Researchers Propose US Offshore Wind Grid
Apr 13, 2010 - Elizabeth Boyle, UDel and Leslie Taylor, SoMAS
"Making wind-generated electricity more steady will enable wind power to become a much larger fraction of our electric sources," said the paper's lead author Willett Kempton, UD professor of marine policy in the College of Earth, Ocean, and Environment and director of its Center for Carbon-free Power Integration.
The research team — which also included UD alumnus Felipe Pimenta, UD research faculty member Dana Veron, and Brian Colle, associate professor in the School of Marine and Atmospheric Sciences at Stony Brook University — demonstrated thoughtful design of offshore wind power projects can minimize the impacts of local weather on power fluctuations.
The researchers analyzed five years of wind observations from 11 monitoring stations along the U.S. East Coast from Florida to Maine. Based on wind speeds at each location, they estimated electrical power output from a hypothetical five-megawatt offshore turbine. After analyzing the patterns of wind energy among the stations along the coast, the team explored the seasonal effects on power output.
"Our analysis shows that when transmission systems will carry power from renewable sources, such as wind, they should be designed to consider large-scale meteorology, including the prevailing movement of high- and low-pressure systems," Kempton said.
Colle explained the ideal configuration. "A north-south transmission geometry fits nicely with the storm track that shifts northward or southward along the U.S. East Coast on a weekly or seasonal time scale," he said. "Because then at any one time a high or low pressure system is likely to be producing wind (and thus power) somewhere along the coast."
The researchers found each hypothetical power generation site exhibited the expected ups and downs, but when they simulated a power line connecting them, the overall power output was smoothed so that maximum or minimum output was rare. In the particular five-year period studied, the power output of the simulated grid never completely stopped.
No wind turbines are presently located in U.S. waters, although projects have been proposed off the coasts of several Atlantic states. This research could prove useful as project sites are selected and developed.
Reducing the severity of wind power fluctuations would allow sufficient time for power suppliers to ramp up or down power production from other energy sources as needed. Solutions that reduce power fluctuations also are important if wind is to displace significant amounts of carbon-emitting energy sources, the researchers said.
The University of Delaware, the flagship institution of the state of Delaware, is one of the oldest Land Grant institutions in the nation, and one of only three institutions to also have Sea Grant and Space Grant status. The university is classified by the Carnegie Foundation for the Advancement of Teaching as a research university with very high research activity — a designation accorded fewer than 3 percent of U.S. colleges and universities. The university is a state-assisted, privately controlled institution with an enrollment of more than 16,000 undergraduates, 3,500 graduate students and 1,000 professional and continuing study students.
Leslie Taylor is Communications Manager with the School of Marine and Atmospheric Sciences (SoMAS) at Stony Brook University. Elizabeth Boyle is Staff Writer at the College of Earth, Ocean, and Environment at the University of Delaware.
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