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Aerodynamic effects of leading-edge erosion in wind farm flow modeling

Jens Visbech, Tuhfe Göçmen, Özge Sinem Özçakmak, Alexander Meyer Forsting, Ásta Hannesdóttir, Pierre‐Elouan Réthoré

2024Wind energy science12 citationsDOIOpen Access PDF

Abstract

Abstract. Leading-edge erosion (LEE) can significantly impact the aerodynamic performance of wind turbines and thereby the overall efficiency of a wind farm. Typically, erosion is modeled for individual turbines where aerodynamic effects only impact the energy production through degraded power curves. For wind farms, aerodynamic deficiency has the potential to also alter wake dynamics, which will affect the overall energy production. The objective of this study is to demonstrate this combined effect by coupling LEE damage prediction and aerodynamic loss modeling with steady-state wind farm flow modeling. The modeling workflow is used to simulate the effect of LEE on the Horns Rev 1 wind farm. Based on a 10-year simulation, the aerodynamic effect of LEE was found to be insignificant for the first few years of operation but rapidly increases and reaches a maximum annual energy production (AEP) loss of 2.9 % in the last year for a single turbine. When including the impact of LEE to the wakes behind eroded turbines, the AEP loss is seen to reduce to 2.7 % at the wind farm level, i.e., corresponding to an overestimation of the AEP loss of up to 7 % when only considering a single wind turbine. In addition, it was demonstrated that the modeling framework can be used to prioritize turbines for an optimal repairing strategy.

Topics & Concepts

AerodynamicsErosionAeolian processesFlow (mathematics)Environmental scienceEnhanced Data Rates for GSM EvolutionLeading edgeMarine engineeringAerospace engineeringGeologyEngineeringMechanicsPhysicsGeomorphologyTelecommunicationsWind Energy Research and DevelopmentAeolian processes and effectsIcing and De-icing Technologies