Abstract
Leading edge protection (LEP) coating systems are applied to protect turbine blade edges from rain erosion. The performance of a LEP system is assessed in an accelerated rain erosion test (RET) as a metric for industrial application, but these tests are expensive. Modelling methods are available to predict erosion, based on fundamental material properties, but there is a lack of validation. The Springer model (1976) is analysed in this work to assess it as a tool for using material fundamental properties to predict the time to failure in a rain erosion test. It has been applied, referenced and industry validated with important partial considerations. The method has been applied successfully for erosion damage by wear performance prediction when combined with prior material data from rain erosion test (RET), instead of obtaining it directly from fundamental properties measured separately as Springer proposed. The method also offers accurate predictions when coupled with modified numerical parameters obtained from experimental RET testing data. This research aims to understand the differences between the experimental data used by Springer and the current industry approach to rain erosion testing, and to determine how it may introduce inaccuracies into lifetime predictions of current LEP systems, since they are very different to those tested in the historic modelling validation. In this work, a review of the modelling is presented, allowing for the understanding of key issues of its computational implementation and the required experimental material characterisation. Modelling results are discussed for different original application issues and industry-related LEP configuration cases, offering the reader to interpret the limits of the performance prediction when considering the variation in material fundamental properties involved.
Highlights
Protecting the leading edge of wind turbine blades has developed into a major challenge for the wind industry [1]
The Springer model ignores the inclusion of a filler layer, which is common in current wind turbine leading edge protection systems
This study aims to understand if the differences between the experimental data used by Springer and the current industry approach to rain erosion testing is introducing inaccuracies into lifetime predictions of current Leading edge protection (LEP) systems, since they are very different to those tested for the modelling validation
Summary
Protecting the leading edge of wind turbine blades has developed into a major challenge for the wind industry [1]. Springer [3] proposed a model that relates material fundamental properties to predict the time to failure in a rain erosion test. It has been applied [4,5], referenced [6,7] and industry validated [8]. The proposed modelling cases are completely developed and used to interpret the required experimental material characterisation and its relationship with the LEP erosion performance predictions. The modelling methodology is applied to analyse the effects of variation in the material parameters that define the erosion “strength”, namely the ultimate tensile strength, endurance limit, Poisson’s ratio and the ‘knee’ in the fatigue curve. A complete map of the input parameters of the modelling is presented in Figure 2, to summarise all the material properties and operational conditions required in the modelling, as well as how their relevant equations interact to predict the end of the incubation period for a material [3]
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