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| Naji, M. |
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Godfrey, Mike
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Publications (4/4 displayed)
- 2022New generation of embedded planar optics for in-situ, through-thickness and real-time strain measurements in carbon fiber reinforced polymer composites during the cure processcitations
- 2021The effect of temperature on the erosion of polyurethane coatings for wind turbine leading edge protectioncitations
- 2020Structural health monitoring of composite laminate for aerospace applications via embedded panda fiber Bragg gratingcitations
- 2020Real-time through-thickness and in-plane strain measurement in Carbon Fibre Reinforced Polymer composites using planar optical Bragg gratingcitations
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article
The effect of temperature on the erosion of polyurethane coatings for wind turbine leading edge protection
Abstract
Wind turbine leading-edge erosion can degrade the aerodynamic properties of blades and reduce their efficiency. Previous theoretical work has suggested that low temperatures might affect the erosion performance of leading-edges and protective leading-edge coatings. Solid particle erosion is caused by dust, sand and hailstones impacting the leading edges. For polymer coatings, temperature is a particular concern; the low temperatures can cause a transition from ductile to brittle failures. Polyurethane (PU) coatings were eroded at two temperatures: ambient (25°C) and cold (-30°C). An adapted solid-air erosion facility was used to accelerate sub-angular sand particles of 96.2 µm mean size to a velocity of 68±8 m/s. Low volumetric sand concentrations of 1.3×10-4 % were studied at two impingement angles of 45 and 90 degrees. The results showed that cold temperatures influenced the erosion rate and erosion mechanism of the coatings, with the erosion rate at the cold temperature increasing significantly. The erosion classification values and the shape of the wear scar suggested plastic erosion behaviour of the PU at cold temperatures, as opposed to the more erosion-resistant elastic behaviour. A temperaturecontrolled nanoindentation study demonstrated that the ratio of hardness to modulus reduced and the plasticity index increased with a reduction in temperature, implying the PU coatings had an increased propensity to plastically deform during cold erosion. This supports the erosion performance seen in experiments; however, the cold erosion surfaces developed more pits than the ambient case. Crosssection analysis of the eroded coatings showed accumulation of damage subsurface with evidence of delamination at the weakest interfaces in the layered coating systems, across all temperatures.