On the vibrations of a high-speed rotating multi-hybrid nanocomposite reinforced cantilevered microdisk

M.S.H. Al Furjan; Seyedeh Yasaman Bolandi; Lijun Shan; Mostafa Habibi; Dong won Jung

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On the vibrations of a high-speed rotating multi-hybrid nanocomposite reinforced cantilevered microdisk

M. S. H. Al-Furjan ^[4] ; Seyedeh Yasaman Bolandi ^[1] ; Lijun Shan ^[4] ; Mostafa Habibi ^[2] ; Dong won Jung ^[3]
1. [1] Ferdowsi University of Mashhad
  
  Ferdowsi University of Mashhad
  
  Irán
2. [2] Duy Tan University
  
  Duy Tan University
  
  Vietnam
3. [3] Jeju National University
  
  Jeju National University
  
  Corea del Sur
4. [4] Hangzhou Dianzi University
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Localización: Mechanics based design of structures and machines, ISSN 1539-7734, Vol. 50, Nº. 12, 2022, págs. 4157-4185
Idioma: inglés
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Resumen
- In this study, the vibrational characteristics of a rotating multi-hybrid nanocomposite reinforced (MHCR) cantilevered disk (MHCRCD) are presented.
  
  The centrifugal and Coriolis effects due to the rotation are considered. The strains and stresses can be determined via the high-order shear deformable theory (HSDT). For access to various mass densities, as well as the Poisson ratio, the rule of the mixture is applied, although a modified Halpin-Tsai theory is used for obtaining the module of elasticity. The boundary conditions and governing equations are obtained using Hamilton’s principle and finally are solved via generalized differential quadrature method (GDQM). Vibration characteristics of the rotating MHCRCD with various boundary conditions are described according to the curves drawn by Matlab software. Also, the simply supported conditions are applied to edges h ¼ p=2, and h ¼ 3p=2, also, cantilever (clamped–free) boundary conditions are investigated in R¼Ri, and R0, respectively. Apart from the numerical solution, a 3-D finite element model using ABAQUS software was presented using the finite element package to simulate the response of the rotating MHCRCD. The results created from a finite element simulation illustrates a close agreement with the semi-numerical method results. The outcomes show that the fibers’ angel, angular velocity speed, and various patterns of carbon nanotube (CNT) have a considerable impact on the amplitude, and vibration behavior of a rotating MHCRCD. As an applicable result in related industries, the rotating speed effect on the real part of frequency is more effective in the higher values of the radius ratio.