This thesis presents the first-known exact solutions for vibration of stepped circular Mindlin plates. The considered circular plate is of several step-wise variation in thickness in the radial direction. The Mindlin first order shear deformable plate theory is employed to derive the governing differential equations for the annular and circular segments. The exact solutions to these differential equations may be expressed in terms of the Bessel functions of the first and second kinds and the modified Bessel functions of the first and second kinds. The governing homogenous system of equations is assembled by implementing the essential and natural boundary conditions and the segment interface conditions. Vibration solutions are presented for circular Mindlin plates of different edge support conditions and various combinations of step-wise thickness variations. These exact vibration results may serve as important benchmark values for researchers to validate their numerical methods for such circular plate problems
Date of Award | 2002 |
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Original language | English |
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- Mindlin
- vibration
- formulation
- plate theory
- coordinates
- frequency
- segment
- equation
- Bessel
Exact solution for vibration of stepped circular Mindlin plates
Zhang, L. (Author). 2002
Western Sydney University thesis: Master's thesis