Vibration Suppression Performance of FRP Spherical-Cylindrical Shells with Porous Graphene Platelet Coating in a Thermal Environment

In this study, the vibration suppression effect of a fiber reinforced polymer (FRP) spherical-cylindrical shell coated with the porous graphene platelet (PGP) in a thermal environment is investigated. The dynamic equilibrium equation is derived by combining the first-order shear deformation theory and the Rayleigh-Ritz approach, together with the virtual spring technology and the multi-segment partition technique. After the free and forced vibration responses of this FRP combined shell with PGP coating are solved. The model is validated by the convergence analysis and comparison of the present results and literature or finite element results for different shell structures with and without coating under various boundary conditions. Using the present model, the parametric study is conducted to explore the effects of porosity distribution type, dispersion pattern of volume fraction porosity, nanofiller weight fraction, and thickness ratio of PGP coating on the transient response. This study provides a useful model and some suggestions for better improving the vibration suppression capability of coated shell structures in a thermal environment.

Automated summary

The vibration suppression effect of a FRP spherical-cylindrical shell coated with PGP in a thermal environment is investigated in this study. A dynamic equilibrium equation is derived and the model is validated. Parametric study is conducted to explore the effects on the transient response. This study provides a useful model and suggestions to improve the vibration suppression capability of coated shell structures in a thermal environment.