Aerodynamic design optimization for low Reynolds tandem airfoil

Fangzheng Chen; Jianqiao Yu; Yuesong Mei

doi:10.1177/0954410017704219

Aerodynamic design optimization for low Reynolds tandem airfoil

Fangzheng Chen, Jianqiao Yu^*, Yuesong Mei

^*Corresponding author for this work

School of Aerospace Engineering

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

18 Citations (Scopus)

Abstract

A series of aerodynamic design optimization studies are performed to investigate the performance of two-dimensional tandem airfoil at low Reynolds number of 220,000. A total of 23 design variables, including decalage, gap, stagger, and airfoil profile variables are considered. Hierarchical evolutionary algorithm together with dynamic metamodel optimization is used to achieve the maximum lift-to-drag ratio for tandem airfoil. The studies investigate the impact of various design variables on optimized tandem airfoil. The results show that tandem airfoil in lower Reynolds flow has better aerodynamic performance at high angle of attack. And the lift-to-drag ratio can be further increased by 11.9% when airfoil profile variables are introduced. Morphing tandem airfoil can overcome low lift-to-drag ratio at lower lift coefficient, and is attractive for unmanned aircraft.

Original language	English
Pages (from-to)	1047-1062
Number of pages	16
Journal	Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering
Volume	232
Issue number	6
DOIs	https://doi.org/10.1177/0954410017704219
Publication status	Published - 1 May 2018

Keywords

Low Reynolds flow
aerodynamic optimization
laminar separation bubble
metamodel
tandem airfoil

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10.1177/0954410017704219

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title = "Aerodynamic design optimization for low Reynolds tandem airfoil",

abstract = "A series of aerodynamic design optimization studies are performed to investigate the performance of two-dimensional tandem airfoil at low Reynolds number of 220,000. A total of 23 design variables, including decalage, gap, stagger, and airfoil profile variables are considered. Hierarchical evolutionary algorithm together with dynamic metamodel optimization is used to achieve the maximum lift-to-drag ratio for tandem airfoil. The studies investigate the impact of various design variables on optimized tandem airfoil. The results show that tandem airfoil in lower Reynolds flow has better aerodynamic performance at high angle of attack. And the lift-to-drag ratio can be further increased by 11.9% when airfoil profile variables are introduced. Morphing tandem airfoil can overcome low lift-to-drag ratio at lower lift coefficient, and is attractive for unmanned aircraft.",

keywords = "Low Reynolds flow, aerodynamic optimization, laminar separation bubble, metamodel, tandem airfoil",

author = "Fangzheng Chen and Jianqiao Yu and Yuesong Mei",

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AU - Chen, Fangzheng

AU - Yu, Jianqiao

AU - Mei, Yuesong

PY - 2018/5/1

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N2 - A series of aerodynamic design optimization studies are performed to investigate the performance of two-dimensional tandem airfoil at low Reynolds number of 220,000. A total of 23 design variables, including decalage, gap, stagger, and airfoil profile variables are considered. Hierarchical evolutionary algorithm together with dynamic metamodel optimization is used to achieve the maximum lift-to-drag ratio for tandem airfoil. The studies investigate the impact of various design variables on optimized tandem airfoil. The results show that tandem airfoil in lower Reynolds flow has better aerodynamic performance at high angle of attack. And the lift-to-drag ratio can be further increased by 11.9% when airfoil profile variables are introduced. Morphing tandem airfoil can overcome low lift-to-drag ratio at lower lift coefficient, and is attractive for unmanned aircraft.

AB - A series of aerodynamic design optimization studies are performed to investigate the performance of two-dimensional tandem airfoil at low Reynolds number of 220,000. A total of 23 design variables, including decalage, gap, stagger, and airfoil profile variables are considered. Hierarchical evolutionary algorithm together with dynamic metamodel optimization is used to achieve the maximum lift-to-drag ratio for tandem airfoil. The studies investigate the impact of various design variables on optimized tandem airfoil. The results show that tandem airfoil in lower Reynolds flow has better aerodynamic performance at high angle of attack. And the lift-to-drag ratio can be further increased by 11.9% when airfoil profile variables are introduced. Morphing tandem airfoil can overcome low lift-to-drag ratio at lower lift coefficient, and is attractive for unmanned aircraft.

KW - Low Reynolds flow

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KW - laminar separation bubble

KW - metamodel

KW - tandem airfoil

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Aerodynamic design optimization for low Reynolds tandem airfoil

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