The innovative radar scanner from Fraunhofer IAF enables defects in the material composition of the wind turbine blades to be detected with significantly greater accuracy. This cuts production and operating costs. Image credit: Tim Siegert–Fotolia.com Thanks to the innovative radar scanner from the Fraunhofer Institute for Applied Solid State Physics IAF, defects in the material composition of the wind turbine blades can now be detected with far greater accuracy and visualized in a cross-sectional view, thereby saving costs in production and operation.

Wind power has become an indispensable part of an environmentally friendly power supply. Approximately 50 gigawatts, equivalent to 12 percent of the total power in Germany, are generated by over 28,000 wind turbines — with an upward trend. According to the Global Wind Energy Council, the global wind power capacity will quadruple to 2,110 gigawatts by 2030 — constituting 20 percent of the global electricity supply. Therefore it is all the more important for this growth market that wind turbines become more efficient, more reliable and more durable. According to industry experts, weak points in blade production, for example, could result in unplanned additional operation and maintenance costs amounting to several hundred thousand euros over the entire service life of the turbine. To increase the efficiency and reliability of wind turbines, Fraunhofer IAF has developed a material scanner for checking the quality of rotor blades. Using radar-based technology, defects in the material composition of the wind turbine blades can be detected in even greater detail.

The rotors, which are usually equipped with three blades, are the central component of all wind turbines. They convert wind into rotational energy, and then into electricity. Much like the wings on an aircraft, the blades are subjected to enormous external loads and therefore must be designed to be extremely robust. Modern wind turbine blades are mainly constructed from glass fiber and carbon fiber reinforced plastics (GFRP/CFRP), so that they can elastically absorb the wind energy from strong gusts without breaking. For a single blade, up to 100 sheets of glass fiber webbing are layered on top of each other, shaped and then glued together with epoxy resin.

Quality control is essential at this stage in production: "The difficulty lies in layering the glass fiber sheets flat before they are glued, without creating undulations and folds, and avoiding the formation of lumps of resin or sections of laminate, which don't set when applying the epoxy," explains Dr. Axel Hülsmann, coordinator of the radar project and group manager of sensor systems at the Fraunhofer IAF.

These kinds of defects, as well as delaminations or fractures, can be identified on a large-scale using infrared thermography. "Our material scanner enables defects to be identified with even greater accuracy, as depth resolution is also possible with radar technology — even in places where ultrasound methods fail," said Hülsmann.

At the core of the material scanner is a high frequency radar, which operates in the W band between 85 and 100 GHz with only very few watts of transmitting power. Specialized software is then used to process the transmitter and receiver signals and visualize the measurement results. "This enables us to generate a cross-sectional view of the blade, in which defects can be identified in the millimeter range, and makes our material scanner significantly more accurate than conventional methods," said Hülsmann. The radar module is based on indium gallium arsenide semiconductor technology. It is extremely light and compact thanks to its monolithically integrated construction, in which different components and functions are integrated into a single chip. Measuring 42 x 28 x 79 mm, it is approximately the size of a pack of cigarettes and weighs a mere 160 grams. It has a low power consumption of approximately 5 watts and is fitted with an integrated microcontroller that emits measurement signals via an internet interface.

Future improvements will see the module's frequency range extended to 260 GHz into the so-called H band. "This will quadruple the bandwidth of the radar module from 15 GHz to over 60 GHz. While the resolution of the rotor blade cross-section is already very high, our aim is to improve it even further," said Hülsmann.

In addition to its use in the production of rotor blades, in the future, the Fraunhofer IAF material scanner may also find a role in maintenance, where it could be used to classify defects, such as those caused by the impact of birds.

"Currently, the routine testing of rotor blades is mainly performed by hand: an expert knocks on the blade with a hammer and can tell from the tone whether there are any defects in that section. An automated solution, supplemented by our radar technology, could vastly reduce the downtime of wind turbines and thus save costs," said Hülsmann. This is particularly true for the manual maintenance of offshore wind turbines, which must be reached by boat, sometimes on harsh seas — a time-consuming process.