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Abstract
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A layer-wise finite element approach is adopted to analyse the hollow cylindrical shell made of functionally graded material
with piezoelectric rings as sensor/actuator, under dynamic load. The mechanical properties of the substrate are regulated
by volume fraction as a function of radial coordinate. The thickness of functionally graded material shell and piezorings
is divided into mathematical sub-layers and then the general layer-wise laminate theory is formulated through introducing
piecewise continuous approximations across the thickness, accounting for any discontinuity in derivatives of the
displacement at the interface between the ring and cylinder. The virtual work statement including structural and electrical
potential energies yields the three-dimensional governing equations which are reduced to two-dimensional differential
equations, using layer-wise method. For axisymmetric case, the resulted equations are solved with one-dimensional
finite element method in the axial direction. By assembling stiffness and mass matrices, the required stress and displacement
continuities at each interface and between the two adjacent elements are forced. The results for free vibration and
static loading are applied to study the convergence and verified by comparing them to solutions of similar existing problems.
The induced deformation by piezoelectric actuators as well as the effect of rings on functionally graded material
shell is investigated.
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