Micropolar dissipative models for the analysis of 2D dispersive waves in periodic lattices
详细信息 查看全文
- 作者:H. Redaa ; b ; J.F. Ganghoffera ; jean-francois.Ganghoffer@univ-lorraine.fr ; H. Lakissb
- 关键词:Dissipative periodic lattices ; Dispersion relations ; Auxetic material ; Homogenization methods ; Damping ratio ; Phase velocity ; Floquet-Bloch analysis ; Metamaterial
- 刊名:Journal of Sound and Vibration
- 出版年:2017
- 出版时间:31 March 2017
- 年:2017
- 卷:392
- 期:Complete
- 页码:325-345
- 全文大小:3035 K
- 卷排序:392
文摘
The computation of the dispersion relations for dissipative periodic lattices having the attributes of metamaterials is an actual research topic raising the interest of researchers in the field of acoustics and wave propagation phenomena. We analyze in this contribution the impact of wave damping on the dispersion features of periodic lattices, which are modeled as beam-lattices. The band diagram structure and damping ratio are computed for different repetitive lattices, based on the homogenized continuum response of the initially discrete lattice architecture, modeled as Kelvin-Voigt viscoelastic beams. Three of these lattices (reentrant hexagonal, chiral diamond, hexachiral lattice) are auxetic metamaterials, since they show negative Poisson's ratio. The effective viscoelastic anisotropic continuum behavior of the lattices is first computed in terms of the homogenized stiffness and viscosity matrices, based on the discrete homogenization technique. The dynamical equations of motion are obtained for an equivalent homogenized micropolar continuum evaluated based on the homogenized properties, and the dispersion relation and damping ratio are obtained by inserting an harmonic plane waves Ansatz into these equations. The comparison of the acoustic properties obtained in the low frequency range for the four considered lattices shows that auxetic lattices attenuate waves at lower frequencies compared to the classical hexagonal lattice. The diamond chiral lattice shows the best attenuation properties of harmonic waves over the entire Brillouin zone, and the hexachiral lattice presents better acoustic properties than the reentrant hexagonal lattice. The range of validity of the effective continuum obtained by the discrete homogenization has been assessed by comparing the frequency band structure of this continuum with that obtained by a Floquet-Bloch analysis.