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Experimental and numerical investigation onto 1250mm axial fan

Numerical simulation is of interest for most fan designers to optimize the fan designs. Computational fluid dynamic (CFD) has become an essential tool in almost every branch of fluid dynamics and one of the major tools for fan designs. As the fan designers relying on the numerical simulation, the ac...

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Main Authors: Munisamy K.M., Govindasamy R., Thangaraju S.K.
Other Authors: 15035918600
Format: Conference paper
Published: 2023
Subjects:
Axial fan
CFD
Axial flow turbomachinery
Computational fluid dynamics
Design
Helicopter rotors
Optimization
Testing
Turbomachine blades
Axial fans
Blade pitch
CFD modeling
Computational model
Experimental conditions
Fan designs
Guide vane
Incidence angles
Mesh density
Modeling strategy
Numerical investigations
Outlet guide vanes
Rotor blades
Stator blade
Test procedures
Turbulent models
Velocity vectors
Computer simulation
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spelling my.uniten.dspace-295372023-12-28T14:30:26Z Experimental and numerical investigation onto 1250mm axial fan Munisamy K.M. Govindasamy R. Thangaraju S.K. 15035918600 55523370400 36633163200 Axial fan CFD Axial flow turbomachinery Computational fluid dynamics Design Helicopter rotors Optimization Testing Turbomachine blades Axial fans Blade pitch CFD modeling Computational model Experimental conditions Fan designs Guide vane Incidence angles Mesh density Modeling strategy Numerical investigations Outlet guide vanes Rotor blades Stator blade Test procedures Turbulent models Velocity vectors Computer simulation Numerical simulation is of interest for most fan designers to optimize the fan designs. Computational fluid dynamic (CFD) has become an essential tool in almost every branch of fluid dynamics and one of the major tools for fan designs. As the fan designers relying on the numerical simulation, the accuracy of tools such as CFD in predicting the performance has become a subject of interest. This paper validates the CFD modeling of an axial fan design against experimental result. The experimental rig and test procedure are developed with reference to "AMCA standard 210". The analysis is conducted on 1250mm diameter axial fan with two different blade pitch angle 30� and 40�. Prior to encounter the swirling effect and deflection of velocity vector due to rotor blade, a stator blade with the same profile as rotor blade is used as the outlet guide vanes in opposite direction. The computational model is created according to the experimental condition and applied realistic boundary conditions. The model is simulated using commercial CFD package, ANSYS FLUENT. The results obtained are compared against experimental data (AMCA standard 210) over wide range of flow rate. Provided the modeling strategy is chosen appropriately with correct configuration of mesh density and turbulent model then, the results correlates closely with experimental data. This is shown in this investigation. The guide vane incidence angle determination is also done in this paper for 30� and 40� blade pitch angle. The outcome of this paper would provide confidence for designers in numerical simulation for predicting performance of axial fan. In addition, numerical simulation creates a platform for systems to be optimized with a lower cost and high efficiency outcomes. � (2012) Trans Tech Publications, Switzerland. Final 2023-12-28T06:30:26Z 2023-12-28T06:30:26Z 2012 Conference paper 10.4028/www.scientific.net/AMM.225.91 2-s2.0-84871124521 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84871124521&doi=10.4028%2fwww.scientific.net%2fAMM.225.91&partnerID=40&md5=60a59aa70fa9ca134862e5c3809bb11f https://irepository.uniten.edu.my/handle/123456789/29537 225 91 96 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Axial fan
CFD
Axial flow turbomachinery
Computational fluid dynamics
Design
Helicopter rotors
Optimization
Testing
Turbomachine blades
Axial fans
Blade pitch
CFD modeling
Computational model
Experimental conditions
Fan designs
Guide vane
Incidence angles
Mesh density
Modeling strategy
Numerical investigations
Outlet guide vanes
Rotor blades
Stator blade
Test procedures
Turbulent models
Velocity vectors
Computer simulation
spellingShingle Axial fan
CFD
Axial flow turbomachinery
Computational fluid dynamics
Design
Helicopter rotors
Optimization
Testing
Turbomachine blades
Axial fans
Blade pitch
CFD modeling
Computational model
Experimental conditions
Fan designs
Guide vane
Incidence angles
Mesh density
Modeling strategy
Numerical investigations
Outlet guide vanes
Rotor blades
Stator blade
Test procedures
Turbulent models
Velocity vectors
Computer simulation
Munisamy K.M.
Govindasamy R.
Thangaraju S.K.
Experimental and numerical investigation onto 1250mm axial fan
description Numerical simulation is of interest for most fan designers to optimize the fan designs. Computational fluid dynamic (CFD) has become an essential tool in almost every branch of fluid dynamics and one of the major tools for fan designs. As the fan designers relying on the numerical simulation, the accuracy of tools such as CFD in predicting the performance has become a subject of interest. This paper validates the CFD modeling of an axial fan design against experimental result. The experimental rig and test procedure are developed with reference to "AMCA standard 210". The analysis is conducted on 1250mm diameter axial fan with two different blade pitch angle 30� and 40�. Prior to encounter the swirling effect and deflection of velocity vector due to rotor blade, a stator blade with the same profile as rotor blade is used as the outlet guide vanes in opposite direction. The computational model is created according to the experimental condition and applied realistic boundary conditions. The model is simulated using commercial CFD package, ANSYS FLUENT. The results obtained are compared against experimental data (AMCA standard 210) over wide range of flow rate. Provided the modeling strategy is chosen appropriately with correct configuration of mesh density and turbulent model then, the results correlates closely with experimental data. This is shown in this investigation. The guide vane incidence angle determination is also done in this paper for 30� and 40� blade pitch angle. The outcome of this paper would provide confidence for designers in numerical simulation for predicting performance of axial fan. In addition, numerical simulation creates a platform for systems to be optimized with a lower cost and high efficiency outcomes. � (2012) Trans Tech Publications, Switzerland.
author2 15035918600
author_facet 15035918600
Munisamy K.M.
Govindasamy R.
Thangaraju S.K.
format Conference paper
author Munisamy K.M.
Govindasamy R.
Thangaraju S.K.
author_sort Munisamy K.M.
title Experimental and numerical investigation onto 1250mm axial fan
title_short Experimental and numerical investigation onto 1250mm axial fan
title_full Experimental and numerical investigation onto 1250mm axial fan
title_fullStr Experimental and numerical investigation onto 1250mm axial fan
title_full_unstemmed Experimental and numerical investigation onto 1250mm axial fan
title_sort experimental and numerical investigation onto 1250mm axial fan
publishDate 2023
_version_ 1806425805327171584
score 13.188404

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