Sandia National Laboratories are showing new design for 650 foot wind turbine blades in an effort to bring offshore 50-MW wind turbines to the United States and the world.

Sandia National Laboratories’ research on the extreme-scale Segmented Ultralight Morphing Rotor (SUMR) is funded by the Department of Energy’s (DOE) Advanced Research Projects Agency-Energy program. The challenge is to design a low-cost offshore 50-megawatt turbine using a rotor blade more than 650 feet (200 meters) long. It will be two and a half times longer than any existing wind blade offering six times more power.

Todd Griffith, lead blade designer on the project and technical lead for Sandia’s Offshore Wind Energy Program said, “Exascale turbines take advantage of economies of scale.”

“Conventional upwind blades are expensive to manufacture, deploy and maintain beyond 10-15 MW. They must be stiff, to avoid fatigue and eliminate the risk of tower strikes in strong gusts. Those stiff blades are heavy, and their mass, which is directly related to cost, becomes even more problematic at the extreme scale due to gravity loads and other changes,” he said.

Sandia’s 100-meter blade is the basis for the Segmented Ultralight Morphing Rotor (SUMR), a new low-cost offshore 50-MW wind turbine. At dangerous wind speeds, the blades are stowed and aligned with the wind direction, reducing the risk of damage. At lower wind speeds, the blades spread out more to maximize energy production. Illustration courtesy of TrevorJohnston.com, Popular Science.

Sandia’s 100-meter blade is the basis for the Segmented Ultralight Morphing Rotor (SUMR), a new low-cost offshore 50-MW wind turbine. At dangerous wind speeds, the blades are stowed and aligned with the wind direction, reducing the risk of damage. At lower wind speeds, the blades spread out more to maximize energy production. Illustration courtesy of TrevorJohnston.com, Popular Science.  Click image for the largest view.

Griffith explained the new blades could be more easily and cost-effectively manufactured in segments, avoiding the unprecedented-scale equipment needed for transport and assembly of blades built as single units.

The exascale turbines would be sited downwind behind the tower, unlike conventional turbines that are configured with the rotor blades upwind of the tower.

A SUMR’s load-alignment is bio-inspired by the way palm trees move in storms. The lightweight, segmented trunk approximates a series of cylindrical shells that bend in the wind while retaining segment stiffness. This alignment radically reduces the mass required for blade stiffening by reducing the forces on the blades using the palm-tree inspired load-alignment approach.

Segmented turbine blades have a significant advantage in parts of the world at risk for severe storms, such as hurricanes, where offshore turbines must withstand tremendous wind speeds over 200 mph. The blades align themselves to reduce cantilever forces on the blade through a trunnion hinge near the hub that responds to changes in wind speed.

“At dangerous wind speeds, the blades are stowed and aligned with the wind direction, reducing the risk of damage. At lower wind speeds, the blades spread out more to maximize energy production.” Griffith said.

Sandia’s previous work on 13-MW systems uses 100-meter blades (328 feet) on which the initial SUMR designs are based. While a 50-MW horizontal wind turbine is well beyond the size of any current design, studies show that load alignment can dramatically reduce peak stresses and fatigue on the rotor blades. This reduces costs and allows construction of blades big enough for a 50-MW system.

Most current U.S. wind turbines produce power in the 1- to 2-MW range, with blades about 165 feet (50 meters) long, while the largest commercially available turbine is rated at 8 MW with blades 262 feet (80 meters) long.

“The U.S. has great offshore wind energy potential, but offshore installations are expensive, so larger turbines are needed to capture that energy at an affordable cost,” Griffith explained.

This is progress, but barriers remain before designers can scale up to a 50-MW turbine running at more than six times the power output of the largest current turbines. At this scale the economics will be much different. 20 exascale turbines would approximate a good sized power plant instead of 50 to 100 turbines.

Moving toward exascale turbines could be an important way to meet DOE’s goal of providing 20 percent of the nation’s energy from wind by 2030, as detailed in its recent Wind Vision Report.

The team is led by the University of Virginia and includes Sandia Laboratories and researchers from the University of Illinois, the University of Colorado, the Colorado School of Mines and the National Renewable Energy Laboratory. Corporate advisory partners include Dominion Resources, General Electric Co., Siemens AG and Vestas Wind Systems.


Comments

1 Comment so far

  1. Graham on February 2, 2016 3:04 AM

    When the blades are part-bent, won’t any variation in blade angle put the assembly out of balance, risking further damage? Also, won’t the gravity-pull put loads of strain on the hinged section that cycles during rotation. Doesn’t that pose more engineering problems than it solves?

    So, here’s a crazy alernative thought – telescopic blades that retract in strong winds. You could have fun with that one too!

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