Multi-scale material/structure integrated elastic metamaterial for broadband vibration absorbing
Xingzhong Wang, Chao Zhang, Shiteng Rui, Chengjun Wu, Weiquan Zhang, Fuyin Ma
Abstract
To break the high additional mass ratio requirement of traditional vibration absorbing materials/devices, and overcome the shortcoming of the narrow operating frequency band of conventional local resonance metamaterial dampers, this paper proposes a lightweight multi-scale material/structure integrated elastic metamaterial for broadband vibration absorption. By replacing the mass components in the macroscopic metamaterial vibration absorber with a composite mass body filled with microscopic particle materials, a multi-scale structure/material integrated design between the macroscopic oscillator and microscopic particle is realized. The macroscopic oscillator absorbs low-frequency vibration, while the microscopic particle cluster absorbs medium–high frequency vibration, thereby achieving a broadband vibration absorption covering the low-medium–high ranges. Based on the band gap theory and the multiphase flow theory of gas-particle, this paper systematically analyzes the band gap effect of multi-scale metamaterials and the dissipation capacity of medium–high frequency caused by particle damping. The structure exhibits commendable vibration damping performance. The multi-scale integrated vibration damper retains the lightweight and sub-wavelength characteristics of the traditional local resonance unit cells, while greatly broadening the working bandwidth, and having potential applications in low-frequency broadband vibration reduction of various mechanical equipment.