Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic Algorithm

Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic Algorithm

This work aims to optimize the aerodynamic parameters (airfoil chord lengths and twist angles smoothed using Bezier curves) of the NREL 5MW wind turbine and a wind turbine designed for site-specific wind conditions to increase the wind turbine's annual energy production (AEP) under this site co...

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Bibliographic Details
Main Authors: Khaled Yassin, Aya Diab, Zakaria Ghoneim
Format: Article
Language:English
Published: Academy Publishing Center 2015-08-01
Series:Renewable Energy and Sustainable Development
Subjects:
wind turbine
aerodynamics
optimization
genetic algorithm
site-specific wind turbine
Online Access:http://apc.aast.edu/ojs/index.php/RESD/article/view/24
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spelling doaj-e262121e021c4e5199010b1f304335412021-07-01T21:41:22Zeng Academy Publishing CenterRenewable Energy and Sustainable Development 2356-85182356-85692015-08-011110611210.21622/resd.2015.01.1.10622Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic AlgorithmKhaled YassinAya DiabZakaria GhoneimThis work aims to optimize the aerodynamic parameters (airfoil chord lengths and twist angles smoothed using Bezier curves) of the NREL 5MW wind turbine and a wind turbine designed for site-specific wind conditions to increase the wind turbine's annual energy production (AEP) under this site conditions. This optimization process is carried out using a Genetic Algorithm (GA) developed in MATLAB and coupled with NREL's FAST Modularization Framework. The results shows that after optimizing the NREL 5MW wind turbine design, the AEP was improved by 5.9% of the baseline design AEP while a site-specific designed wind turbine using Schmitz equations shows 1.2% improvement in AEP. These results shows that optimization of wind turbine blade aerodynamic parameters for site-specific wind conditions leads to improvement in AEP and hence decreasing cost of energy generated by wind turbines.http://apc.aast.edu/ojs/index.php/RESD/article/view/24wind turbineaerodynamicsoptimizationgenetic algorithmsite-specific wind turbine
collection DOAJ
language English
format Article
sources DOAJ
author Khaled Yassin
Aya Diab
Zakaria Ghoneim
spellingShingle Khaled Yassin
Aya Diab
Zakaria Ghoneim
Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic Algorithm
Renewable Energy and Sustainable Development
wind turbine
aerodynamics
optimization
genetic algorithm
site-specific wind turbine
author_facet Khaled Yassin
Aya Diab
Zakaria Ghoneim
author_sort Khaled Yassin
title Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic Algorithm
title_short Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic Algorithm
title_full Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic Algorithm
title_fullStr Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic Algorithm
title_full_unstemmed Aerodynamic Optimization of a Wind Turbine Blade Designed for Egypt's Saharan Environment Using a Genetic Algorithm
title_sort aerodynamic optimization of a wind turbine blade designed for egypt's saharan environment using a genetic algorithm
publisher Academy Publishing Center
series Renewable Energy and Sustainable Development
issn 2356-8518
2356-8569
publishDate 2015-08-01
description This work aims to optimize the aerodynamic parameters (airfoil chord lengths and twist angles smoothed using Bezier curves) of the NREL 5MW wind turbine and a wind turbine designed for site-specific wind conditions to increase the wind turbine's annual energy production (AEP) under this site conditions. This optimization process is carried out using a Genetic Algorithm (GA) developed in MATLAB and coupled with NREL's FAST Modularization Framework. The results shows that after optimizing the NREL 5MW wind turbine design, the AEP was improved by 5.9% of the baseline design AEP while a site-specific designed wind turbine using Schmitz equations shows 1.2% improvement in AEP. These results shows that optimization of wind turbine blade aerodynamic parameters for site-specific wind conditions leads to improvement in AEP and hence decreasing cost of energy generated by wind turbines.
topic wind turbine
aerodynamics
optimization
genetic algorithm
site-specific wind turbine
url http://apc.aast.edu/ojs/index.php/RESD/article/view/24
work_keys_str_mv AT khaledyassin aerodynamicoptimizationofawindturbinebladedesignedforegyptssaharanenvironmentusingageneticalgorithm
AT ayadiab aerodynamicoptimizationofawindturbinebladedesignedforegyptssaharanenvironmentusingageneticalgorithm
AT zakariaghoneim aerodynamicoptimizationofawindturbinebladedesignedforegyptssaharanenvironmentusingageneticalgorithm
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