Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions

This paper presents a numerical method investigation on the aerodynamic performance of a small-scale propeller with four different shapes of propeller design using computational fluid dynamic (CFD). In this study, the relationship between varying airfoil's origin position (AOP) at each station...

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Main Authors: Ahmad Faris, Ahmad Fariduddin, Basri, Adi Azriff, Basri, Ernnie Illyani, Hameed Sultan, Mohammed Thariq, Ahmad, Kamarul Arifin
Format: Article
Published: Zhongguo Hangkong Taikong Xuehui 2022
Online Access:http://psasir.upm.edu.my/id/eprint/100144/
https://www.airitilibrary.com/Article/Detail/P20140627004-202209-202204060005-202204060005-325-334
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Institution: Universiti Putra Malaysia
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spelling my.upm.eprints.1001442024-07-17T03:04:29Z http://psasir.upm.edu.my/id/eprint/100144/ Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions Ahmad Faris, Ahmad Fariduddin Basri, Adi Azriff Basri, Ernnie Illyani Hameed Sultan, Mohammed Thariq Ahmad, Kamarul Arifin This paper presents a numerical method investigation on the aerodynamic performance of a small-scale propeller with four different shapes of propeller design using computational fluid dynamic (CFD). In this study, the relationship between varying airfoil's origin position (AOP) at each station and resultant aerodynamics performance is investigated. Several designs of the propellers are derived by changing the AOP at each blade station with the percentage of 0% AOP, 25% AOP, 50% AOP, 75% AOP and 100% AOP. The result of thrust, power coefficients and efficiencies are validated with the existing experimental wind tunnel data. All in all, the results show that propeller design with 100% AOP generates better aerodynamic performance than the one with 25% AOP by 7.473%, -5.587% and 15.891% in terms of thrust, coefficient of power and efficiency, respectively. It has also been found that the propeller design with 100% AOP has a better aerodynamics performance compared to the 25% AOP, 50% AOP and 75% AOP, especially at an advanced ratio of 0.799. Overall, it can be concluded that the improvement in terms of aerodynamic characteristics and performance is possible by increasing the position of the blade origin at each station, which in turn results in different propeller design shapes. Zhongguo Hangkong Taikong Xuehui 2022-09-01 Article PeerReviewed Ahmad Faris, Ahmad Fariduddin and Basri, Adi Azriff and Basri, Ernnie Illyani and Hameed Sultan, Mohammed Thariq and Ahmad, Kamarul Arifin (2022) Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions. Journal of Aeronautics, Astronautics and Aviation, 54 (3). pp. 325-334. ISSN 1990-7710 https://www.airitilibrary.com/Article/Detail/P20140627004-202209-202204060005-202204060005-325-334 10.6125/JoAAA.202209_54(3).09
institution Universiti Putra Malaysia
building UPM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Putra Malaysia
content_source UPM Institutional Repository
url_provider http://psasir.upm.edu.my/
description This paper presents a numerical method investigation on the aerodynamic performance of a small-scale propeller with four different shapes of propeller design using computational fluid dynamic (CFD). In this study, the relationship between varying airfoil's origin position (AOP) at each station and resultant aerodynamics performance is investigated. Several designs of the propellers are derived by changing the AOP at each blade station with the percentage of 0% AOP, 25% AOP, 50% AOP, 75% AOP and 100% AOP. The result of thrust, power coefficients and efficiencies are validated with the existing experimental wind tunnel data. All in all, the results show that propeller design with 100% AOP generates better aerodynamic performance than the one with 25% AOP by 7.473%, -5.587% and 15.891% in terms of thrust, coefficient of power and efficiency, respectively. It has also been found that the propeller design with 100% AOP has a better aerodynamics performance compared to the 25% AOP, 50% AOP and 75% AOP, especially at an advanced ratio of 0.799. Overall, it can be concluded that the improvement in terms of aerodynamic characteristics and performance is possible by increasing the position of the blade origin at each station, which in turn results in different propeller design shapes.
format Article
author Ahmad Faris, Ahmad Fariduddin
Basri, Adi Azriff
Basri, Ernnie Illyani
Hameed Sultan, Mohammed Thariq
Ahmad, Kamarul Arifin
spellingShingle Ahmad Faris, Ahmad Fariduddin
Basri, Adi Azriff
Basri, Ernnie Illyani
Hameed Sultan, Mohammed Thariq
Ahmad, Kamarul Arifin
Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions
author_facet Ahmad Faris, Ahmad Fariduddin
Basri, Adi Azriff
Basri, Ernnie Illyani
Hameed Sultan, Mohammed Thariq
Ahmad, Kamarul Arifin
author_sort Ahmad Faris, Ahmad Fariduddin
title Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions
title_short Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions
title_full Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions
title_fullStr Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions
title_full_unstemmed Aerodynamics effects of APC slow flyer propeller blade design with different airfoil origin positions
title_sort aerodynamics effects of apc slow flyer propeller blade design with different airfoil origin positions
publisher Zhongguo Hangkong Taikong Xuehui
publishDate 2022
url http://psasir.upm.edu.my/id/eprint/100144/
https://www.airitilibrary.com/Article/Detail/P20140627004-202209-202204060005-202204060005-325-334
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