Search results for "edge erosion"

showing 5 items of 5 documents

Minimum Leading Edge Protection Application Length to Combat Rain-Induced Erosion of Wind Turbine Blades

2021

Leading edge erosion (LEE) repairs of wind turbine blades (WTBs) involve infield application of leading edge protection (LEP) solutions. The industry is currently aiming to use factory based LEP coatings that can applied to the WTBs before they are shipped out for installation. However, one of the main challenges related to these solutions is the choice of a minimum LEP application length to be applied in the spanwise direction of the WTBs. Generally, coating suppliers apply 10–20 m of LEP onto the blades starting from the tip of the blade using the “rule of thumb”, and no studies in the literature exist that stipulate how these LEP lengths can be calculated. In this study, we extend the sc…

Leading edgeControl and OptimizationTurbine blade020209 energyEnergy Engineering and Power Technology020101 civil engineeringcoatings02 engineering and technologylcsh:TechnologyTurbine0201 civil engineeringlaw.inventionWind turbine bladesCoatingslawleading edge erosionwind energy0202 electrical engineering electronic engineering information engineeringSensitivity (control systems)Electrical and Electronic EngineeringWind energyEngineering (miscellaneous)Parametric statisticsWind powerlcsh:TRenewable Energy Sustainability and the Environmentbusiness.industrywind turbine blades; leading edge erosion; wind energy; repair; coatingswind turbine bladesRule of thumbPower (physics)VDP::Teknologi: 500repairEnvironmental sciencebusinessRepairLeading edge erosionEnergy (miscellaneous)Marine engineeringEnergies
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Effects of Onshore and Offshore Environmental Parameters on the Leading Edge Erosion of Wind Turbine Blades: A Comparative Study

2021

Abstract The presence of rain-induced leading edge erosion of wind turbine blades (WTBs) necessitates the development of erosion models. One of the essential parameters for erosion modeling is the relative impact velocity between rain droplets and the rotating blade. Based on this parameter, the erosion damage rate of a WTB is calculated to estimate the expected leading edge lifetime. The environmental conditions that govern this parameter have site-specific variations, and thus, rain and wind loading on a turbine differ for onshore and offshore locations. In addition, there are wave loads present in the offshore environment. The present paper tries to provide guidelines for erosion modelin…

Leading edgeOcean energy technologyTurbine blade020209 energyOcean Engineering02 engineering and technology01 natural sciencesTurbine010305 fluids & plasmaslaw.inventionSea breezelaw0103 physical sciences0202 electrical engineering electronic engineering information engineeringGeotechnical engineeringDesign of offshore structuresWind powerbusiness.industryMechanical EngineeringOffshore material performance and applicationsTurbulence kinetic energyErosionEnvironmental scienceSubmarine pipelinebusinessLeading edge erosionJournal of Offshore Mechanics and Arctic Engineering
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Numerical investigation of rain droplet impact on offshore wind turbine blades under different rainfall conditions: A parametric study

2020

The leading edge of a fiber composite wind turbine blade (WTB) is prone to erosion damages due to repeated rain droplet impact during its service life. Such damages are critical to the blade's aerodynamic as well as structural performance, ultimately resulting in substantial repair costs. An effective design of a coating material for WTB is necessary and its analysis must include variables associated with erosive rain droplets such as (1) droplet diameter, (2) impact velocity, and (3) droplet impact angle. The present paper develops and validates a coupled fluid structure interaction (FSI) computational model for simulating rain droplet impact on WTBs, where the structure domain is modelled…

Leading edgeOffshore wind turbine bladeTurbine blade02 engineering and technologyAerodynamicsMechanics021001 nanoscience & nanotechnologySmooth particle hydrodynamics (SPH)Finite element methodlaw.inventionSmoothed-particle hydrodynamicsOffshore wind powerVDP::Teknologi: 500020303 mechanical engineering & transports0203 mechanical engineeringCoating materiallawFluid–structure interactionCeramics and CompositesErosionOperation and maintenanceEnvironmental science0210 nano-technologyCivil and Structural EngineeringLeading edge erosion
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A probabilistic rainfall model to estimate the leading-edge lifetime of wind turbine blade coating system

2021

Rain-induced leading-edge erosion of wind turbine blades is associated with high repair and maintenance costs. For efficient operation and maintenance, erosion models are required that provide estimates of blade coating lifetime at a real scale. In this study, a statistical rainfall model is established that describes probabilistic distributions of rain parameters that are critical for site-specific leading-edge erosion assessment. A new droplet size distribution (DSD) is determined based on two years’ onshore rainfall data of an inland site in the Netherlands and the obtained DSD is compared with those from the literature. Joint probability distribution functions of rain intensities and dr…

Probabilistic analysisScale (ratio)Turbine bladeMeteorologyRenewable Energy Sustainability and the EnvironmentProbabilistic logicLeading-edge erosionTurbineAnalytical methodWind speedWind turbine bladelaw.inventionVDP::Teknologi: 500Joint probability distributionlawErosionEnvironmental scienceProbabilistic analysis of algorithmsLong term analysis
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A probabilistic long‐term framework for site‐specific erosion analysis of wind turbine blades: A case study of 31 Dutch sites

2021

Abstract Rain‐induced leading‐edge erosion (LEE) of wind turbine blades (WTBs) is associated with high repair and maintenance costs. The effects of LEE can be triggered in less than 1 to 2 years for some wind turbine sites, whereas it may take several years for others. In addition, the growth of erosion may also differ for different blades and turbines operating at the same site. Hence, LEE is a site‐ and turbine‐specific problem. In this paper, we propose a probabilistic long‐term framework for assessing site‐specific lifetime of a WTB coating system. Case studies are presented for 1.5 and 10 MW wind turbines, where geographic bubble charts for the leading‐edge lifetime and number of repai…

operation and maintenanceTurbine bladeTJ807-830coatingsTurbineleading-edge erosionRenewable energy sourceslaw.inventionlawwind energyedge erosionOrographic liftWind powerRenewable Energy Sustainability and the Environmentbusiness.industryleading‐edge erosionProbabilistic logicwind turbine bladesTerm (time)VDP::Teknologi: 500OA-Fund TU DelftService lifeErosionEnvironmental sciencebusinessMarine engineeringWind Energy
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