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Active thermography for the interpretation and detection of rain erosion damage evolution on GFRP airfoils

Friederike Jensen, Josefa Feline Jerg, Michael Sorg, Andreas Fischer

2022NDT & E International15 citationsDOIOpen Access PDF

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
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