Generalized micropolar continualization of 1D beam lattices

TL;DR

This paper introduces an enhanced homogenization method for 1D beam lattices that accurately models boundary layer effects and dynamic spectra using micropolar continuum models, improving upon traditional homogenization techniques.

Contribution

It develops a novel continualization approach transforming discrete beam lattice equations into higher-order, energetically consistent micropolar continuum models capable of capturing complex behaviors.

Findings

Accurately simulates boundary layer effects in beam lattices.

Represents the Floquet-Bloch spectrum effectively.

Provides static and dynamic response predictions matching discrete models.

Abstract

The enhanced continualization approach proposed in this paper is aimed to overcome some drawbacks observed in the homogenization of beam lattices. To this end an enhanced homogenization technique is proposed and formulated to obtain consistent micropolar continuum models of the beam lattices and able to simulate with good approximation the boundary layer effects and the Floquet-Bloch spectrum of the Lagrangian model. The continualization technique here proposed is based on a transformation of the difference equation of motion of the discrete system via a proper down-scaling law into a pseudo-differential problem; a further McLaurin approximation is applied to obtain a higher order differential problem. The formulation is carried out for simple one-dimensional beam lattices that are, nevertheless, characterized by a rather wide variety of static and dynamic behaviors: the rod lattice, the beam lattice with node rotations and a 1D beam lattice model with generalized displacements. Higher order models may be obtained which are characterized by differential problems involving non-local inertia terms together with spatial high gradient terms. Moreover, the homogenized models obtained by the proposed enhanced continualization technique turn out to be energetically consistent and provide a good simulation of both the static response and of the acoustic spectrum of the original discrete models. The proposed homogenization procedure is first presented for the simple case of monoatomic axial chains. The beam lattice with node rotations and displacement prevented exhibits, in the static regime, decaying oscillations of the nodal rotation in the boundary layer which is well simulated by the homogenized model obtained by the proposed approach.