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Effect of Different Types of Wing-Wing Interactions in Flapping MAVs

Wee Beng Tay   

  1. Temasek Laboratories, National University of Singapore, 5A Engineering Drive 1, 117411, Singapore
  • 收稿日期:2016-06-06 修回日期:2016-12-06 出版日期:2017-01-10 发布日期:2017-01-10
  • 通讯作者: Wee Beng Tay E-mail:tsltaywb@nus.edu.sg
  • 作者简介:Wee Beng Tay

Effect of Different Types of Wing-Wing Interactions in Flapping MAVs

Wee Beng Tay   

  1. Temasek Laboratories, National University of Singapore, 5A Engineering Drive 1, 117411, Singapore
  • Received:2016-06-06 Revised:2016-12-06 Online:2017-01-10 Published:2017-01-10
  • Contact: Wee Beng Tay E-mail:tsltaywb@nus.edu.sg
  • About author:Wee Beng Tay

摘要: Wing-Wing Interaction (WWI), such as the Clap and Fling Motion (CFM), occurs when two wings are flapping close together, improving performance. We intend to design a hovering Flapping Micro Aerial Vehicle (FMAV) which makes use of WWI. We investigate the effects of flexibility, kinematic motions, and two- to six-wing flapping configurations on the FMAV through numerical simulations. Results show that a rigid spanwise and flexible chordwise wing produces the highest lift with minimum power. The smoothly varying sinusoidal motion, which is visually similar to the CFM, produces similar lift in comparison to the CFM, while having lower peak power requirement. Lastly, lift produced by each wing of the two-, four-, six-wing configurations is approximately equal. Hence more wings generate higher total lift force, but at the expense of higher drag and power requirement. These results will be beneficial in the understanding of the underlying aerodynamics of WWI, and in improving the performance of our FMAV.

关键词: immersed boundary methods, clap and fling, MAV, flapping wings

Abstract: Wing-Wing Interaction (WWI), such as the Clap and Fling Motion (CFM), occurs when two wings are flapping close together, improving performance. We intend to design a hovering Flapping Micro Aerial Vehicle (FMAV) which makes use of WWI. We investigate the effects of flexibility, kinematic motions, and two- to six-wing flapping configurations on the FMAV through numerical simulations. Results show that a rigid spanwise and flexible chordwise wing produces the highest lift with minimum power. The smoothly varying sinusoidal motion, which is visually similar to the CFM, produces similar lift in comparison to the CFM, while having lower peak power requirement. Lastly, lift produced by each wing of the two-, four-, six-wing configurations is approximately equal. Hence more wings generate higher total lift force, but at the expense of higher drag and power requirement. These results will be beneficial in the understanding of the underlying aerodynamics of WWI, and in improving the performance of our FMAV.

Key words: flapping wings, clap and fling, immersed boundary methods, MAV