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A worker helps to install the Alstom 2.7 MW turbine for extended testing at the NWTC.
Image Credit: Dennis Schroeder

Published on April 13th, 2013 | by Guest Contributor

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Change Is In The Air At NREL’s Wind Center

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April 13th, 2013 by
 
This article first appeared on NREL’s website by David Glickson

The National Wind Technology Center (NWTC) is at the nexus of a changing landscape, where the mountains meet the plains. It’s also where changes in the wind industry are being previewed. And, a visitor or passerby will notice significant yet subtle changes taking place on site, including a new turbine installation and new blades on another of the site’s giant turbines.

Aerial view of the 1.5 MW GE, 3 MW Alstom, 2.3 MW Siemens, 2 MW Gamesa, and CART wind turbines at NREL's National Wind Technology Center (NWTC).  Image Credit: Dennis Schroeder

Aerial view of the 1.5 MW GE, 3 MW Alstom, 2.3 MW Siemens, 2 MW Gamesa, and CART wind turbines at NREL’s National Wind Technology Center (NWTC).
Image Credit: Dennis Schroeder

Researchers at the US Department of Energy’s (DOE) National Renewable Energy Laboratory (NREL), along with their industry partners, are advancing a more sustainable energy future at the NWTC by leading the way in testing the most advanced wind turbine technologies and preparing them for future deployment.

“The addition of modern megawatt-scale wind turbines has been critical in the development of our center,” NWTC Director Fort Felker said. “It has changed the way the wind industry thinks about NREL in the sense that the work we are doing is relevant, impactful, and immediately beneficial to them. The continued partnership efforts on these turbines demonstrate how our industry partners value the contribution we provide and the important role we can play in testing new technologies.”

More Power at Lower Wind Speeds

NREL entered into a partnership with Alstom, a French power-generation company, in early 2011 when its ECO 100 wind turbine was installed at the NWTC for certification testing.

The next step in that partnership took place recently when the turbine was updated to test a new, state-of-the-art blade design. The change converted the ECO 100 turbine into an ECO 110 turbine with a behemoth 110-meter rotor diameter, making it the largest and most powerful wind turbine currently on the NWTC site.

“This is the largest machine we’ve ever had our hands on,” NREL Test Engineer and Project Manager Jeroen van Dam said. “It’s always an exciting opportunity to get to apply our testing methods to a larger or newer concept and continue to validate those methods.”

The unique rotor design of the Alstom turbine required that the blades be switched out, one at a time, in the air. The logistics of such an operation were tricky and required two very large cranes with skilled operators and teams of staff on the ground and inside the turbine. The installation also required calm weather – hardly a given at the notoriously windy NWTC site.

The Alstom ECO 110 turbine with the larger blade configuration is specifically designed to operate efficiently at lower wind speeds. Longer blades mean more wind is captured, allowing greater power generation at lower speeds. The downside of this longer blade configuration is a greater risk of damaging structural loads on the turbine at higher wind speeds. The testing at NREL will focus on power performance and mechanical loads to validate computer modeling that predicts the design loads. This is part of the certification efforts for this turbine blade design before it can enter the U.S. market.

“There is great potential for developing medium wind speed resources throughout the United States and Canada,” said Albert Fisas, director of innovation for Alstom’s North American Wind business. “With this upgrade complete, Alstom and NREL will launch a commissioning and testing program to certify the performance of the new rotor configuration for use in North America and worldwide.”

A Stronger Wind Turbine for Stronger Winds

Crews lift a blade assembly onto the nacelle of Gamesa's G9X-2.0 MW turbine at the NWTC.  Image Credit: Dennis Schroeder

Crews lift a blade assembly onto the nacelle of Gamesa’s G9X-2.0 MW turbine at the NWTC.
Image Credit: Dennis Schroeder

In another collaboration with the wind industry in late 2011, NREL began testing a G97 Class IIIA 2.0 megawatt (MW) turbine from Gamesa Technology Corporation, Inc. This public-private partnership was developed to study and test a variety of components and systems on the turbine and to guide development of the next generation of wind turbines being designed specifically for the U.S. market.

Testing on the original turbine was completed, and in order to continue the collaborative research, the turbine was recently upgraded with a new rotor and other components, including a new control system. This upgrade to a Class II version of the Gamesa G97 model will allow the turbine to operate efficiently at higher wind speeds.

The International Electrotechnical Commission (IEC) develops international standards for wind turbines. The IEC standards set wind classes for conditions a turbine might see at hub height in a given location from I to III, with Class I winds being the highest (speeds averaging 22 miles per hour) and Class III winds the lowest (speeds averaging 17 miles per hour).

“From the outside, you can’t really tell the difference between this one and the original — the differences are very subtle,” van Dam said. “The Class II design has different blades and more material in strategic places to make it a more robust design capable of standing up to stronger Class II wind speeds.”

NREL testing of the Gamesa turbine will focus on evaluating the new design features of the G97 model and will lead to certification for use in the U.S. market. NREL’s work will also include power performance testing and acoustic testing of the Gamesa design.

