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Observations and measurements of wing parameters of the selected beetle species and the design of a mechanism structure implementing a complex wing movement

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Języki publikacji
EN
Abstrakty
EN
Beetle wings perform a flapping movement, consisting of the rotation relative to the two axes. This paper presents the results of observations and measurements of wings operating parameters in different planes of some beetle species. High speed photos and videos were used. The concept of the mechanism performing a complex wing movement was proposed and developed.
Rocznik
Strony
837--847
Opis fizyczny
Bibliogr. 38 poz., rys., tab.
Twórcy
autor
  • Institute of Mechanics and Machine Design Foundations, The Faculty of Mechanical Engineering and Computer Science, Czestochowa University of Technology, ul. J.H. Dąbrowskiego 73, 42–200 Częstochowa, Poland
Bibliografia
  • [1] Bhayu P.R., Nguyen Q.V., Park H.C., Goo N.S. and Byun D. (2010): Artifical Cambrered-Wing for a Beetle-Mimicking Flaper. – Journal of Bionic Engineering, 7 Suppl, pp.S130-S136.
  • [2] Nguyen Q.V., Park H.C, Goo S.G. and Byun D. (2010): Characteristics of a Beetle’s Free Flight and a Flapping-Wing System that Mimics Beetle Flight. – Journal of Bionic Engineering. 7 Suppl., pp.77-86.
  • [3] Frantsevich L. (2011): Mechanisms Modeling the Double Rotation of the Elytra in Beetles (Coleoptera). – Journal of Bionic Engineering, vol.8, pp.395–405.
  • [4] Frantsevich L. (2012): Double rotation of the opening (closing) elytra in beetles (Coleoptera). – Journal of Insect Physiology, vol.58, pp.24-34.
  • [5] Frantsevich L. (2012): Indirect closing of elytra by the prothorax in beetles (Coleoptera): general observations and exceptions. – Zoology, vol.115, pp.12-21.
  • [6] Fenelon M.A.A. and Furukawa T. (2010): Design of an active flapping wing mechanism and a micro aerial vehicle using a rotary actuator. – Mechanism and Machine Theory, vol.45, pp.137–146.
  • [7] Nguyen Q.V., Truong Q.T., Hoon Park H.C, Goo S.G. and Byun D. (2010): Measurement of Force Produced by an Insect-Mimicking Flapping-Wing System. – Journal of Bionic Engineering, 7 Suppl., pp.S94-S102.
  • [8] Czekałowski P. and Sibilski K. (2012): Influence of cruise flight speed of entomopter on aerodynamics loads. – Gliwice: Modelling in Engineering, vol.45. No.14, pp.206-212.
  • [9] Czekałowski P. (2009): Investigation of the Entomopter’s wings movement kinematics on its performance - the general concept of research. – Modelling in Engineering, vol. 37, pp.71-76, Gliwice.
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  • [11] Haas F. and Beutel R.G. (2001): Wing folding and the functional morphology of the wing base in Coleoptera. – Zoology, vol.104, pp.123-141.
  • [12] Muhammad A., Nguyen Q.V., Park H.C, Hwang D.Y., Byun D. and Goo S.G. (2010): Improvement of artificial foldable wing models by mimicking the unfolding/folding mechanism of a beetle hind wing. – Journal of Bionic Engineering, 7 Suppl, pp.134-141.
  • [13] Phan H.V., Nguyen Q.V., Truong Q.T., Truong T.V., Park H.C., Goo N.S., Byun D. and Kim N.J. (2012): Stable vertical takeoff of an insect-mimicking flapping-wing system without guide implementing inherent pitching stability. – Journal of Bionic Engineering, vol.9, pp.391–401.
  • [14] Czekałowski P., Nowakowski M., Sibilski K., Żyluk A. and Wróblewski W. (2014): Neural model of an entomopter aerodynamics. AIAA Atmospheric Flight Mechanics Conference, AIAA SciTech, – AIAA 2014-0893.
  • [15] Truong Q.T., Argyoganendro B.W. and Park H.C. (2014): Design and demonstration of insect mimicking foldable artificial wing using four-bar linkage systems. – Journal of Bionic Engineering, vol.11, No.3, pp.449–458.
  • [16] Dawson J.C. and Huang P.G. (2011): Figure-8 flapping micro air vehicle. 49th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition 4 - 7 January 2011, Orlando, Florida, – AIAA 2011-551.
  • [17] Khan Z.A. and Agrawal S.K. (2011): Study of biologically inspired flapping mechanism for micro air vehicles. – AIAA JOURNAL, vol.49, No.7, July 2011, pp.1354-1365.
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  • [19] Seshadri P., Benedict M. and Chopra I. (2013): Understanding Micro Air Vehicle Flapping-Wing Aerodynamics Using Force and Flowfield Measurements. – Journal of Aircraft, vol.50, No.4, July–August 2013, pp.1070-1087.
  • [20] Oppenheimer M.W., Sigthorsson D.O., Weintraub I.E., Smith T.J., Dawson J.C. and Doman D.B. (2013): Development of a Flapping Wing Mechanism That Can Produce Lift Greater Than Weight. Guidance, Navigation, and Control and Co-located Conferences, August 19-22, 2013, Boston, MA, – AIAA 2013-5106.
  • [21] Tsai B.J. and Fu Y.C. (2009): Design and aerodynamic analysis of a flapping-wing micro aerial vehicle. – Aerospace Science and Technology 13 pp.383–392.
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  • [23] Geisler T. (2011): Construction and wing folding of selected families of beetles (Coloptera). – Czestochowa Entomological Circle Bulletin, No.10, pp.12-21.
  • [24] Geisler T. (2012): Analysis of the structure and mechanism of wing folding and flexion in Xylotrupes gideon beetle (L. 1767) (Coloptera, Scarabaeidae). – Acta Mechanica et Automatica, vol.6, No.3, pp.37-44.
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  • [31] Sun J., Ling M., Wu W., Bhushan B. and Tong J. (2014): The hydraulic mechanism of the unfolding of hind wings in dorcus titanus platymelus (order: coleoptera). – International Journal of Molecular Sciences, vol.15, pp.6009-6018.
  • [32] Geisler T. (2014): Wing functionality observation of the selected beetle species (Coleoptera: Scarabaeidae, Cerambycidae). – Czestochowa Entomological Circle Bulletin, No.12, pp.6-11.
  • [33] Geisler T. (2016): Structure, functions and observations of behavior of elytra and wings of selected species of beetles (Coleoptera). – Czestochowa Entomological Circle Bulletin, No.14, pp.3-13.
  • [34] Geisler T. and Topczewska S. (2015): Analysis of the wing mechanism movement parameters of selected beetle species (Coleoptera). – International Journal of Applied Mechanics and Engineering, vol.20, No.1, pp.53-64.
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  • [38] Miller S. (1996): Theory of mechanisms and machines - analysis of physical systems. – Wrocław: Technical University of Wrocław.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-2367f792-a2e9-446a-847d-e3c8bac2dd2d
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