The Viability of Wave Energy Applicability for the Pacific Northwest?

Relative Strength to Wave Energy Best sites are a) North Atlantic b) Gulf of Alaska – units are KW/meter

More Continuous Data

Conceptual Difficulties In a wave, the energy content is distributed throughout the wave In a wave, the energy content is distributed throughout the wave Therefore, one needs to build a device to focus or collimate that distributed energy Therefore, one needs to build a device to focus or collimate that distributed energy Design challenge then becomes a) how big of device is needed and b) what is the efficiency of converting wave mechanical energy into electricity? Design challenge then becomes a) how big of device is needed and b) what is the efficiency of converting wave mechanical energy into electricity? Wave energy is variable hourly and seasonaly Wave energy is variable hourly and seasonaly

Three Basic Kinds of Systems  Offshore (so your dealing with swell energy not breaking waves)  Near Shore (maximum wave amplitude)  Embedded devices (built into shoreline to receive breaking wave – but energy loss is occurring while the wave is breaking)

Some Physics Ocean waves are irregular and are not easily characterized by an average height Ocean waves are irregular and are not easily characterized by an average height Relevant parameter is A, or amplitude of the wave (above mean sea level) Relevant parameter is A, or amplitude of the wave (above mean sea level)

More Physics Power per meter is the product of the energy density and the wave front velocity (essentially the period of the wave) Power per meter is the product of the energy density and the wave front velocity (essentially the period of the wave) On the PNW coast, values for average wave amplitude and for wave period are such that wave power is in the kw/m area. So potential yield along the Oregon Coast, assuming 10% efficiency is: 40 kw/m x 1000 m/km x 600 km = MW

Devices 1: The Air Piston Incoming wave pushes water level up to basically compress air in a piston to turn the crank on a generator. When water recedes, air comes back into the chamber. This device is known as the oscillating water column (OSC).

OSC Continued In principle, one could modify extant coastal headline topography to build these devices. Note: Red Line is average sea level – front wall must be located below that line to make a seal so that the air doesn’t rush out – tidal variations are therefore important

Difficulties with OWC approach Initial cost of barrier wall is high – due to lack of access to the site (not easy to build anything on a coastal headland)Initial cost of barrier wall is high – due to lack of access to the site (not easy to build anything on a coastal headland) Zoning regulations protect most coastal headlandsZoning regulations protect most coastal headlands Rich marine life is often found thereRich marine life is often found there Device must withstand potentially big stormsDevice must withstand potentially big storms

Unit Capacity of OWC Physics is similar to that of a wind turbine but wave power is more densePhysics is similar to that of a wind turbine but wave power is more dense Yield depends on total square meters of rotor area but efficiencies are very difficult to calculateYield depends on total square meters of rotor area but efficiencies are very difficult to calculate Near Shore anchored devices capture highest amount of wave energy but sensitive to local mean sea levelNear Shore anchored devices capture highest amount of wave energy but sensitive to local mean sea level Reliability of waves is about 2 times higher than windReliability of waves is about 2 times higher than wind

Unit Capacity/Footprint Based on existing ON shore facility in India (operational around 1993)Based on existing ON shore facility in India (operational around 1993) 50 KW plant requires50 KW plant requires 100 square meter footprint and 3000 tons of concrete100 square meter footprint and 3000 tons of concrete Scaling up to 100 MW implies 2000 individual 100 square meter installations or roughly 5 per mile along Oregon coastline and this is just for 100 MWScaling up to 100 MW implies 2000 individual 100 square meter installations or roughly 5 per mile along Oregon coastline and this is just for 100 MW

Conclusions about OWC Shoreline installations probably don’t make sense – even if previous calculation is wrong by a factor of 10 (which is unlikely) Shoreline installations probably don’t make sense – even if previous calculation is wrong by a factor of 10 (which is unlikely) Therefore, look towards large installations in near shore  but that could be expensive Therefore, look towards large installations in near shore  but that could be expensive

Ocean Power Technologies Claim The footprint of a 100MW conventional power plant, including surrounding grounds, fuel unloading areas, waste settling ponds, and additional facilities can be up to 2 sq miles. A comparable OPT power plant would occupy less than 1 square mile of unused ocean surface out for sight from the shore (okay?)okay

The Tapered Channel Device Works like a hydroelectric dam Waves rush in to fill reservoir which then drains through a turbine system back into the ocean. Simple idea really. Power depends on total volume of water.

Pros and Cons of TAPCHAN Could incorporate this into new kinds of seawall/jetty/harbor protection projects Average wave energy must be high in order to push all the water into the reservoir Reservoir needs to stay full and can’t drain at low tides Significant capital cost and large coastal footprint per MW because the depth of the reservoir is shallow Likely not practical in most locations

The Power Buoy Video explanation

Power Buoy Continued Unit capacities are small (20KW) so you need a large network – possibly subject to catastrophic failure in severe weather Unit capacities are small (20KW) so you need a large network – possibly subject to catastrophic failure in severe weather

An Offshore Buoy Farm Current Problem is that unit capacity is only 50 Watts for a 12 foot cylinder – need millions Principle Advantage: Can Withstand severe Weather

The Overtopping Device Similar to TAPCHAN idea but can easily be installed near short instead of on shore. Power basically depends on incoming wave amplitude (height above mean sea level)

The Wave Dragon Project Wave DragonWave Dragon  Ambitious project to harvest up to 10 Gigawatts of Power in the North Atlantic  Floating sea monsters

Pros and Cons of Wave Dragon  In principle this could actually work  Unit capacity appears to be 16 Turbine 4 MW individual dragon  25,000 then gives you 10 GW of power  Principle challenge is then “grid connection” but scale of project does not seem formidable

Attenuation devices  Use Bernoulli principle to increase pressure and velocity  Tapered long columns that intercept surface waves  Might be good at beaches – not well developed idea yet, however

UK Pelamis Project Unit Capacity is 750 KW; Power is generated at each of the hinged locations essentially through a device that converts pressure wave energy into electrical current. Each tube is 150 meters long and 3.5 meters wide UK project employs 7 tubes to generate 5.25 MW Biggest potential problem (besides grid connection) is durability

The Pelamis Project To set the scale of the devices

The Future Sea Snake Farm ? Sea Snake FarmSea Snake Farm  Footprint argument is favorable: 30MW facility would occupy 1 sq km of ocean.  Look to the UK to seriously develop this resource if initial prototypes prove succesful

Summary  There is much potential in worldwide wave energy  Capturing wave energy and converting that into electricity is difficult  Large scale projects very capital intensive  Optimum technology not yet discovered so best to experiment  Surface sea snakes, however, seem to be the best option

Potential Local Projects  OPT facility at off shore from Reedsport  Oregon State wave energy research facility at newport  Tidal power project in Tacoma Narrows