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Vibration analysis of a sandwich cylindrical shell in hygrothermal environment

Authors
  • Zhang, Chunwei1
  • Jin, Qiao2
  • Song, Yansheng2
  • Wang, Jingli2
  • Sun, Li2
  • Liu, Haicheng2
  • Dun, Limin3
  • Tai, He3
  • Yuan, Xiaodong4
  • Xiao, Hongmei1
  • Zhu, Limeng1
  • Guo, Songlin1
  • 1 School of Civil Engineering, Structural Vibration Control Group, Qingdao University of Technology, China , (China)
  • 2 School of Civil Engineering, Shenyang Jianzhu University, China , (China)
  • 3 Shenyang Geotechnical Investigation & Surveying Research Institute Co., Ltd, China , (China)
  • 4 CSCEC Capital Holding, China State Construction Engineering Group Co., Ltd, China , (China)
Type
Published Article
Journal
Nanotechnology Reviews
Publisher
De Gruyter
Publication Date
Jun 03, 2021
Volume
10
Issue
1
Pages
414–430
Identifiers
DOI: 10.1515/ntrev-2021-0026
Source
De Gruyter
Keywords
Disciplines
  • Research Article
License
Green

Abstract

The sandwich structures are three- or multilayered structures such that their mechanical properties are better than each single layer. In the current research, a three-layered cylindrical shell including a functionally graded porous core and two reinforced nanocomposite face sheets resting on the Pasternak foundation is used as model to provide a comprehensive understanding of vibrational behavior of such structures. The core is made of limestone, while the epoxy is utilized as the top and bottom layers’ matrix phase and also it is reinforced by the graphene nanoplatelets (GNPs). The pattern of the GNPs dispersion and the pores distribution play a crucial role at the continuous change of the layers’ properties. The sinusoidal shear deformation shells theory and the Hamilton’s principle are employed to derive the equations of motion for the mentioned cylindrical sandwich shell. Ultimately, the impacts of the model’s geometry, foundation moduli, mode number, and deviatory radius on the vibrational behavior are investigated and discussed. It is revealed that the natural frequency and rotation angle of the sandwich shell are directly related. Moreover, mid-radius to thickness ratio enhancement results in the natural frequency reduction. The results of this study can be helpful for the future investigations in such a broad context. Furthermore, for the pipe factories current study can be effective at their designing procedure.

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