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Superconducting wind turbine chalks up first test success

Date:
November 12, 2019
Source:
IOP Publishing
Summary:
A superconducting rotor has been successfully tested on an active wind turbine for the first time. The researchers designed, developed, manufactured a full-size superconducting generator for a 3.6 megawatt wind turbine, and field-tested it.
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A superconducting rotor has been successfully tested on an active wind turbine for the first time.

The EcoSwing consortium designed, developed, manufactured a full-size superconducting generator for a 3.6 megawatt wind turbine, and field-tested it in Thyborøn, Denmark.

They report their results in the IOP Publishing journalSuperconductor Science and Technology.

Corresponding author Anne Bergen, from the University of Twente, The Netherlands, said: "Wind turbine size has grown significantly over the last few decades. However, today's technology has trouble keeping up with the trend towards ever-increasing unit power levels.

"Permanent-magnet (PM) based direct-drive (DD) generators offer a solution in state-of-the-art multi-megawatt generators, but the feasibility of 10+ megawatt PM-DD turbines requires significant weight reduction. Pseudo-magnetic direct-drive (PDD) machines, integrating magnetic gearing and generator functions are a possible solution to this, but they can be expensive and highly complex to produce."

To tackle this challenge, the team employed rare-earth barium copper oxide (ReBCO) high-temperature superconducting generators. These require a smaller amount of rare-earth materials than PM machines, resulting in a lower cost. Superconductors can also carry high current densities, which results in more power-dense coils and a lower weight.

Ms Bergen said: "The field test of the generator was extremely successful. When the generator was installed at Thyborøn, the turbine achieved its targeted power range, including more than 650 hours of grid operation. This shows the compatibility of superconductive generator technology with all the elements of an operational environment such as variable speeds, grid faults, electromagnetic harmonics, and vibrations.

"The project made several other substantial pieces of progress. It demonstrated that HTS coil production is not limited to specialised laboratories, and constitutes a successful technology transfer from science to industry. The HTS rotor was also assembled in an industrial setting, showing superconducting components can be deployed in a `standard' manufacturing environment.

"Now the concept has been proven, we hope to see superconducting generator technology begin to be widely applied on wind turbines."

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Materials provided byIOP Publishing.注意:内容可能被编辑风格d length.


Journal Reference:

  1. Anne Bergen, Rasmus Andersen, Markus Bauer, Hermann Boy, Marcel ter Brake, Patrick Brutsaert, Carsten Bührer, Marc Dhallé, Jesper Hansen, Herman ten Kate, Jürgen Kellers, Jens Krause, Erik Krooshoop, Christian Kruse, Hans Kylling, Martin Pilas, Hendrik Pütz, Anders Rebsdorf, Michael Reckhard, Eric Seitz, Helmut Springer, Xiaowei Song, Nir Tzabar, Sander Wessel, Jan Wiezoreck, Tiemo Winkler, Konstantin Yagotyntsev.Design and in-field testing of the world’s first ReBCO rotor for a 3.6 MW wind generator.Superconductor Science and Technology, 2019; 32 (12): 125006 DOI:10.1088/1361-6668/ab48d6

Cite This Page:

IOP Publishing. "Superconducting wind turbine chalks up first test success." ScienceDaily. ScienceDaily, 12 November 2019. /releases/2019/11/191112110335.htm>.
IOP Publishing. (2019, November 12). Superconducting wind turbine chalks up first test success.ScienceDaily. Retrieved September 6, 2023 from www.koonmotors.com/releases/2019/11/191112110335.htm
IOP Publishing. "Superconducting wind turbine chalks up first test success." ScienceDaily. www.koonmotors.com/releases/2019/11/191112110335.htm (accessed September 6, 2023).

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