicted for its Archimedes Waveswing, a prototype wave energy generator that’s been undergoing ocean-based testing at the European Marine Energy Centre (EMEC) in Orkney for the last six months.
The Waveswing is a cylindrical metal buoy that’s tethered to a single point on the ocean floor. In operation, it stays beneath the surface and responds to water pressure changes. As a wave passes overhead, the pressure increase pushes down on the top “floater” section of the device, sliding it downward relative to the lower “silo” section, with a rolling seal ensuring no water gets in.
This linear motion in this “telescoping can” compresses the air in the Waveswing device, creating an air spring to push the floater section back up as the wave rolls onward. As the floater moves up and down, it drives a hydraulic motor, which converts the linear motion into rotation, and a regular electrical generator draws power from both the upward and downward strokes.
The device can be raised and lowered on its tether for maintenance and deployment, and there’s also a facility to regulate the air pressure inside the cylinder, effectively tuning the air spring to take maximal advantage of the wave conditions.
AWS reports that “during a period of moderate wave conditions” at the EMEC installation, the prototype machine captured an average of 10 kW, with peaks up to 80 kW, against its rated capacity of 16 kW. The test has also demonstrated that the Waveswing can be fully deployed from sitting quayside to fully operational in less than 12 hours, and that it can survive Force-10 gale conditions.
The power output frankly looks surprisingly low to us given the size of this machine. It stands a towering 7 m (23.0 ft) tall fully extended, with a diameter of 4 m (13.1 ft), and it weighs 50 tons; it makes a pretty impressive sight as it’s driven down the road on a trailer.
But this is not the commercial device. AWS says these units will be configurable for power ratings between 15 kW and 500 kW – although it’s unclear whether these half-megawatt versions will need to be physically bigger, or if so, by how much. The company sees commercial deployments taking the shape of multi-absorber structures, which could see 20 of the most powerful units arrayed together into a 10-MW platform.
According to IRENA, there’s enough energy in the motion of the ocean – specifically, in wave energy as opposed to tidal energy – to meet the world’s entire energy demand. But the technology here is in its infancy; there are plenty of pilots and prototypes, but precious few commercial installations. And since nothing has proven itself yet, there’s a fascinating proliferation of different designs all duking it out in search of a solution that’s cheap, easy to deploy and maintain, eco-friendly, and capable of producing power in all sorts of conditions for decades despite the brutal corrosive assault of salty seawater and sludgy biofouling.
Effectively harnessing wave energy could radically lower prices of renewable energy grids; these things won’t shut down at night like solar, or when the wind drops, so they can reduce the need for long- and short-term energy storage that a grid needs to guarantee a reliable electricity supply. This, as CSIRO modeling for Wave Swell Energy’s UniWave generation systems suggests, could slash up-front CAPEX (Capital expenditure) on multi-mode renewable energy systems by as much as two thirds.
So it’s an area of immense potential and consequence, but also one where it seems we’ll need to keep being patient. See the Waveswing prototype operating in the video below.
Source AWS Ocean Energy