Surrogate models for the blade element  momentum aerodynamic model using  non-intrusive polynomial chaos expansions

Haghi, Rad; Crawford, Curran

doi:10.5194/wes-7-1289-2022

Cited by 6 publications

(1 citation statement)

References 40 publications

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“…Their results indicate that the mean wind speed and turbulence intensity have the most significant effect on fatigue load estimation. In another study, Haghi and Crawford developed a PCE to map the random phases of synthetic wind to the loads on a wind turbine rotor [15]. Most of the studies in the literature focus on the realm of Surrogate Model (SM)s, attempting to map wind speed by itself or combined with other relative variables to the fatigue or extreme loads of a wind turbine.…”

Section: Introductionmentioning

confidence: 99%

Wind Turbine Damage Equivalent Load Assessment Using Gaussian Process Regression Combining Measurement and Synthetic Data

Haghi,

Stagg,

Crawford

2024

Energies

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Assessing the structural health of operational wind turbines is crucial, given their exposure to harsh environments and the resultant impact on longevity and performance. However, this is hindered by the lack of data in commercial machines and accurate models based on manufacturers’ proprietary design data. To overcome these challenges, this study focuses on using Gaussian Process Regression (GPR) to evaluate the loads in wind turbines using a hybrid approach. The methodology involves constructing a hybrid database of aero-servo-elastic simulations, integrating publicly available wind turbine models, tools and Supervisory Control and Data Acquisition (SCADA) measurement data. Then, constructing GPR models with hybrid data, the prediction is validated against the hybrid and SCADA measurements. The results, derived from a year of SCADA data, demonstrate the GPR model’s effectiveness in interpreting and predicting turbine performance metrics. The findings of this study underscore the potential of GPR for the health and reliability assessment and management of wind turbine systems.

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Section: Introductionmentioning

confidence: 99%

Wind Turbine Damage Equivalent Load Assessment Using Gaussian Process Regression Combining Measurement and Synthetic Data

Haghi,

Stagg,

Crawford

2024

Energies

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A novel approach to inverse design of wind turbine airfoils using tandem neural networks

Anand,

Marepally,

Muneeb Safdar

et al. 2024

Wind Energy

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The performance of a wind turbine and its efficiency majorly depends on wind‐to‐rotor efficiency. The aerodynamic design of the wind turbine blades using high‐fidelity tools such as adjoint‐computational fluid dynamics (CFD) is accurate but computationally expensive. It becomes impractical when the number of design variables increases for multidisciplinary optimization (MDO). Low‐fidelity tools are computationally cheaper but are not accurate, especially in regions of adverse pressure gradient and reverse flows. Surrogate modeling has been used in many aerodynamic problems. We develop and apply a recent architecture of the deep learning module, tandem neural networks (T‐NNs) for the inverse design of wind turbine airfoils. The T‐NNs trained on CFD data for fully turbulent cases predict not only the performance parameters for the given airfoil geometry but also the airfoil geometry for a given design objective. This framework uses the entire performance polar for inverse design which ensures that the airfoil optimization is not a single‐point optimization problem which is essential for practical design problems. The T‐NNs are also optimized to include multiple constraints like maximum thickness and trailing edge (TE) thickness which is a novel contribution in the field of inverse design using surrogate models. A statistical analysis is also performed to predict a family of airfoil geometries.

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Wind Characterization for Energy Production. Case Study: Huascachaca Mines—Ecuador

Mata-Quevedo,

Verdugo-Ormaza,

Rojas-Coronel

et al. 2023

Lecture Notes in Networks and Systems

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Surrogate models for the blade element momentum aerodynamic model using non-intrusive polynomial chaos expansions

Cited by 6 publications

References 40 publications

Wind Turbine Damage Equivalent Load Assessment Using Gaussian Process Regression Combining Measurement and Synthetic Data

Wind Turbine Damage Equivalent Load Assessment Using Gaussian Process Regression Combining Measurement and Synthetic Data

A novel approach to inverse design of wind turbine airfoils using tandem neural networks

Wind Characterization for Energy Production. Case Study: Huascachaca Mines—Ecuador

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