Abstract
This paper focuses on size effects in periodic mechanical metamaterials driven by reversible pattern transformations due to local elastic buckling instabilities in their microstructure. Two distinct loading cases are studied: compression and bending, in which the material exhibits pattern transformation in the whole structure or only partially. The ratio between the height of the specimen and the size of a unit cell is defined as the scale ratio. A family of shifted microstructures, corresponding to all possible arrangements of the microstructure relative to the external boundary, is considered in order to determine the ensemble averaged solution computed for each scale ratio. In the compression case, the top and the bottom edges of the specimens are fully constrained, which introduces boundary layers with restricted pattern transformation. In the bending case, the top and bottom edges are free boundaries resulting in compliant boundary layers, whereas additional size effects emerge from imposed strain gradient. For comparison, the classical homogenization solution is computed and shown to match well with the ensemble averaged numerical solution only for very large scale ratios. For smaller scale ratios, where a size effect dominates, the classical homogenization no longer applies.
Highlights
Over the past decade, cellular materials have found widespread use in thermal, mechanical, and acoustic applications
This value ensures that specimens of all scale ratios of interest, 4 ≤ L/` ≤ 128, are subjected to pattern transformations without deforming in a higher mode
The deformed shapes and corresponding stress–strain curves for the two cases are shown in Fig. 4 for the scale ratio L/` = 5 and zero vertical shifts
Summary
Cellular materials have found widespread use in thermal, mechanical, and acoustic applications. Their mechanical response is largely influenced by the geometry at the scale of the microstructure. This has inspired researchers to design microstructures which exhibit anomalous behavior (see Florijn et al, 2014). Architectured cellular materials consisting of periodically arranged circular holes in an elastomer base material exhibit a pattern transformation, which is triggered when the applied ∗. (b) deformed compressive load reaches a critical value.
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