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Finite Element Analysis of the local effect of a piezoelectric patch on an aluminum plate

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
We have been accustomed to traditional materials such as wood, leather, wool... and have known the revolution of plastics and composites materials. Recently, we have known other innovations: these of smart materials able to change the shape as the piezoelectric materials. This work deals with the electro-mechanical modeling of these structures by the finite element method. It consists on to model and to simulate deformations in a square aluminum plate subjected to an electric field. This is achieved by using PZT piezoelectric transducers that have such particularity to deform under the influence of an electric field. The study of the deformed aluminum plates equipped with a PZT patch is considered and these types of materials are commonly used in aeronautics and astronautics, which is the context of our study. We have clearly shown the effect of the electromechanical properties of different piezoelectric materials, the transverse piezoelectric coefficient d31 and the longitudinal piezoelectric coefficient d33 of PZT patch on the final response of the intelligent structure.
Rocznik
Strony
233--242
Opis fizyczny
Bibliogr. 18 poz., il. kolor., rys., wykr.
Twórcy
autor
  • Laboratory of Transportation Engineering and Environment, Faculty of Technology Sciences, Mentouri-Constantine University, 25000 Constantine, Algeria
autor
  • Laboratory of Mechanics, Faculty of Technology Sciences, Mentouri-Constantine University, 25000 Constantine, Algeria
autor
  • Applied Mechanics Department, FEMTO-ST Institute/ENSMM, 25030 Besançon, France
Bibliografia
  • [1] Cheng, J. and Li, G.: Stress analyses of a smart composite pipe joint integrated with piezoelectric composite layers under torsion loading, International Journal of Solids and Structures, 45 1153-1178, 2008.
  • [2] Huang, Y., Deng, Z. and Xiong, Y.: High-order model and slide mode control for rotating flexible smart structure, Mechanism and Machine Theory, 826-839, 2007.
  • [3] Kalamkarov, A. L., Saha, G. C. and Georgiades, A. V.: General micromechanical modeling of smart composite shells with application to smart honeycomb sandwich structures, Composite Structures, 79, 18-33, 2007.
  • [4] Güey, M. and Eşkinat, E.: Optimal actuator and sensor placement in flexible structures using closed-loop criteria, Journal of Sound and Vibration 312, 210-233, 2008.
  • [5] Shameli, E., Alasty, A. and Salaarieh, H.: Stability analysis and nonlinear control of a miniature shape memory alloy actuator for precise applications, Mechatronics, 15, 471-486, 2005.
  • [6] Davidson, R.: Smart composites - fact or fiction?, 5th European conference on composite materials, 3-11, 1992.
  • [7] Thomas, O., Nicu, L., Ayela, C. and Touz e, C.: Flambage et vibrations non-lineaires d'une plaque stratifiee piezoelectrique. Application à un bio-capteur MEMS, 8eme Colloque national en calcul de structure, Giens, 2007.
  • [8] Dorf, R. C.: Modern Control Systems. 3thd edition, Addison-Wesley Publishing Company , 1980.
  • [9] Tiersten, H. F.: Hamilton's principle for linear piezoelectric media, Proceedings Letters of the IEEE Journal, 1523-1524, 1967.
  • [10] Yu, Y. Y.: Vibration of Elastic Plate: Linear and Nonlinear Dynamical Modeling of Sandwiches, Laminated Composites, and Piezoelectric Layers, Springer-Verlag, 1996.
  • [11] Liang, J.: Non-local theory solution of two collinear modeI cracks in piezoelectric materials, Applied Mathematical Modelling, 32, 1126-1142, 2008.
  • [12] Sosa, H. and Khutoryansky, N.: Transient dynamic response of piezoelectric bodies subjected to internal electric impulses, Int. J. Solids Struct., 36, (??), 5467-5484, 1999.
  • [13] Soh, A. K., Fang, D. N. and Lee, K. L. : Analysis of a bi-piezoelectric ceramic layer with an interfacial crack subjected to anti-plane shear and in-plane electric loading, Eur. J. Mech. A Solid 19 (??) (2000) 961-977.
  • [14] Balamurugan, V. and Narayanan, S.: Shell finite element for smart piezoelectric composite plate/shell structures and its application to the study of active vibration control, Finite Element in Analysis and Design, 37, 713-738, 2001.
  • [15] Zallo, A. and Gaudenzi, P.: Finite element models for laminated shells with actuation capability, Computers & Structures, 81, 1059-1069, 2003.
  • [16] Benjeddou, A.: Advances in piezoelectric finite element modeling of adaptative structural elements: a survey, Computers & Structures, 76, 347-363, 2000.
  • [17] Leleu, S., Abou-Kandil, H. and Bonnassieux, Y.: Vibration control by slinding modes for a clamped plate with piezoelectric actuator and sensor, ECC, 438-443, 2001.
  • [18] Leleu, S., Abou-Kandil, H. and Bonnassieux, Y.: Piezoelectric actuators and sensors location for active control of flexible structures, Proceedings of IEEE Instrumentation and Measurement Technology Conference, 819-824, 2000.
Uwagi
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-7b6a6248-6cbd-4992-8c4a-10ed5aed667b
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