Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller
The current work presents a numerical method prediction using the commercial Computational Fluid Dynamic (CFD) of ANSYS FLUENT in order to determine the best propeller design which produce the nearest aerodynamics performance with the experimental data of a small-scale propeller. This study implemen...
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Transstellar
2020
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my.upm.eprints.882302022-03-10T03:54:18Z http://psasir.upm.edu.my/id/eprint/88230/ Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller Ahmad Faris, Ahmad Fariduddin Basri, Adi Azriff Basri, Ernnie Illyani Gires, Ezanee Hameed Sultan, Mohamed Thariq Ahmad, Kamarul Arifin The current work presents a numerical method prediction using the commercial Computational Fluid Dynamic (CFD) of ANSYS FLUENT in order to determine the best propeller design which produce the nearest aerodynamics performance with the experimental data of a small-scale propeller. This study implements 2 different propeller design by changing the airfoil origin position (AOP) at each of blade design station which create the different design of propeller shape. The changing of AOP is referred in terms of percentage of 0% AOP and 25% AOP of the respective airfoil chord from the hub of the propeller blade. The study utilizes a tetrahedron meshing throughout the analysis with different turbulence models comparison. Multiple Reference Frame (MRF) technique was used to create the rotation of the propeller towards its local reference frame at 3008 revolutions per minute (RPM). The result of thrust, power coefficients and the efficiencies are validated with the experimental wind tunnel data. The results showed that the model with 25% AOP generated the nearest amount of thrust, power, and efficiency when compared to experimental data with 0.82%, 6.68% and -5.49% for lowest advance ratio of 0.236. Hence, using novel technique of CFD analysis provide a better platform in designing the best aerodynamics propeller blade design before fabricate the actual model of propeller. Transstellar 2020 Article PeerReviewed text en http://psasir.upm.edu.my/id/eprint/88230/1/ABSTRACT.pdf Ahmad Faris, Ahmad Fariduddin and Basri, Adi Azriff and Basri, Ernnie Illyani and Gires, Ezanee and Hameed Sultan, Mohamed Thariq and Ahmad, Kamarul Arifin (2020) Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller. International Journal of Mechanical and Production Engineering Research and Development, 10 (6). 265 - 280. ISSN 2249–6890; ESSN: 2249–8001 http://www.tjprc.org/view_paper.php?id=14762 |
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The current work presents a numerical method prediction using the commercial Computational Fluid Dynamic (CFD) of ANSYS FLUENT in order to determine the best propeller design which produce the nearest aerodynamics performance with the experimental data of a small-scale propeller. This study implements 2 different propeller design by changing the airfoil origin position (AOP) at each of blade design station which create the different design of propeller shape. The changing of AOP is referred in terms of percentage of 0% AOP and 25% AOP of the respective airfoil chord from the hub of the propeller blade. The study utilizes a tetrahedron meshing throughout the analysis with different turbulence models comparison. Multiple Reference Frame (MRF) technique was used to create the rotation of the propeller towards its local reference frame at 3008 revolutions per minute (RPM). The result of thrust, power coefficients and the efficiencies are validated with the experimental wind tunnel data. The results showed that the model with 25% AOP generated the nearest amount of thrust, power, and efficiency when compared to experimental data with 0.82%, 6.68% and -5.49% for lowest advance ratio of 0.236. Hence, using novel technique of CFD analysis provide a better platform in designing the best aerodynamics propeller blade design before fabricate the actual model of propeller. |
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Article |
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Ahmad Faris, Ahmad Fariduddin Basri, Adi Azriff Basri, Ernnie Illyani Gires, Ezanee Hameed Sultan, Mohamed Thariq Ahmad, Kamarul Arifin |
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Ahmad Faris, Ahmad Fariduddin Basri, Adi Azriff Basri, Ernnie Illyani Gires, Ezanee Hameed Sultan, Mohamed Thariq Ahmad, Kamarul Arifin Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller |
author_facet |
Ahmad Faris, Ahmad Fariduddin Basri, Adi Azriff Basri, Ernnie Illyani Gires, Ezanee Hameed Sultan, Mohamed Thariq Ahmad, Kamarul Arifin |
author_sort |
Ahmad Faris, Ahmad Fariduddin |
title |
Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller |
title_short |
Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller |
title_full |
Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller |
title_fullStr |
Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller |
title_full_unstemmed |
Computation fluid dynamics study on aerodynamics blade design of Advance Precision Composite (APC) slow flyer propeller |
title_sort |
computation fluid dynamics study on aerodynamics blade design of advance precision composite (apc) slow flyer propeller |
publisher |
Transstellar |
publishDate |
2020 |
url |
http://psasir.upm.edu.my/id/eprint/88230/1/ABSTRACT.pdf http://psasir.upm.edu.my/id/eprint/88230/ http://www.tjprc.org/view_paper.php?id=14762 |
_version_ |
1728052819774144512 |