Grand Challenges in the Design, Manufacture, and Operation of Future Wind Turbine Systems

Veers, Paul S.; Bottasso, Carlo L.; Manuel, Lance; Naughton, Jonathan W.; Pao, Lucy Y.; Paquette, Joshua; Robertson, Amy; Robinson, Michael C.; Ananthan, Shreyas; Barlas, Thanasis K.; Bianchini, Alessandro; Bredmose, Henrik; Horcas, Sergio González; Keller, Jonathan; Madsen, Helge Aagaard; Manwell, James F.; Moriarty, Patrick; Nolet, Stephen; Rinker, Jennifer M.

doi:10.5194/wes-2022-32

Cited by 22 publications

(20 citation statements)

References 191 publications

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“…Accurate wake modeling is essential for optimizing wind plant layouts and creating effective control strategies (Veers et al, 2022;Meyers et al, 2022). Hybrid wake models balance the accuracy of high-fidelity simulations with the computational efficiency of analytic models to facilitate wind plant design studies.…”

Section: Introductionmentioning

confidence: 99%

Evolution of eddy viscosity in the wake of a wind turbine

et al. 2023

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Abstract. The eddy viscosity hypothesis is a popular method in wind turbine wake modeling for estimating turbulent Reynolds stresses. We document the downstream evolution of eddy viscosity in the wake of a wind turbine from experimental and large-eddy-simulation data. Wake eddy viscosity is isolated from its surroundings by subtracting the inflow profile, and the driving forces are identified in each wake region. Eddy viscosity varies in response to changes in turbine geometry and nacelle misalignment with larger turbines generating stronger velocity gradients and shear stresses. We propose a model for eddy viscosity based on a Rayleigh distribution. Model parameters are obtained from scaling the eddy viscosity hypothesis and demonstrate satisfactory agreement with the reference data. The model is implemented in the curled wake formulation in the FLOw Redirection and Induction in Steady State (FLORIS) framework and assessed through comparisons with the previous formulation. Our approach produced more accurate flow field estimates with lower total error for the majority of cases.

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Section: Introductionmentioning

confidence: 99%

Evolution of eddy viscosity in the wake of a wind turbine

et al. 2023

View full text Add to dashboard Cite

show abstract

“…Accurate wake modeling is essential for optimizing wind plant layouts and creating effective control strategies (Veers et al, 2022;Meyers et al, 2022). Hybrid wake models balance the accuracy of high fidelity simulations with the computational efficiency of analytic models to facilitate wind plant design studies.…”

Section: Introductionmentioning

confidence: 99%

Evolution of Eddy Viscosity in the Wake of a Wind Turbine

Scott

Martínez‐Tossas

Hamilton

et al. 2022

Preprint

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Abstract. The eddy viscosity hypothesis is a popular method in wind turbine wake modeling for estimating turbulent stresses. We document the downstream evolution of eddy viscosity in the wake of a wind turbine from experimental and large eddy simulation data. Wake eddy viscosity is isolated from its surroundings by subtracting the inflow profile and the driving forces are identified in each wake region. Eddy viscosity varies in response to changes in turbine geometry and nacelle misalignment with larger turbines generating stronger velocity gradients and shear stresses. We propose a model for eddy viscosity based on a Rayleigh distribution curve. Model parameters are obtained from scaling the eddy viscosity hypothesis and demonstrate satisfactory agreement with the reference data. The model is implemented in the curled wake formulation in the FLOw Redirection and Induction in Steady State (FLORIS) framework and assessed through comparisons to the previous formulation. Our approach produced more accurate flow field estimates with lower total error for the majority of cases.

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“…However, system reliability refers to the system's ability to remain at a certain performance level. Therefore, it can be concluded that resilience studies are complementary to system reliability studies [2].The reliability of the WT converter [29], and also the reliability of WT systems [30] has been investigated. Whereas, no comprehensive study on WT and WF resilience is conducted.…”

Section: Power System Resiliencementioning

confidence: 99%

A review of power system resilience assessment and enhancement approaches by focusing on wind farms and wind turbines

Modaberi

Tohidi

Zadeh

et al. 2023

IET Renewable Power Gen

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Recently, due to the increase of the frequency of high impact low probability (HILP) events (manmade and natural events), assessment and enhancement of resilience has become very important in the operation and planning procedures of future power systems. In this regard, several researches have been conducted on operation and planning strategies of the power system to improve resilience. Here, assessment and enhancement approaches of power system resilience by focusing on the role of wind farms and wind turbines are reviewed. To do so, a comprehensive review of the related metrics, hazard types, modelling approaches, assessment methods, and enhancement solutions is presented. Then, the assessment and enhancement methods of power system resilience are categorized in three phases before event (preventive proactive actions), during event (corrective active actions) and after event (restorative reactive actions) from the point of view of operation and planning actions. Finally, the current challenges, research gaps and future trends are discussed.

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Grand Challenges in the Design, Manufacture, and Operation of Future Wind Turbine Systems

Cited by 22 publications

References 191 publications

Evolution of eddy viscosity in the wake of a wind turbine

Evolution of eddy viscosity in the wake of a wind turbine

Evolution of Eddy Viscosity in the Wake of a Wind Turbine

A review of power system resilience assessment and enhancement approaches by focusing on wind farms and wind turbines

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