Reduced integration schemes in micromorphic computational homogenization of elastomeric mechanical metamaterials

TL;DR

This paper develops and tests reduced-order integration schemes within a micromorphic computational homogenization framework to efficiently model the complex behavior of elastomeric mechanical metamaterials, maintaining accuracy while reducing computational cost.

Contribution

It introduces a one-point integration quadrilateral element with stabilization for micromorphic homogenization, improving efficiency without sacrificing accuracy.

Findings

Reduced integration maintains accuracy in benchmark tests.

The proposed scheme enhances computational efficiency.

Stability of reduced-order elements is successfully demonstrated.

Abstract

Exotic behaviour of mechanical metamaterials often relies on an internal transformation of the underlying microstructure triggered by its local instabilities, rearrangements, and rotations. Depending on the presence and magnitude of such a transformation, effective properties of a metamaterial may change significantly. To capture this phenomenon accurately and efficiently, homogenization schemes are required that reflect microstructural as well as macro-structural instabilities, large deformations, and non-local effects. To this end, a micromorphic computational homogenization scheme has recently been developed, which employs the particular microstructural transformation as a non-local mechanism, magnitude of which is governed by an additional coupled partial differential equation. Upon discretizing the resulting problem it turns out that the macroscopic stiffness matrix requires integration of macro-element basis functions as well as their derivatives, thus calling for a higher-order integration rules. Because evaluation of constitutive law in multiscale schemes involves an expensive solution of a non-linear boundary value problem, computational efficiency can be improved by reducing the number of integration points. Therefore, the goal of this paper is to investigate reduced-order schemes in computational homogenization, with emphasis on the stability of the resulting elements. In particular, arguments for lowering the order of integration from the expensive mass-matrix to a cheaper stiffness-matrix equivalent are first outlined. An efficient one-point integration quadrilateral element is then introduced and proper hourglass stabilization discussed. Performance of the resulting set of elements is finally tested on a benchmark bending example, showing that we achieve accuracy comparable to the full quadrature rules.