Abstract
Nonlinear dynamics of a rotating flexible slender beam with embedded active elements is studied in the paper. Mathematical model of the structure considers possible moderate oscillations thus the motion is governed by the extended Euler–Bernoulli model that incorporates a nonlinear curvature and coupled transversal–longitudinal deformations. The Hamilton’s principle of least action is applied to derive a system of nonlinear coupled partial differential equations (PDEs) of motion. The embedded active elements are used to control or reduce beam oscillations for various dynamical conditions and rotational speed range. The control inputs generated by active elements are represented in boundary conditions as non-homogenous terms. Classical linear proportional (P) control and nonlinear cubic (C) control as well as mixed (P-C) control strategies with time delay are analyzed for vibration reduction. Dynamics of the complete system with time delay is determined analytically solving directly the PDEs by the multiple timescale method. Natural and forced vibrations around the first and the second mode resonances demonstrating hardening and softening phenomena are studied. An impact of time delay linear and nonlinear control methods on vibration reduction for different angular speeds is presented.
Highlights
Slender beam-like elements play an important role in engineering and structural design
Nonlinear vibrations and time delay control practicing engineers and scholars to extensively study the methods of oscillations suppression and to improve structural positioning accuracy
The model studied in this paper considers an active structure with embedded piezo-layers and a boundary control method with time delay
Summary
Slender beam-like elements play an important role in engineering and structural design. Nonlinear vibrations and time delay control practicing engineers and scholars to extensively study the methods of oscillations suppression and to improve structural positioning accuracy. To mitigate vibrations the proportional and time derivative potential feedback control was formulated It was shown by tuning the control parameters and gains the nonlinear dynamic behavior of the structure could be actively suppressed. Liu et al [29] studied the piezoelectric based optimal delayed feedback control method when applied to large amplitude nonlinear vibrations of a beam. The discussed above new results obtained for nonlinear stationary beams, followed by the observed interactions between transversal and longitudinal vibrations and the dichotomy of softening and hardening response behavior as well as the potential of feedback control methods motivated authors of the present contribution to a more detailed study of the problem under discussion. “Appendix” contains listing of adopted shape functions of the first- and second-order perturbation solution
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