Improvement of Electric Aircraft Endurance through Propeller Optimization via BEM-CFD Methodology

José D. Hoyos; Jesús H. Jímenez; Pablo Alvarado

doi:10.1088/1742-6596/1733/1/012011

Improvement of Electric Aircraft Endurance through Propeller Optimization via BEM-CFD Methodology

José D. Hoyos, Jesús H. Jímenez, Pablo Alvarado

Aerospace Engineering

Research output: Contribution to journal › Conference and proceedings › peer-review

2 Scopus citations

Abstract

An exhaustive optimization method is developed to minimize the power consumption for a propeller-driven electrical aircraft. The method finds the optimal value for a wide range of geometrical and operational parameters for a target thrust and airspeed. The optimization routine employs BEM for propeller predictions fed with aerodynamic airfoil data obtained from a proposed combined CFD-Montgomerie method which is also validated, furthermore several corrections to account for compressibility, three dimensional, viscous and Reynolds number effects are implemented. This BEM model showed an adequate fitting with experimental data. Additionally, Goldstein optimization via Vortex Theory is employed to design pitch and chord distributions minimizing the induced losses of the propeller. The optimization algorithm is validated through a study case where an existent optimization problem is approached leading to very similar results. Some trends and insights are obtained and discussed from the study case regarding the design of an optimal propulsion system. Finally, CFD simulations of the study case are carried out showing a slight relative error of BEM.

Original language	English
Article number	012011
Journal	Journal of Physics: Conference Series
Volume	1733
Issue number	1
DOIs	https://doi.org/10.1088/1742-6596/1733/1/012011
State	Published - 19 Jan 2021
Event	2nd International Conference on Trends in Mechanical and Aerospace, TMAE 2020 - Washington, Virtual, United States Duration: 25 Sep 2020 → 27 Sep 2020

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© Published under licence by IOP Publishing Ltd.

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10.1088/1742-6596/1733/1/012011

Cite this

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title = "Improvement of Electric Aircraft Endurance through Propeller Optimization via BEM-CFD Methodology",

abstract = "An exhaustive optimization method is developed to minimize the power consumption for a propeller-driven electrical aircraft. The method finds the optimal value for a wide range of geometrical and operational parameters for a target thrust and airspeed. The optimization routine employs BEM for propeller predictions fed with aerodynamic airfoil data obtained from a proposed combined CFD-Montgomerie method which is also validated, furthermore several corrections to account for compressibility, three dimensional, viscous and Reynolds number effects are implemented. This BEM model showed an adequate fitting with experimental data. Additionally, Goldstein optimization via Vortex Theory is employed to design pitch and chord distributions minimizing the induced losses of the propeller. The optimization algorithm is validated through a study case where an existent optimization problem is approached leading to very similar results. Some trends and insights are obtained and discussed from the study case regarding the design of an optimal propulsion system. Finally, CFD simulations of the study case are carried out showing a slight relative error of BEM.",

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AU - Jímenez, Jesús H.

AU - Alvarado, Pablo

N1 - Publisher Copyright: © Published under licence by IOP Publishing Ltd.

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Y1 - 2021/1/19

N2 - An exhaustive optimization method is developed to minimize the power consumption for a propeller-driven electrical aircraft. The method finds the optimal value for a wide range of geometrical and operational parameters for a target thrust and airspeed. The optimization routine employs BEM for propeller predictions fed with aerodynamic airfoil data obtained from a proposed combined CFD-Montgomerie method which is also validated, furthermore several corrections to account for compressibility, three dimensional, viscous and Reynolds number effects are implemented. This BEM model showed an adequate fitting with experimental data. Additionally, Goldstein optimization via Vortex Theory is employed to design pitch and chord distributions minimizing the induced losses of the propeller. The optimization algorithm is validated through a study case where an existent optimization problem is approached leading to very similar results. Some trends and insights are obtained and discussed from the study case regarding the design of an optimal propulsion system. Finally, CFD simulations of the study case are carried out showing a slight relative error of BEM.

AB - An exhaustive optimization method is developed to minimize the power consumption for a propeller-driven electrical aircraft. The method finds the optimal value for a wide range of geometrical and operational parameters for a target thrust and airspeed. The optimization routine employs BEM for propeller predictions fed with aerodynamic airfoil data obtained from a proposed combined CFD-Montgomerie method which is also validated, furthermore several corrections to account for compressibility, three dimensional, viscous and Reynolds number effects are implemented. This BEM model showed an adequate fitting with experimental data. Additionally, Goldstein optimization via Vortex Theory is employed to design pitch and chord distributions minimizing the induced losses of the propeller. The optimization algorithm is validated through a study case where an existent optimization problem is approached leading to very similar results. Some trends and insights are obtained and discussed from the study case regarding the design of an optimal propulsion system. Finally, CFD simulations of the study case are carried out showing a slight relative error of BEM.

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Y2 - 25 September 2020 through 27 September 2020

ER -

Improvement of Electric Aircraft Endurance through Propeller Optimization via BEM-CFD Methodology

Abstract

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