中国物理B ›› 2013, Vol. 22 ›› Issue (8): 88702-088702.doi: 10.1088/1674-1056/22/8/088702

• INTERDISCIPLINARY PHYSICS AND RELATED AREAS OF SCIENCE AND TECHNOLOGY • 上一篇    下一篇

Experimental investigations of the functional morphology of dragonfly wings

H. Rajabi, A. Darvizeh   

  1. Department of Mechanical Engineering, Faculty of Engineering, The University of Guilan, Rasht, Iran
  • 收稿日期:2013-01-23 修回日期:2013-03-05 出版日期:2013-06-27 发布日期:2013-06-27

Experimental investigations of the functional morphology of dragonfly wings

H. Rajabi, A. Darvizeh   

  1. Department of Mechanical Engineering, Faculty of Engineering, The University of Guilan, Rasht, Iran
  • Received:2013-01-23 Revised:2013-03-05 Online:2013-06-27 Published:2013-06-27
  • Contact: H. Rajabi E-mail:harajabi@ahrar.ac.ir

摘要: Nowadays, the importance of identifying the flight mechanisms of the dragonfly, as an inspiration for designing flapping wing vehicles, is well known. An experimental approach to understanding the complexities of insect wings as organs of flight could provide significant outcomes for design purposes. In this paper, a comprehensive investigation is carried out on the morphological and microstructural features of dragonfly wings. Scanning electron microscopy (SEM) and tensile testing are used to experimentally verify the functional roles of different parts of the wings. A number of SEM images of the elements of the wings, such as the nodus, leading edge, trailing edge, and vein sections, which play dominant roles in strengthening the whole structure, are presented. The results from the tensile tests indicate that the nodus might be the critical region of the wing that is subjected to high tensile stresses. Considering the patterns of the longitudinal corrugations of the wings obtained in this paper, it can be supposed that they increase the load-bearing capacity, giving the wings an ability to tolerate dynamic loading conditions. In addition, it is suggested that the longitudinal veins, along with the leading and trailing edges, are structural mechanisms that further improve fatigue resistance by providing higher fracture toughness, preventing crack propagation, and allowing the wings to sustain a significant amount of damage without loss of strength.

关键词: dragonfly wings, SEM, tensile test, nodus, longitudinal corrugation

Abstract: Nowadays, the importance of identifying the flight mechanisms of the dragonfly, as an inspiration for designing flapping wing vehicles, is well known. An experimental approach to understanding the complexities of insect wings as organs of flight could provide significant outcomes for design purposes. In this paper, a comprehensive investigation is carried out on the morphological and microstructural features of dragonfly wings. Scanning electron microscopy (SEM) and tensile testing are used to experimentally verify the functional roles of different parts of the wings. A number of SEM images of the elements of the wings, such as the nodus, leading edge, trailing edge, and vein sections, which play dominant roles in strengthening the whole structure, are presented. The results from the tensile tests indicate that the nodus might be the critical region of the wing that is subjected to high tensile stresses. Considering the patterns of the longitudinal corrugations of the wings obtained in this paper, it can be supposed that they increase the load-bearing capacity, giving the wings an ability to tolerate dynamic loading conditions. In addition, it is suggested that the longitudinal veins, along with the leading and trailing edges, are structural mechanisms that further improve fatigue resistance by providing higher fracture toughness, preventing crack propagation, and allowing the wings to sustain a significant amount of damage without loss of strength.

Key words: dragonfly wings, SEM, tensile test, nodus, longitudinal corrugation

中图分类号:  (Biomaterials)

  • 87.85.J-
81.05.Zx (New materials: theory, design, and fabrication) 87.19.R- (Mechanical and electrical properties of tissues and organs) 87.18.-h (Biological complexity)