J4 ›› 2012, Vol. 9 ›› Issue (3): 294-303.doi: 10.1016/S1672-6529(11)60123-6

• 论文 • 上一篇    下一篇

Dynamic Flight Stability of a Model Hoverfly in Inclined-Stroke-Plane Hovering

Xiaolei Mou, Mao Sun   

  1. Key Laboratory of Fluid Mechanics (Ministry of Education, China), Beihang University,
    Beijing 100191, P. R. China
  • 出版日期:2012-09-30
  • 通讯作者: Xiaolei Mou E-mail:mouxiaolei@ase.buaa.edu.cn

Dynamic Flight Stability of a Model Hoverfly in Inclined-Stroke-Plane Hovering

Xiaolei Mou, Mao Sun   

  1. Key Laboratory of Fluid Mechanics (Ministry of Education, China), Beihang University,
    Beijing 100191, P. R. China
  • Online:2012-09-30
  • Contact: Xiaolei Mou E-mail:mouxiaolei@ase.buaa.edu.cn

摘要:

Most hovering insects flap their wings in a horizontal plane, called ‘normal hovering’. But some of the best hoverers, e.g. true hoverflies, hover with an inclined stroke plane. In the present paper, the longitudinal dynamic flight stability of a model hoverfly in inclined-stroke-plane hovering was studied. Computational fluid dynamics was used to compute the aerodynamic derivatives and the eigenvalue and eigenvector analysis was used to solve the equations of motion. The primary findings are as follows. (1) For inclined-stroke-plane hovering, the same three natural modes of motion as those for normal hovering were identified: one unstable oscillatory mode, one stable fast subsidence mode, and one stable slow subsidence mode. The unstable oscillatory mode and the fast subsidence mode mainly have horizontal translation and pitch rotation, and the slow subsidence mode mainly has vertical translation. (2) Because of the existence of the unstable oscillatory mode, inclined-stroke-plane hovering flight is not stable. (3) Although there are large differences in stroke plane and body orientations between the inclined-stroke-plane hovering and normal hovering, the relative position between the mean center of pressure and center of mass for these two cases is not very different, resulting in similar stability derivatives, hence similar dynamic stability properties for these two types of hovering.

关键词: insect, dynamic flight stability, inclined-stroke-plane hovering, natural modes of motion

Abstract:

Most hovering insects flap their wings in a horizontal plane, called ‘normal hovering’. But some of the best hoverers, e.g. true hoverflies, hover with an inclined stroke plane. In the present paper, the longitudinal dynamic flight stability of a model hoverfly in inclined-stroke-plane hovering was studied. Computational fluid dynamics was used to compute the aerodynamic derivatives and the eigenvalue and eigenvector analysis was used to solve the equations of motion. The primary findings are as follows. (1) For inclined-stroke-plane hovering, the same three natural modes of motion as those for normal hovering were identified: one unstable oscillatory mode, one stable fast subsidence mode, and one stable slow subsidence mode. The unstable oscillatory mode and the fast subsidence mode mainly have horizontal translation and pitch rotation, and the slow subsidence mode mainly has vertical translation. (2) Because of the existence of the unstable oscillatory mode, inclined-stroke-plane hovering flight is not stable. (3) Although there are large differences in stroke plane and body orientations between the inclined-stroke-plane hovering and normal hovering, the relative position between the mean center of pressure and center of mass for these two cases is not very different, resulting in similar stability derivatives, hence similar dynamic stability properties for these two types of hovering.

Key words: insect, dynamic flight stability, inclined-stroke-plane hovering, natural modes of motion