Fluid–Structure Coupling and Aerodynamic Performance of a Multi-Dimensional Morphing Wing with Flexible Metastructure Skin

Yang, Hui; Jiang, Songcheng; Wang, Yan; Xiao, Hong

doi:10.3390/aerospace10080678

Aerospace

2023

DOI: 10.3390/aerospace10080678

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Fluid–Structure Coupling and Aerodynamic Performance of a Multi-Dimensional Morphing Wing with Flexible Metastructure Skin

Hui Yang,

Songcheng Jiang,

Yan Wang

et al.

Abstract: A multi-dimensional morphing wing skeleton mechanism is proposed with double-sided triangular pyramid units, which can realize continuous variable span-wise bend, span-wise twist, and sweep. A lockable morphing unit is designed, and its mechanism/structure characteristics, degree of freedom, and the deformable function of its deformable wing skeleton mechanism are analyzed. One kind of flexible skin is proposed to meet the performance requirements, consisting of an internal metastructure and a flexible surface… Show more

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Cited by 4 publications

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Design, kinematic and fluid-structure interaction analysis of a morphing wing

Yang,

Jiang,

Wang

et al. 2023

Aerospace Science and Technology

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Design, kinematic and fluid-structure interaction analysis of a morphing wing

Yang,

Jiang,

Wang

et al. 2023

Aerospace Science and Technology

View full text Add to dashboard Cite

Tension-twist coupling morphing wing using a novel mechanical metamaterial

Zhu,

Zhang,

Chen

et al. 2024

Aerospace Science and Technology

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Numerical investigation of aerodynamic performance in a morphing wing with flexible leading edge using computational fluid dynamics

Shi,

Han,

et al. 2024

J. Eng. Appl. Sci.

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In this study, a numerical investigation into the sustained aerodynamic performance of a morphing wing equipped with a flexible leading edge, employing a 2-dimensional NACA0012 airfoil configuration, is conducted. The compressible governing equations of the flow are employed, simulating 2 distinct states: the airfoil without motion and the airfoil featuring a flexible leading edge with a chord length of 0.856 m, assessing various angles of attack utilizing the k-ω SST turbulence approach within Fluent software. Dynamic mesh, facilitated by a user-defined function, is utilized in Fluent software to simulate the movement of the airfoil wall at the leading edge. The study thoroughly analyzes the flow behavior concerning diverse angles of attack and deviations, evaluating their impact on aerodynamic coefficients, velocity, and pressure fields under steady-state settings. Validation of the chosen numerical approach demonstrates close alignment of the front and back coefficients with experimental settings. Outcomes from the steady-state flow simulation of the morphing wing reveal that positive deflection angles correspond to increased lift coefficients and decreased drag coefficients, with lift coefficient increases of up to 15% and drag coefficient reductions of up to 10% at specific angles. Meanwhile, the negative deflection angles have shown a decline in lift coefficients, with the drag coefficients increasing with the decrease in deflection angle. All these observations show that at the flexible leading edge, there is a considerable improvement in aerodynamic efficiency. Hence, it should find more applications in different regimes of flight.

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Fluid–Structure Coupling and Aerodynamic Performance of a Multi-Dimensional Morphing Wing with Flexible Metastructure Skin

Cited by 4 publications

References 20 publications

Design, kinematic and fluid-structure interaction analysis of a morphing wing

Design, kinematic and fluid-structure interaction analysis of a morphing wing

Tension-twist coupling morphing wing using a novel mechanical metamaterial

Numerical investigation of aerodynamic performance in a morphing wing with flexible leading edge using computational fluid dynamics

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