Abstract
Piezoelectric energy harvesters can transform the mechanical strain into electrical energy. The microelectromechanical transformation device is often composed of piezoelectric cantilevers and has been largely experimented. Most resonances have been developed to harvest nonlinear vibratory energy except for combination resonances. This paper is to analyze several secondary resonances of a cantilever-type piezoelectric energy harvester with a tip magnet. The conventional Galerkin method is improved to truncate the continuous model, an integro-partial differential equation with time-dependent boundary conditions. Then, more resonances on higher-order vibration modes can be obtained. The stable steady-state response is formulated approximately but analytically for the first two subharmonic and combination resonances. The instability boundaries are discussed for these secondary resonances from quadratic nonlinearity. A small damping and a large excitation readily result in an unstable response, including the period-doubling and quasiperiodic motions that can be employed to enhance the voltage output around a wider band of working frequency. Runge–Kutta method is employed to numerically compute the time history for stable and unstable motions. The stable steady-state responses from two different methods agree well with each other. The outcome enriches structural dynamic theory on nonlinear vibration.
Highlights
Applying pressure to piezoelectric materials causes them to produce an electric charge.The piezoelectric material would contract or expand in an electric field
The task of our work is to develop secondary resonances to harvest more mechanical energy around a wider range of working frequencies
The effects of damping and excitation on secondary resonances from quadratic nonlinearity are discussed in detail
Summary
Applying pressure to piezoelectric materials causes them to produce an electric charge. Magnetic nonlinearity is often employed to improve cantilevered piezoelectric energy harvester [11,12] This field encompasses mechanics, material science, and electrical circuitry, and has captivated both academics and industrialists. The efforts have been made on them as well as two subharmonic resonances for an electromechanical system with quadratic nonlinearity in this article It has experimental value and theoretical significance to investigate a cantilever-type piezoelectric energy harvester with tip magnets [21,22]. The effects of damping and excitation on secondary resonances from quadratic nonlinearity are discussed in detail Their stability theories are analytically proposed to better design the physical parameters of the piezoelectric cantilever.
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