Parametric study and flow characteristics of a new duct for ducted wind turbines system using analytical hierarchy process: numerical & experimental study

This paper aims to study aerodynamic modeling and optimization of the ducts to increase the power efficiency of ducted wind turbines. We design ducted wind turbines based on the features used to determine the sizes and indices of wind tunnels. Many researchers used analytical and numerical methods t...

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Bibliographic Details
Published in:Energy systems (Berlin. Periodical) 2024-05, Vol.15 (2), p.585-614
Main Authors: Taghinezhad, Javad, Alimardani, Reza, Masdari, Mehran, Mosazadeh, Hossein
Format: Article
Language:English
Subjects:
Aerodynamics
Analytic hierarchy process
Correlation analysis
Design
Design optimization
Economics and Management
Energy
Energy Policy
Energy Systems
Experimental methods
Flow characteristics
Flow velocity
Fluid dynamics
Free flow
Hierarchies
Multiple criterion
Numerical analysis
Numerical methods
Operations Research/Decision Theory
Optimization
Original Paper
Power efficiency
Pressure distribution
Spectral analysis
Spectrum analysis
Turbines
Turbulence
Turbulent flow
Wind
Wind power
Wind speed
Wind tunnels
Wind turbines
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Summary:This paper aims to study aerodynamic modeling and optimization of the ducts to increase the power efficiency of ducted wind turbines. We design ducted wind turbines based on the features used to determine the sizes and indices of wind tunnels. Many researchers used analytical and numerical methods to select the optimized duct. This study evaluates the effect of design parameters, such as nozzle length, contraction ratio, and outlet diameter, on multiple responses. By applying the analytical hierarchy process (AHP), we find the best design of a duct optimizing the multi-criteria responses. A duct prototype is fabricated to validate the optimal design, and experimental analyses are conducted based on the fabricated duct. A measurement system estimates the pressure distribution in the inlet contraction section; then, a hot-wire sensor investigates wind speed and the flow turbulence in the throat section. A good correlation between calculated data and measured values was found during the estimation of pressure distribution along the inlet contraction wall. Investigation of flow turbulence in the throat section indicates velocity in the duct throat can increase from 2.6 to 2.9 times related to the free flow velocity at different working speeds. Spectral analysis of the flow signal inside the duct shows two peaks in a frequency lower than 32 Hz related to wind tunnel vibration and Gartler vortex. Then, the flow disturbances will not significantly impact the performance of the wind turbine placed inside the duct throat.
ISSN:1868-3967
1868-3975
DOI:10.1007/s12667-022-00500-z