Smart embedded sensor systems for offshore wind turbines

Smart Embedded Sensor Systems will allow operators of offshore wind farms to check ‘the health’ of the wind turbines, while the operator is sitting in a warm and dry place on land and while the turbine blades are spinning merrily, far away at sea.

This is made possible by incorporating sensors into the wind turbine blades to discover changes and damage in the blade structure at an early stage before the blade breaks. Remote monitoring of damage to off-shore wind turbines could save money, because the intervals between inspections can be increased. Moreover, operation becomes safer and more stable as it possible to check from a remote place whether a blade has been damaged after a heavy storm. The project is called SESS and stands for Smart Embedded Sensor Systems.

Many unnecessary inspections can be avoided
The new sensor system is to monitor “the health” of each wind turbine, sending the information to the operator on shore. If the operators think it is necessary, they can send technicians to carry out repairs before a stoppage occurs. This will lead to significant savings in operating costs through the whole life of the turbine. It will also be easier to decide what to do with a wind turbine once it gets “old”. Can it continue to work, does it pay to rebuild it, or should it be taken down and sent to recycling?

Risø DTU is helping develop the sensor system. Models describing the reaction of composite materials to various load conditions are tested in the laboratory, and classify the various defects and damages that may occur. Efforts are also made to model the reaction of the blade to the damage condition, and the loads during operation.

Interfering before minor damages become fatal
The idea is to develop a model which follows the principle of the old saying “Many of one thing makes another larger thing”: Many small changes in the blade material should be monitored one at a time in order to assess the overall impact. In this way one can predict when a particular blade should be repaired.

This tool makes it possible to design new types of blades, and to predict how damage will develop. The sensors also give the opportunity to develop prognostics calculating the remaining life of the turbine, based on its current condition. Operators of large wind farms could use the tool to decide how best to maintain the blades during operation.

The models are developed and verified through mechanical tests of materials, structural sub-components and blades at full scale.

Sensors are used in all tests to provide detailed knowledge of the progress of the test. Typical sensors can include fibre optics, piezoelectric materials, strain gauges, etc. They keep an eye on the different types of damage that may occur to the blade.

Many functions within one sensor system
“We want to develop an integrated sensor system which can carry out many tasks simultaneously. It will be needed in a future remote monitoring system for wind turbine blades. No single type of sensor will be able to supply all the necessary information to estimate the condition of the turbine blade because there are many potential sources of errors and damage in blade materials,” says Malcolm McGugan and Kaj Borum from the Materials Research Division at Risø DTU. They emphasize that the sensor system has to be very reliable; it must not cause wrong alarms, leading the operator to send technicians to a wind turbine without reason.

“The advantage for us is that we can test the blades throughout the entire scale from the microscopic damage of material to tests on the blade at full scale at Risø’s Experimental Research Facility for Blade Structure,” the two scientists say, continuing: “The intention is to make the new sensors a part of the data flow which is already transmitted from a wind turbine, in accordance with the wind industry IEC standards. Adapting the integrated sensors for these standards, we have created a fine basis for monitoring key components of the wind turbine, including the turbine blades.”

To be used on buildings, bridges, aircraft and ships
The new “health” sensors will probably be introduced gradually. As more experience is gained with the sensors in connection with wind turbines, it will be possible to use the sensors in other fields too, such as the aviation industry. Other obvious uses are: bridges, ships and buildings. We believe that such systems could predict, for instance, whether the roof of a sports hall after heavy snow is in danger of collapsing due to the weight of snow.

In September, Risø DTU held a course with focus on this broad application. The course title was “Structural Health Monitoring – SHM”, and this type of monitoring is expected to have a great future when it comes to monitoring and protecting many types of constructions.

 

Source : RISO

Siemens to produce wind turbines in China

Siemens is expanding its global manufacturing network for wind turbine plants and is building a new production facility in Lingang New City in Shanghai. By establishing this new rotor blade and nacelle plant, the company is further strengthening its environmental portfolio. This new facility is scheduled to take up operation in the second half of 2010, initially with 400 employees. The wind turbine plants produced in Shanghai will be for the Chinese market and for export. Siemens is investing more than EUR60 million in setting up this new location.

“Siemens is expanding its commitment to environmentally-friendly energy technology in China with this new wind turbine production facility in Shanghai,” declared Wolfgang Dehen, CEO of the Siemens Energy Sector and member of the managing board of Siemens AG on the occasion of the laying of the cornerstone in Shanghai on May 22, 2009. “China could soon become the largest wind energy market in the world and with our new production facility in Shanghai we are establishing an excellent starting position for meeting the growing demand of this exciting market. In addition, we are also rigorously advancing the internationalization of our manufacturing network for wind turbines to optimally meet the needs of our customers in Asia, Europe and America.”

The new production site will have a total space of 180,000 square meters and be situated at an excellent location with regard to shipping and traffic facilities, being in the direct vicinity of the Yang Shan deep-sea harbor. Siemens will initially produce blades for 2.3 and 3.6 MW wind turbine plants. These blades will be produced using the IntegralBlade® process patented by Siemens, without any glued joints that are susceptible to damage. Wind turbine plant nacelles will also be produced at this new plant. A nacelle is mounted on the top of the tower and supports the rotor as well as encloses a wind turbine plant’s major components for electric power generation; these include the gearbox, the drive train as well as the control electronics.

The production capacity for the new facility is initially planned at 500 MW annually. The first wind turbine blades and nacelles are scheduled to leave the plant in time for the EXPO 2010 international exhibition in Shanghai. Siemens has already reserved additional space in Lingang for potential expansion of this production facility, however.

Since Siemens entered the market for wind turbine plants through the acquisition of the Danish company Bonus Energy in 2004, it has substantially expanded its worldwide fabrication capacities. Plans for building of a new facility for wind turbine plants in Hutchinson, Kansas (USA) were just recently announced by Siemens. Siemens also recently established rotor blade fabrication facilities in Fort Madison, Iowa (USA) and in Engesvang, Denmark. The Danish locations Brande and Aalborg have additionally been expanded and new research and development centers have also been set up in Germany, Holland, Great Britain, the USA and Denmark. The number of Siemens employees involved in the wind energy business has gown from 800 in 2004 to currently over 5500. This corresponds to an increase of 650 percent.

Wind turbine plants are an important component of the Siemens environmental portfolio, which earned the company revenues of nearly EUR19 billion in fiscal 2008, roughly a quarter of Siemens total revenues.

The Siemens Energy Sector is the world’s leading supplier of a complete spectrum of products, services and solutions for the generation, transmission and distribution of power and for the extraction, conversion and transport of oil and gas. In fiscal 2008 (ended September 30), the Energy Sector had revenues of approximately EUR22.6 billion and received new orders totaling approximately EUR33.4 billion and posted a profit of EUR1.4 billion. On September 30, 2008, the Energy Sector had a work force of approximately 83,500. Further information is available at: http://www.siemens.com/energy

Source: EC