GE researchers are working on a project to design and develop advanced controls to support a 12-megawatt (MW) floating offshore wind turbine, in an effort to enable larger, more powerful turbines to be installed deeper waters unlocked by floating wind technologies.
The $4 million project is being run through ARPA-E’s ATLANTIS (Aerodynamic Turbines Lighter and Afloat with Nautical Technologies and Integrated Servo-control) program, which aims to accelerate the development of new technologies to promote the future of floating offshore wind energy.
Rogier Blom, a senior principal engineer in model-based controls and the project’s principal investigator, said the enormity of building a floating platform that can support a structure as large as an 850-plus feet offshore turbine cannot be understated “Designing a floating turbine is like putting a bus on a tall pole, making it float and then stabilizing it while it interacts with wind and waves. Doing this well is both a design and controls challenge,” he said. “Through our ATLANTIS project with ARPA-E, we will be concurrently designing the controls system with the design of the floating structure itself to advance floating offshore wind energy toward becoming a future commercially viable solution.”
GE is working on the project with marine design and consulting firm Glosten, developer of the PelaStar tension-leg platform floating wind turbine foundation. By coupling a 12 MW GE turbine with Glosten’s tension leg platform technology, the team has taken on the challenge of designing a lightweight floating turbine with up to 35% less mass in the tower and the floating platform. This is expected to result in a very significant reduction of the resulting levelized cost of energy (LCOE) of the electricity generated with this turbine. The core principle that makes this possible is co-designing the controls system with the tower and floating platform.
Ben Ackers, vice president and principal in Glosten’s ocean engineering and analysis group, said, “We excel when we engage across all of the active disciplines and components as we optimize our floating structures for a full system solution. Collaborating closely with GE gives us another layer of detailed engineering design input beyond the standard drivers of site conditions, construction cost, schedule and the resulting LCOE. This is the cooperation needed to bring floating wind to technical and commercial success.”
Between GE Research and Glosten, the joint research team brings decades of expertise in all areas of technology involved in carrying out the mission of our project, including turbine controls, structures, aero engineering, naval architecture, and hydrodynamics.
Blom noted that enabling floating offshore wind would dramatically expand the power generation potential of offshore wind power.
“With GE’s Haliade X, the world’s most powerful offshore wind turbine built to date, we’re just beginning to tap into the future promise of offshore wind power in Europe, the U.S. and other parts of the globe,” Blom said. “Today, these fixed-bottom wind turbines are limited to depths of 60 meters or less. With floating turbines, we would be able to dramatically expand the reaches of offshore wind power to areas with water depths of 60 meters or greater.”
According to the National Renewable Energy Lab (NREL), the introduction of floating turbines would dramatically expand the potential of U.S. offshore wind resources to more than 7,000 TeraWatt hours (TWhs) per year, nearly double the total annual U.S. energy consumption of 4,000 TWh.
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