November 22, 2024
Seyed Ehsan Habibi

Seyed Ehsan Habibi

Academic Rank: Assistant professor
Address: -
Degree: Ph.D in -
Phone: -
Faculty: Faculty of Engineering

Research

Title
Thermoelastic analysis of FG-GPLRC truncated conical shells under thermo-mechanical loading based on Lord-shulman Theory
Type Thesis
Keywords
ترمو الاستيك، پوسته مخروطي ناقص، مواد مدرج تابعي تقويتشده با پلاكتهاي گرافني، بارگذاري ترمو – مكانيكي ، تئوري لورد - شولمن
Researchers bahram rezaei (Student) , Yasin Heydarpour (Primary advisor) , Seyed Ehsan Habibi (Primary advisor) , Parviz Malekzadeh (Advisor)

Abstract

In this thesis, thermoelastic analysis of FG-GPLRC truncated conical shells under thermo-mechanical shock loading based on Lord-Shulman theory is investigated. Due to layer-by-layer changes in material properties, multilayered truncated conical shells have been decomposed into a set of coaxial nanocomposite shells. temperature distribution, displacement components, mechanical and thermal stresses have been investigared. in The first step, governing equations and related boundary conditions and compatibility, which include the effects of thermal and mechanical stresses, have been derived using the Lord-Shulman energy balance equations and the equations of motion. Then, in order to discretize the governing equations and related boundary conditions and compatibility, the efficient and accurate differential quadrature method in the space dimension and the Newmark method in the time dimension have been used. The effective elastic properties of the shell have been obtained using the modified Halpin-Tsai micromechanical model. the rule of mixtures has been used to obtain other material properties. Except one things (investigation of classical boundary condition), clamped boundary conditions are considered on the lower and upper surfaces. The rapid validation of this method for the thermoelastic analysis of FGGPLRC truncated conical shells has been numerically demonstrated. At the end of the study, the effect of different patterns of graphene platelet distribution and aspect ratio, as well as the effect of geometry parameters on the thermo-elastic response of the shell is investigated. Also It was shown that the addition of a small amount of graphene platelets in the polymer field significantly increases the heat wave speed and reduce the radial displacements.