2021
DOI: 10.1017/aer.2021.51
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Propeller aerodynamic optimisation to minimise energy consumption for electric fixed-wing aircraft

Abstract: An electric propulsion model for propeller-driven aircraft is developed with the aim of minimising the power consumption for a given airspeed and thrust. Blade Element Momentum Theory (BEMT) is employed for propeller performance predictions fed with aerodynamic aerofoil data obtained from a proposed combined Computational Fluid Dynamics (CFD)–Montgomerie method, which is also validated. The Two-Dimensional (2D) aerofoil data are corrected to consider compressibility, three-dimensional, viscous and Reynolds-num… Show more

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Cited by 1 publication
(4 citation statements)
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“…Additionally, the distributions are compared against Goldstein distributions, which are the optimal pitch and chord calculated through the Euler-Lagrange equations applied to vortex theory. Some details about how to calculate these distributions can be found in [9]. Nevertheless, the Goldstein distributions are unique for given trust, airfoil distribution, and operational conditions having a considerably lower computational cost; hence, these distributions are analyzed for looking at an insight, which allows reducing the current computational cost of searching a distribution with a PSO that fulfills the target thrust while minimizing the torque.…”
Section: Case Of Studymentioning
confidence: 99%
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“…Additionally, the distributions are compared against Goldstein distributions, which are the optimal pitch and chord calculated through the Euler-Lagrange equations applied to vortex theory. Some details about how to calculate these distributions can be found in [9]. Nevertheless, the Goldstein distributions are unique for given trust, airfoil distribution, and operational conditions having a considerably lower computational cost; hence, these distributions are analyzed for looking at an insight, which allows reducing the current computational cost of searching a distribution with a PSO that fulfills the target thrust while minimizing the torque.…”
Section: Case Of Studymentioning
confidence: 99%
“…Nevertheless, the Goldstein distributions are unique for given trust, airfoil distribution, and operational conditions having a considerably lower computational cost; hence, these distributions are analyzed for looking at an insight, which allows reducing the current computational cost of searching a distribution with a PSO that fulfills the target thrust while minimizing the torque. Moreover, in [9], the thin propeller results also showed the difficulty of optimizing the propeller aerodynamic without considering the structural constraints. However, similar airfoil thickness and camber distributions (with a minimum value somewhere between tip and root) were obtained in that study (nevertheless, the airfoil design space is different).…”
Section: Case Of Studymentioning
confidence: 99%
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