Tewkesbury, United Kingdom – September X, 2020 – Moog Inc. (NYSE: MOG.A and MOG.B), a designer and manufacturer of high-performance motion control products and solutions, has applied its expertise with servo control and actuation to help create a testing facility for researchers at the Technical University of Denmark (DTU) Large Scale Facility, part of the Department of Wind Energy and the Villum Center for Advanced Structural and Material Testing (CASMaT). Underpinning the test facility on the DTU Risø campus in Denmark, is Moog’s digital closed loop control system and application software. Moog and its partner T A Savery designed and installed test equipment for three test stands, which can accommodate 15-, 25- and 45-meter wind turbine blades. Moog engineers carried out the installation and commissioning of the suite of test equipment and provide ongoing support for DTU staff. The Moog scope of supply for the three, blade test stands included the hydraulic power plant and distribution network, six hydraulic winches for the static test and a combination of eight mass resonance exciters (MRE) and linear actuator assemblies for dynamic test work. The solution also included all pipe work, hosing and actuation devices, control system electronics and application software. To design the winch assemblies, Moog collaborated with U.K.-based Qualter Hall, a provider of bespoke hoisting, winching and haulage systems.
“Much analysis went into how the MRE would work, the frequency and how DTU would like it to perform,” adds Graham Wood, managing director with T A Savery, a U.K.-based firm with a 200-year pedigree of engineering and machining for industries ranging from defence to mining and a long-standing relationship with Moog. “This was not a contract in which the customer simply said, ‘Make A, B and C and that’s that.’ Moog won the contract, and then began a great deal of technical research, modelling and hardware design.”
Moog’s goal was to give DTU the latitude to conduct an array of tests. For example, if researchers wanted to use a test bay to conduct a dynamic test on a blade, the hydraulic system would accommodate wide pressure fluctuations. If the next test required a static one with winches, DTU could set the hydraulics to meet a very-low flow.
“DTU can select what they want, without being constrained by the equipment,” adds Kevin Cherrett, business segment manager for Systems and Services with Moog’s Industrial Solutions & Services Group.
Moog continues to support DTU’s work via a project in which researchers hope to increase the reliability of wind turbine blades.
“Moog’s technology is helping with this because we will embed sensors in test blades with built-in defects and monitor how the damage grows, whilst the Moog exciters will put realistic loads on the blades,” says Dr. Kim Branner, senior research scientist and head of the Structural Design & Testing Team for DTU Wind Energy.
Meanwhile, Branner sees the project helping blade makers build better blades but also creating a digitised twin of each blade that a wind farm operator could use to model what a blade’s future state might look like. If all goes according to plan, someday a wind farm control centre could predict a blade fail before it happens.
About Moog Inc.
Moog Inc. is a worldwide designer, manufacturer and integrator of precision control components and systems. Moog Industrial Group designs and manufactures high performance motion control products, solutions and services combining electric, hydraulic, and hybrid technologies with expert consultative support in a range of applications in energy, industrial machinery, simulation and test markets. We help performance-driven companies to design and develop their next-generation equipment. Moog Industrial Group, with fiscal year 2019 sales of US $928 million and over 40 locations worldwide, is part of Moog Inc. (NYSE: MOG.A and MOG.B), which has sales of US $2.9 billion. For more information, please visit. www.moog.com/
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For more information about this project
Please visit: info.moog.co.uk/bladetest7