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Critical voltage, thermal buckling and frequency characteristics of a thermally affected GPL reinforced composite microdisk covered with piezoelectric actuator

    1. [1] Ton Duc Thang University

      Ton Duc Thang University

      Vietnam

    2. [2] Islamic Azad University

      Islamic Azad University

      Irán

    3. [3] Tarbiat Modares University

      Tarbiat Modares University

      Irán

    4. [4] Sharif University of Technology

      Sharif University of Technology

      Irán

    5. [5] Jeju National University

      Jeju National University

      Corea del Sur

    6. [6] Velayat University
  • Localización: Mechanics based design of structures and machines, ISSN 1539-7734, Vol. 50, Nº. 4, 2022, págs. 1331-1353
  • Idioma: inglés
  • Texto completo no disponible (Saber más ...)
  • Resumen
    • Due to the remarkable progress in the field of the manufacturing process, smart composites have become the desired target for high-tech engineering applications. Accordingly, for the first time, thermal buckling, critical voltage and vibration response of a thermally affected graphene nanoplatelet reinforced composite (GPLRC) microdisk in the thermal environment are explored with the aid of generalized differential quadrature method (GDQM). Also, the current microstructure is coupled with a piezoelectric actuator (PIAC). The extended form of Halpin-Tsai micromechanics is used to acquire the elasticity of the structure, whereas, the variation of thermal expansion, Poisson’s ratio, and density through the thickness direction is determined by the rule of mixtures. Hamilton’s principle is implemented to establish governing equations and boundary conditions of the GPLRC microdisk joint with a PIAC. The compatibility conditions are satisfied by taking perfect bonding between the core and PIAC into consideration.

      Maxwell’s equation is employed to capture the piezoelectricity effects. The numerical results revealed the important role of distribution patterns and weight fraction of GPL (gGPL), non-dimensional piezoelectric thickness (hp/ h), outer to the inner ratio of the radius (Ro=Ri) and applied voltage on the frequency behavior, critical voltage and thermal buckling of the system.

      Another valuable consequence is that the influence of the hp parameter is hardly dependent on the value of the temperature changes (DT). The favorable suggestion of this survey is that for optimized designing of the GPLRC microsized circular plate should pay special attention to pattern 3 of the GPLs, because in this pattern by increasing the gGPL parameter the critical voltage of the structure increases but for other patterns of GPL, this phenomenon is inverse.


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