“Wind energy is going to continue to play a key role in creating a stronger and more sustainable American economy,” said Dan Broderick, engineering manager for Gamesa North America. “This partnership with NREL is an exciting venture that showcases Gamesa’s commitment to enhanced clean energy development, as well as our ability to deliver reliable, efficient, and cost-effective wind turbine technologies to the U.S. marketplace.”

NREL Leading the Way to Expanded Deployment and Lower-Cost Wind Energy

Enlarge image A worker helps to install the Alstom 2.7 MW turbine for extended testing at the NWTC. Image Credit: Dennis Schroeder

Enlarge image
A worker helps to install the Alstom 2.7 MW turbine for extended testing at the NWTC.
Image Credit: Dennis Schroeder

It might appear odd that these two projects — one wind turbine being refitted to accommodate lower wind speeds while another is updated to handle higher wind speeds — are happening simultaneously and at the same location. However, the NWTC site is uniquely positioned to meet the demands of both.

“Our site regularly gets Class II and Class III wind speeds, with Class I extremes,” van Dam said. “The variety of wind we get at this location allows for us to do a wide variety of testing effectively. And the fact that we often get very high winds here makes it a great location to test structural loads on all types of turbine designs, regardless of their intended wind speed for deployed use.”

Additionally, the expertise and efficiency of NREL’s testing capabilities make the NWTC an attractive location for this type of continued collaboration.

“We have unique capabilities to support the type of testing that they want to do,” van Dam said. “Also, with the site and infrastructure we have here, and the benefit of being pre-permitted on public land, the deployment of prototype technologies can be expedited. This helps get newer designs certified and to market quicker.”

NREL’s ultimate goal in this testing is to foster the technological developments necessary for wider deployment of wind energy in the marketplace at the lowest cost possible. New wind turbine designs that are able to efficiently handle a wider regime of wind speeds and the ability to select technology that is optimized for a specific location and wind resource will allow greater deployment of wind energy in more areas where it may not have otherwise been practical.

“These newer designs will have a lower cost of energy, and this can directly lead to greater market penetration,” van Dam said. “Our work in testing these new designs and having them be quickly deployed, effectively validated, and proven is a critical part of the process.”

Industry Collaborations Building a Big Future for Wind Energy

NREL researchers are staying focused on the path forward for wind energy. Continuing to lead the way in testing new technologies and maintaining a cutting-edge approach to working with the wind industry makes the NWTC a valued partner. NREL places a high importance on its collaborations with industry and sees these partnerships as critical to meeting the nation’s goals of moving toward a clean energy future.

“We are pleased to have a dynamic and diverse group of industry colleagues working with NREL as R&D partners,” Felker said. “These types of collaborations demonstrate a commitment to crucial technology development and the public-private partnerships necessary to ensure the continued momentum of the wind power industry. Our role is to help reduce the technical risks and thereby help accelerate next-generation technology into the marketplace. NREL is proud to be at the forefront of this important work.”

Learn more about NREL’s National Wind Technology Center.

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  • Dave2020

    “select technology that is optimized for a specific location and wind resource”

    I’m playing devil’s advocate here:- They’re saying turbine design is ‘customized’, which can hardly meet the cost-saving objectives of standardisation and mass production. The composite, ‘hand-made’ construction of the blades is only one of the HAWT’s shortcomings, and the NWTC have yet to consider offshore location. That’s a whole new ball game.

    Far from being ‘cutting-edge next-generation technology’, this lags behind turbines that are already twice as powerful and scheduled for deployment in 2015:-

    http://www.marinelink.com/news/collaborate-projects353425.aspx
    DONG Energy & Siemens AG sign up to supply and service a total of 154 offshore wind turbines (OWT) of 6MW each. The agreements concern Siemens’ 6MW offshore wind turbine based on gear-less direct drive technology and with a 154-metre rotor.

    I think they’re both mistaken. I’d opt for a design that works both at lower wind speeds AND captures the energy in gales. It won’t need to be bigger than 3MW and should be robust enough to be safe offshore, :-

    http://www.earthtechling.com/2013/04/offshore-wind-power-huge-potential-goes-largely-untapped/
    “The process for getting offshore wind power off the ground takes far too long.”

    “The result is a lower cost/kWh relative to turbines with complex propeller designs.”
    http://www.onlinetes.com/wind-sail-type-vertical-axis-wind-turbines-111011.aspx

    Naturally, one has to make allowances for research bias, but Wind-sail strikes me as credible, unlike this extraordinary claim:-

    http://cleantechnica.com/2013/03/07/modec-unveils-sqwid-offshore-wind-current-ocean-energy-platform/
    “With a larger, rectangular swept area capable of harnessing low and high-speed winds from any direction, vertical-axis Darrieus wind turbine can generate twice as much power as conventional wind turbines with vertical propeller blades, according to MODEC.”

    Do they have any evidence to back that up? Somehow I doubt it.

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