Modelado de la interacción fluido estructura (FSI) para el diseño de una turbina eólica HAWT

Kevin Molina; Daniel Ortega; Manuel Martínez; William Pinto-Hernández; Octavio Andrés González-Estrada

doi:10.18273/revuin.v17n2-2018023

Vol. 17 No. 2 (2018): Revista UIS Ingenierías

Articles

Modeling of the fluid structure interaction (FSI) for the design of a HAWT wind turbine

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Kevin Molina,
Daniel Ortega,
Manuel Martínez,
William Pinto-Hernández,
Octavio Andrés González-Estrada

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Kevin Molina
Unidades Tecnológicas de Santander

Daniel Ortega
Unidades Tecnológicas de Santander

Manuel Martínez
Universidad Industrial de Santander

William Pinto-Hernández
Universidad Industrial de Santander

Octavio Andrés González-Estrada
Universidad Industrial de Santander
Bio

DOI: https://doi.org/10.18273/revuin.v17n2-2018023

Published 2018-05-30

Keywords

blade,
BEM,
profile design,
FSI,
wind turbine,
HAWT

...

How to Cite

Molina, K., Ortega, D., Martínez, M., Pinto-Hernández, W., & González-Estrada, O. A. (2018). Modeling of the fluid structure interaction (FSI) for the design of a HAWT wind turbine. Revista UIS Ingenierías, 17(2), 269–282. https://doi.org/10.18273/revuin.v17n2-2018023

Abstract

In this work, the mechanical behavior of the blade of a wind turbine is studied, analyzing the impact of the design of the blade on the amount of energy generated and its structural response as a function of the stresses induced by the air flow. In order to study the relationship between flow forces, deformations and stresses induced in the structure, a Fluid Structure Interaction (FSI) model was used. The blade structure is designed using blade element momentum theory (BEM), taking as a starting point constant properties related to the wind (speed, density, Reynolds), and the selection of a profile recommended by NACA, RISO, DU or NREL. Then, the same procedure is used for a profile designed using performance theories. Having these results for both types of blades, a comparison of the stresses and deformations due to the variations between the designed profile and the selected profile was made, analyzing the effects on the generated energy and the structural integrity of the turbine.

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