Tidal, wave energy monitoring

New tool monitors effects of tidal, wave energy on marine habitat


News and Information

Researchers building a new underwater robot they’ve dubbed the “Millennium Falcon” certainly have reason to believe it will live up to its name.

From left to right: UW researchers Ben Rush, Nick Michel-Hart, James Joslin and Paul Gibbs prepare to test the monitoring device underwater in a tank on campus.

 

From left to right: UW researchers Ben Rush, Nick Michel-Hart, James Joslin and Paul Gibbs prepare to test the monitoring device underwater in a tank on campus.Applied Physics Laboratory, UW

The robot will deploy instruments to gather information in unprecedented detail about how marine life interacts with underwater equipment used to harvest wave and tidal energy. Researchers still don’t fully understand how animals and fish will be affected by ocean energy equipment, and this instrument seeks to identify risks that could come into play in a long-term marine renewable energy project.

“This is the first attempt at a ‘plug-and-socket’ instrumentation package in the marine energy field. If successful, it will change the way that industry views the viability of environmental research and development,” said Brian Polagye, a University of Washington assistant professor of mechanical engineering and one of the project’s leaders.

The Millennium Falcon robot maneuvers underwater in a testing tank on campus. The monitoring instruments (white box in the middle) are guided by the robot's thrusters toward a docking station on the bottom of the tank. Researchers controlled the machine from above.

 

The Millennium Falcon robot maneuvers underwater in a testing tank on campus. The monitoring instruments (white box in the middle) are guided by the robot’s thrusters toward a docking station on the bottom of the tank. Researchers controlled the machine from above.Applied Physics Laboratory, UW

The UW research team tested the Millennium Falcon and the instruments it transports, called the Adaptable Monitoring Package, underwater for the first time in January in a deep tank on campus. Researchers will continue testing in Puget Sound under more challenging conditions starting this month. They hope this tool will be useful for pilot tidal- and wave-energy projects and eventually in large-scale, commercial renewable-energy projects.

“We’ve really become leaders in this space, leveraging UW expertise with cabled instrumentation packages like those developed for the Ocean Observatories Initiative. What’s novel here is the serviceability of the system and our ability to rapidly deploy and recover the instruments at low cost,” saidAndrew Stewart, an ocean engineer at the UW Applied Physics Laboratory.

The instrument package can track and measure a number of sights and sounds underwater. It has a stereo camera to collect photos and video, a sonar system, hydrophones to hear marine mammal activity, sensors to gauge water quality and speed, a click detector to listen for whales, dolphins and porpoises, and even a device to detect fish tags. A fiber optic cable connection back to shore allows for real-time monitoring and control, and the device will be powered by a copper wire.

 

The breadth of sensors and various conditions this instrument can measure is unprecedented, researchers say. The tool also is unique for its ability to attach to most types of underwater infrastructure, ranging from tidal turbines to offshore oil and gas rigs. This allows researchers to easily deploy the instrument far offshore and recover it quickly at a relatively low cost compared with other approaches.

“It could be a first step toward a standardized ‘science port’ for marine energy projects,” Polagye said.

This speedy deployment and recovery — sometimes in rough seas — is possible because the instrument fits inside a remotely operated vehicle, or ROV, that can maneuver underwater and drop off the instrumentation package at a docking station integrated onto a turbine or other existing subsea infrastructure.

The monitoring instruments are housed inside the white box in the middle. The Millennium Falcon ROV is positioned just over and under the white box. Researchers tested the device's ability to fasten onto a docking station underwater, seen foreground.

 

The monitoring instruments are housed inside the white box in the middle. The Millennium Falcon ROV is positioned just over and under the white box. Researchers tested the device’s ability to fasten onto a docking station underwater, seen foreground.Applied Physics Laboratory, UW

The vehicle is about the size of a golf cart, and the research team outfitted the off-the-shelf Falcon underwater surveying machine with five extra thrusters on an external frame to give it more power to move against strong currents. Actuators on the vehicle latch the monitoring instruments onto a subsea docking station, and then the Millennium Falcon can disengage, leaving the instruments in place, and travel back to the water’s surface.

The shape of the monitoring package resembles an X-wing Starfighter from the original “Star Wars” trilogy. (The researchers are mum on whether their Millennium Falcon can make theKessel Run in less than 12 parsecs.)

This project is a collaboration between researchers in mechanical engineering and the Applied Physics Laboratory, within the largerNorthwest National Marine Renewable Energy Center, which is a multi-institution organization that develops marine renewable energy technologies through research, education and outreach. The center and the Applied Physics Laboratory recently received $8 million from the U.S. Navy to develop marine renewable energy for use at its facilities worldwide.

Development of this environmental monitoring instrument was prompted by a long-running tidal energy pilot project with the Snohomish County Public Utility District in Admiralty Inlet that recently was dropped because of ballooning costs. Going forward, researchers expect to use the same device to monitor marine-energy projects cropping up around the world and help to reduce the cost of future developments.

“Snohomish PUD was really at the forefront of projects grappling with this problem of monitoring a tidal turbine in deep, fast moving water. But as other projects in the U.S., Europe and Canada have faced similar monitoring scenarios, the instrumentation package is shaping up as a strong candidate to meet their needs,” Polagye said.

Other lead researchers are UW mechanical engineering graduate students James Joslin andEmma Cotter.

The project is funded by the U.S. Department of Energy, the U.S. Naval Facilities Engineering Command, the Snohomish County Public Utility District and the UW.

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For more information, contact Polagye at bpolagye@uw.edu or 206-543-7544 and Stewart atandy@apl.washington.edu or 206-221-8015.