ROSKILDE, Denmark, March 26, 2024 /PRNewswire/ -- In a significant development for the wind energy sector, Shanghai Electric Wind Power Group, a subsidiary of Shanghai Electric (SEHK:2727, SSE:601727), a company renowned for its dedication to clean energy equipment, recently celebrated the fifth anniversary of its European Innovation Center ("the Center") in Rosklide, Denmark.
n a significant development for the wind energy sector, Shanghai Electric Wind Power Group, a subsidiary of Shanghai Electric, focused on clean energy equipment, celebrated the fifth anniversary of its European Innovation Center.
At the 5th International Symposium on Leading Edge Erosion of Wind Turbine Blades the Technical University of Denmark held recently, Koji Fukami, Senior Blade Design Expert, presented his research titled "Engineering Estimation of Severe Leading Edge Roughness Effect". His study, conducted in collaboration with the Center, introduces a novel approach to estimating the impact of leading-edge roughness on wind turbine blades in high precipitation environments both offshore and onshore.
"There's a crucial need to bridge academia and the wind energy industry, looking for more practical, time-efficient, and cost-effective methods to assess and optimize blade designs under harsh conditions," Koji Fukami stated.
Wind turbine blades play a critical role in the effectiveness of wind power generation, with their integrity directly affecting the system's productivity. Erosion, especially from wind force, is a frequent issue. The industry acknowledges rain erosion as the main culprit behind damage to the blades' leading edges.
Megawatt-class blades operate at tip speeds exceeding 90m/s where raindrops can hit with significant force akin to bullets causing substantial tearing forces. This repetitive impact leads to fatigue processes where coatings peel off under continuous hits and lateral tearing forces resulting in protective layer damage eventually compromising the entire leading-edge protective structure.
In designing blades and airfoils for real-world operation, addressing the influence of severe environmental conditions is imperative for robust performance. The new approach presented enables precise simulation for blade design with a reduction in computational demand, making the design process faster, less costly, and more functional. This cutting-edge modeling method plays a crucial role in securing the robustness and dependability of wind turbine blades in electrical wind power as they confront more extreme climatic challenges.
This method employs concepts from unsteady aerodynamics to optimize airfoil designs, drawing on simulation results that reflect real operational conditions. The high degree of alignment between the simulation data from this method and the experimental data publicly released by the University of Illinois indicates a strong match between the two sets of results.
This coming November, the Center will initiate a new round of collaboration with the Technical University of Denmark, focusing on wind tunnel experiments to test the performance of new airfoil designs and to evaluate new simulation methods.
The Center, founded in March 2019, has capitalized on Denmark's strategic strengths in the wind energy sector, encompassing wind turbine technology, sector growth, application know-how, and the requisite natural settings for wind energy installations. This approach has drawn a multitude of elite engineering specialists to the Center.
Rapidly evolving from a startup in a single office to a modern science and innovation center with a significant employee base, the Center has to date achieved a range of successes in technology innovation projects and acquired numerous patents. These advancements are being progressively utilized to empower advancements in control algorithms, load analysis, blade design, and the optimization of wind farms.
For more information, please visit https://www.shanghai-electric.com/listed_en/windpower/.