Active thermography for the interpretation and detection of rain erosion damage evolution on GFRP airfoils
Friederike Jensen, Josefa Feline Jerg, Michael Sorg, Andreas Fischer
Abstract
Defects such as voids, which may occur during the manufacturing of wind turbine blades, have a significant impact on premature rain erosion, especially at the leading edge. Active thermography offers the potential for non-contact in-situ inspection of rotor blade leading edges. Thermographic investigations on curved and coated GFRP specimens have shown that sub-surface defects not only represent a susceptibility to erosion, but that the onset of erosion is dependent on the depth of the defects. Furthermore, the damage development of sub-surface towards surface defects can be visualized, which allows the damage stage to be assigned to an erosion stage.
Topics & Concepts
ThermographyFibre-reinforced plasticErosionMaterials scienceLeading edgeAirfoilNondestructive testingEnhanced Data Rates for GSM EvolutionTurbine bladeRotor (electric)Stage (stratigraphy)TurbineComposite materialForensic engineeringStructural engineeringGeologyEngineeringMechanical engineeringOpticsInfraredTelecommunicationsRadiologyMedicinePaleontologyPhysicsIcing and De-icing TechnologiesThermography and Photoacoustic TechniquesParticle Dynamics in Fluid Flows