Abstract
Transient responses of stiffened panels with piezoelectric sensors and actuators are studied under normal blast loads. The air vehicles could be exposed to blast pulses generated by an explosion or shock-wave disturbances. Thus, active vibration suppression of the vehicles is important under blast loadings. The structural model is designed as a laminated composite panel with lead zirconate titanate (PZT) piezoceramic layers embedded on both top and bottom surfaces. A uniformly distributed blast load is assumed over the whole of the panel surface. The first-order shear deformation theory of plate is adopted, and the extended Hamilton’s principle is applied to derive the equations of motions. The numerical model is verified by the comparison with previous data. Using linear quadratic regulator (LQR) control algorithm, vibration characteristics and dynamic responses are compared. As piezoelectric patches are attached on the whole of the surface, the effect of the stiffener’s location is studied. Furthermore, the influences of the patch’s positions are also investigated through subjection to the blast wave. From various results, in order to get the best control performances, the research aims to find the optimum position of sensor and actuator pairs that is most effective under blast load environments.
Highlights
The research relevant to the piezoelectric materials to control the vibration of structures is actively reported in the literature
This paper presents vibration suppression control of a stiffened model with piezoelectric sensors
This paperunder presents vibration suppression control of be a stiffened with piezoelectric sensors and actuators blast loads
Summary
The research relevant to the piezoelectric materials to control the vibration of structures is actively reported in the literature. Direct piezoelectric effect means that the materials generate an electric charge while the model is subjected to a mechanical deformation. Reddy [1] investigated theoretical formulations and finite element models using the shear deformation plate theories. They analyzed the laminated plates with sensors and actuators under mechanical and electrical loads. Active vibration suppression of piezoelectric stiffened laminated panels subjected to normal blast waves is studied in this paper. Due to the characteristics of piezoelectric materials as fast responders, the vibration behaviors of stiffened composite panels could be controlled by piezoelectric actuators under a blast loading. Numerical results for vibration suppression of stiffened panels under blast load are discussed in detail. These studies could be applied to various types of structures
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