Transient analysis of rotating functionally graded truncated conical shells based on the Lord

Transient analysis of rotating functionally graded truncated conical shells based on the Lord–Shulman model

Heydarpour, Y. / Aghdam, M.M.

Abstract The generalized coupled thermoelasticity based on the Lord–Shulman (L-S) theory is employed to study the transient thermoelastic behavior of rotating functionally graded (FG) truncated conical shells subjected to thermal shock with different boundary conditions. Material properties are assumed to be graded in the thickness direction, which it can vary according to a simple power law distribution. The governing equations together with related boundary conditions are discretized using a mapping-differential quadrature method (DQM) and Newmark time integration scheme in the spatial and temporal domains, respectively. The formulation and method of the solution are validated by showing their fast rate of convergence and comparison with available data in the open literature. Then, the effects of the material graded index, the angular velocity, semi-vertex angle together with other geometrical parameters on the thermal behavior of the rotating FG truncated conical shells under thermal shock, including temperature change, displacement and stress components are investigated.

Highlights • Transient response of rotating FG conical shells under thermal shock is studied. • The L-S theory for generalized coupled thermoelasticity is considered. • Rapid change of temperature has a significant effect on response of the shell. • Results may be used as benchmark due to practical importance of the problem.