Improved wind turbine performance depends heavily on the design and optimization of wind blades. This work offers a critical evaluation of the state of the art in the field of numerical
The aim of the research is to investigate and compare the performance of small wind turbine blades made using three different materials by performing structural analysis.
Large wind turbines yield more energy but demand careful aeroelastic blade design. Coupled multiphysics design strategies can reduce wind energy costs by exploiting fluid–structure
Rotating wind turbines are more vulnerable to lightning strikes than static wind turbine, possibly due to the different distribution of tip corona charges. However, there is a lack of research on the
The global push for higher-capacity offshore wind farms (GWEC, 2025) demands blades longer than 100 meters, requiring precise simulation to avoid material stress and fatigue failures.
Firstly, systematic computational fluid dynamics (CFD)-based icing simulations were conducted on the blade of a 5 MW onshore wind turbine to investigate the effects of environmental
A high-fidelity computational fluid dynamics simulation explores how adjusting the blade pitch angle modifies the integrated aerodynamic performance and aeroelastic reaction of a 2 kW
Wind turbine blades are known for their complex geometry and difficult-to-predict characteristics. So, this chapter aims to look in depth at theory, design, modeling, and simulation of a
At Fraunhofer IWES, we introduced two fully automated structured mesh generation tools for CFD simulations of wind turbines, namely bladeBlockMesher and windTurbineMesher.
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