Analysis of the wing mechanism movement parameters of selected beetle species (Coleoptera)

• Autorzy: Geisler T. , Topczewska S.

Identyfikatory

DOI

10.1515/ijame-2015-0004

• Języki publikacji: EN

Abstrakty

EN

This study presents a structural and functional analysis of the wing bending and folding mechanism of a selected beetle species. Insect motility studies, with regard to the anatomical structure, were performed. The main inner wing structures were highlighted and their mechanical properties and functions were determined. The structure parameters as mechanisms bodies that allow wings of various beetle species to bend and fold were defined.

Słowa kluczowe

EN

bionic; wing; movement parameters; folding

PL

chrząszcz; skrzydło owada; parametry ruchu

• Wydawca: Oficyna Wydawnicza Uniwersytetu Zielonogórskiego
• Czasopismo: International Journal of Applied Mechanics and Engineering
• Rocznik: 2015
• Tom: Vol. 20, no. 1
• Strony: 53--64
• Opis fizyczny: Bibliogr. 36 poz., rys., tab., wykr.

Twórcy

autor

Geisler T.

• Institute of Mechanics and Fundamentals of Machinery Design The Faculty of Mechanical Engineering and Computer Science University of Technology, Czestochowa ul. Dąbrowskiego 73, 42–200 Częstochowa, POLAND

autor

Topczewska S.

• Institute of Mechanics and Fundamentals of Machinery Design The Faculty of Mechanical Engineering and Computer Science University of Technology, Czestochowa ul. Dąbrowskiego 73, 42–200 Częstochowa, POLAND

Bibliografia

• [1] Artobolewski J.J. (1988): Theory of mechanisms and machines. (in Polish) – Moskwa.
• [2] Bethoux O. (2005): Wing venation pattern of Plecoptera (Insecta: Neoptera). – Illisia, vol.1, No.9, pp.52-81.
• [3] 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.
• [4] Czekałowski P. (2009): Investigation of the Entomopter’s wings movement kinematics on its performance - the general concept of research. (in Polish) – Modelling in Engineering, vol.37, pp.71-76.
• [5] Czekałowski P. and Sibilski K. (2012): Influence of cruise flight speed of entomopter on aerodynamics loads. (In Polish) – Modelling in Engineering, vol.45. No.14, pp.206-212.
• [6] Dudley R. (1999): The Biomechanics of Insect Flight: Form, Function, Evolution. – New Jersey: Princeston University Press.
• [7] Felis J., Jaworowski H. and Cieślik J. (2008): Analysis of Mechanisms. (in Polish) – T.1, Wyd.2, AGH University of Science and Technology Press, Kraków.
• [8] 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.
• [9] Frantsevich L. (2011): Mechanisms Modeling the Double Rotation of the Elytra in Beetles (Coleoptera). – Journal of Bionic Engineering, vol.8, pp.395–405.
• [10] Frantsevich L. (2012): Double rotation of the opening (closing) elytra in beetles (Coleoptera). – Journal of Insect Physiology, vol.58, pp.24-34.
• [11] Frantsevich L. (2012): Indirect closing of elytra by the prothorax in beetles (Coleoptera): general observations and exceptions. – Zoology, vol.115, pp.12-21.
• [12] Geisler T. (2011): Construction and wing folding of selected families of beetles (Coloptera). (in Polish) – Bulletin of Entomological Czestochowa Interest Group, No.10, 11/2011, pp.12-21, Częstochowa.
• [13] Geisler T. (2012): l 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.
• [14] Geisler T. (2014): Wing functionality observation of the selected beetle species (Coleoptera: Scarabaeidae, Cerambycidae). (in Polish) – Bulletin of Entomological Czestochowa Interest Group, No.12, 01/2014, pp.6-11, Częstochowa.
• [15] Geisler T., Rosikoń P., Sochacki W. and Topczewska S. (2014): Functional and Structural Analysis of Wing Folding Mechanism Based on Cockchafer (Melolontha melolontha). – Acta Mechanica et Automatica, vol.8, No.3, pp.129-135.
• [16] Gronowicz A., Miller S. and Twaróg W. (2000): Theory of mechanisms and machines, set of analysis and design problems. – P. Wr., Wrocław.
• [17] Ha N.S., Truong. Q.T., Goo N.S. and Park H.C. (2013): Biomechanical properties of insect wings: the stress stiffening effects on the asymmetric bending of the allomyrina dichotoma beetle's hind wing. – PLoS ONE, vol.8, No.12.
• [18] Hamilton A.K.G. (1971): The insect wing, Part I. Origin and development of wings from notal lobes. – Kansas Entomological Society, vol.44, No.4, pp.421-433.
• [19] Haas F., Gorb S. and Blickhan R. (2000): The function of resilin in beetle wings. – Proceedings of the Royal Society B: Biological Sciences, July 22, 267 (1451), pp.1375-1381.
• [20] 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.
• [21] Haas F. (2006): Evidence from folding and functional lines of wings on inter-ordinal relationships in Pterygota. – Arthropod Systematics Phylogeny, vol.64, No.2, pp.149–158.
• [22] Jaroszewicz A. (2009): Modeling and simulation of entomopter’s flight dynamics. – Modelling in Engineering, vol.38, pp.77-85, Gliwice.
• [23] Jin T., Goo N.S. and Park H.C. (2010): Finite element modeling of a beetle wing. – Journal of Bionic Engineering, 7 Suppl., pp.S145-S149.
• [24] Miller S. (1996): Theory of mechanisms and machines - analysis of physical systems. (in Polish) – Technical University of Wrocław.
• [25] Mallesh P.D. (2012): Large displacement flexible micro actuators. – Journal of Mechanical and Civil Engineering, vol.2, No.3, pp.14-23.
• [26] 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.
• [27] 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.77-89.
• [28] 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.594-S102.
• [29] Pławilszczikow N. (1968): Keys for Identifying Insects. (in Polish) – Warsaw: PWRiL.
• [30] Razowski J. (1987): Dictionary of Entomology. (in Polish) – Warsaw: PWN.
• [31] Razowski J. (1996): Dictionary of Insect Morphology. – PWN, Warsaw-Krakow. (in Polish).
• [32] Sitorus P.E., Park H.C., Byun D., Goo N.S. and Han C.H. (2010): The role of elytra in beetle flight: I. Generation of quasi-static aerodynamic forces. – Journal of Bionic Engineering, 7 Suppl., pp.354-363.
• [33] Stebnicka A. (1978): Keys for identifying polish insects. (in Polish) – Nr 100, Cz. XIX, Zeszyt 28b, Chrząszcze-Coloptera, PWN, Warsaw.
• [34] 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.
• [35] Szwanwicz B. (1956): General Entomology. (in Polish) – Warsaw: PWRiL.
• [36] Wootton R.J. (1997): Function, homology and terminology in insect wings. – Systematic Entomology, vol.4, pp.81-93.