Your search keyword '"Dai, Fuhong"' showing total 3 results

1. Integrated a nonlinear energy sink and a piezoelectric energy harvester using simply-supported bi-stable piezoelectric composite laminate.

Author

Li, Ming, Yu, Dong, Li, Yanqi, Liu, Xiaohui, and Dai, Fuhong

Subjects

*ENERGY harvesting, *VIBRATION absorption, *LAMINATED materials, *ENERGY consumption, *HARMONIC oscillators, *POWER density, *PIEZOELECTRIC composites

Abstract

A nonlinear device is presented for simultaneous vibration absorption and energy harvesting. This device is composed of a nonlinear energy sink and a piezoelectric energy harvester (NES-EH), and its core component is the simply-supported bi-stable piezoelectric composite laminate (BPCL). Its outstanding advantages are light weight, simple and reliable structure. The theoretical model is developed to model a harmonically excited linear oscillator coupled with NES-EH. The Runge–Kutta method and the harmonic balance method (HBM) are used to solve the theoretical model numerically and analytically. The vibration suppression efficiency is utilized to quantify the vibration absorption performance, while the energy harvesting performance is assessed by bandwidth for energy harvesting and maximum voltage within the bandwidth. The effects of the excitation amplitude, the concentrated mass of NES-EH, the length and width of BPCL, and the load resistance are considered on the performances of NES-EH. The vibration absorption and energy harvesting performances of NES-EH can be improved by adjusting these parameters. In addition, the proposed NES-EH can achieve the goal of higher power density and normalized power density under low-amplitude excitation and simultaneously have a good vibration absorption effect. Finally, approximate analytical solutions are obtained by using HBM to exhibit various bifurcations and singularities. • Simply-supported bi-stable piezoelectric composite is first used to integrate vibration absorption and energy harvesting. • NES-EH has advantages of light weight, simple and reliable structure dueto no high strength frame or external device. • Mathematical modeling is developed to forecast the performances of NES-EH. • The effects of excitation amplitude, concentrated mass of NES-EH, geometries of BPCL, and load resistance are considered. [ABSTRACT FROM AUTHOR]

Published

2023

2. A bi-stable device for simultaneous vibration absorption and energy harvesting using bi-stable piezoelectric composite laminate.

Author

Li, Ming, Yu, Dong, Li, Yanqi, Liu, Xiaohui, and Dai, Fuhong

Subjects

*ENERGY harvesting, *VIBRATION absorption, *BISTABLE devices, *LAMINATED materials, *ENERGY consumption, *HARMONIC oscillators, *PIEZOELECTRIC composites

Abstract

A bi-stable device is presented for simultaneous vibration absorption and energy harvesting by introducing the piezoelectric element into the bi-stable nonlinear energy sink (BNES), which is called the bi-stable piezoelectric absorber (BPZA). BPZA only consists of the cantilever bi-stable piezoelectric composite laminate (BPCL) and tip masses. This BPZA is a lightweight, simple and reliable structure since it does not need any external devices to maintain bistability. A finite element model (FEM) and an equivalent theoretical model are developed to model a harmonically excited linear oscillator coupled with BPZA. The Runge-Kutta method is used to solve the theoretical model numerically. The effects of the excitation amplitude, the tip mass of BPZA and the load resistance are considered on the vibration suppression efficiency and energy harvesting of BPZA. The results show adjusting these parameters can improve the vibration suppression efficiency and energy harvesting of BPZA. In addition, the experimental prototype is prepared and verifies the rightness of the finite element model and theoretical model. The BPZA achieves the goal of higher power density at lower acceleration and simultaneously has a good vibration absorption effect. Maximum power of 15.8mW is generated at an excitation frequency of 22 Hz and acceleration of 0.5 g. [ABSTRACT FROM AUTHOR]

Published

2023

3. A bi-stable nonlinear energy sink using the cantilever bi-stable hybrid symmetric laminate.

Author

Li, Ming, Li, Yanqi, Liu, Xiaohui, and Dai, Fuhong

Subjects

*FINITE element method, *PERIODIC motion, *HARMONIC oscillators, *ENERGY consumption, *CANTILEVERS, *NONLINEAR oscillators

Abstract

This paper develops a new bi-stable nonlinear energy sink (BNES) only consisting of the cantilever bi-stable hybrid symmetric laminate (BHSL) and tip masses. This BNES has advantages of light weight, simple and reliable structure, since it does not need external devices or magnets to maintain its bi-stable characteristic. A finite element model (FEM) is developed to perform static and dynamic analyses of a harmonically excited linear oscillator coupled with BNES. An equivalent theoretical model is developed to model the coupled system based on the relationship between the restoring force and the displacement of BHSL. The Runge-Kutta method is used to perform direct numerical solutions. Different types of the steady-state response for BNES contain the local and global periodic motions, the local and global strongly modulated responses and chaos, while the primary object exhibits the periodic motion and the strongly modulated response. The effects of the excitation amplitude, the tip mass of BNES, the lay-up design and the length of BHSL are considered on the dynamic responses and vibration suppression efficiency of BNES. The results show adjusting these parameters and lay-up designs can improve the vibration suppression efficiency of BNES. In addition, the experimental prototype is prepared and verifies the rightness of the finite element model and theoretical model. [ABSTRACT FROM AUTHOR]

Published

2023