The effects of span-wise and chord-wise flexibility on the aerodynamic performance of micro flapping-wing 被引量：10

The effects of span-wise and chord-wise flexibility on the aerodynamic performance of micro flapping-wing

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摘要 The flexibility of flapping-wing strongly affects the aerodynamic performance of Flapping-wing Micro Air Vehicle (FMAV),and the deformations in span-wise and chord-wise directions are coupled together in flight.In this study,the flexible deformation is formulated in span-wise and chord-wise separately in order to analyze its effects on aerodynamic behavior.The preconditioned Navier-Stokes equations based on chimera grid are used in the computational fluid dynamics method to study the aerodynamic effects caused by flexible deformation,and the simulation results are compared with experimental test to illustrate the capability of above method.Based on our results,it is clearly showed that the span-wise flexible deformation should be limited in a small range to achieve higher aerodynamic performance and the chord-wise deformation could enhance the aerodynamic performance.The results also suggest that FMAV designers should design the flapping-wing with high stiffness leading edge to limit the span-wise deformation,and more flexible chord ribs to keep chord-wise deformation in suitable range. The flexibility of flapping-wing strongly affects the aerodynamic performance of Flapping-wing Micro Air Vehicle （FMAV）, and the deformations in span-wise and chord-wise directions are coupled together in flight. In this study, the flexible deformation is formulated in span-wise and chord-wise separately in order to analyze its effects on aerodynamic behavior. The preconditioned Navier-Stokes equations based on chimera grid are used in the computational fluid dynamics method to study the aerodynamic effects caused by flexible deformation, and the simulation results are compared with experimental test to illustrate the capability of above method. Based on our results, it is clearly showed that the span-wise flexible deformation should be limited in a small range t~ achie,m higher aerodynamic performance and the chord-wise deformation could enhance the aerodynamic performance. The results also suggest that FMAV designers should design the flapping-wing with high stiffness leading edge to limit the span-wise deformation, and more flexible chord ribs to keep chord-wise deformation in suitable range.

作者 YANG WenQing SONG BiFeng SONG WenPing WANG LiGuang

机构地区 School of Aeronautics

出处《Chinese Science Bulletin》 SCIE CAS 2012年第22期2887-2897,共11页

基金 supported by the Postdoctoral Science Foundation of China(20100481369)

关键词空气动力性能微型飞行器弹性变形 NAVIER-STOKES方程扑翼弦向空气动力学效应空气动力学性能 FMAV flexible flapping-wing Navier-Stokes equations chimera grid span-wise deformation chord-wise deformation

分类号 V211.41 [航空宇航科学与技术—航空宇航推进理论与工程]

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Chinese Science Bulletin

2012年第22期

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