Origami of Multi-Layered Spaced Sheets

TL;DR

This paper introduces a novel framework for designing multi-layered spaced origami structures that enable the creation of 3D assemblies with separated flat sheets, useful for engineering applications like acoustic cloaks and heat shields.

Contribution

It develops a new design and analysis method for spaced origami with sparse sheet connectivity, expanding the functional possibilities of origami-based structures.

Findings

Multiple folding paths depend on linkage orientation.

Maximized packing ratio achieved in flat foldable configurations.

Potential applications include deployable acoustic cloaks and heat shields.

Abstract

Two-dimensional (2D) origami tessellations such as the Miura-ori are often generalized to build three-dimensional (3D) architected materials with sandwich or cellular structures. However, such 3D blocks are densely packed with continuity of the internal material, while for many engineering structures with multi-physical functionality, it is necessary to have thin sheets that are separately spaced and sparsely connected. This work presents a framework for the design and analysis of multi-layered spaced origami, which provides an origami solution for 3D structures where multiple flat sheets are intentionally spaced apart. We connect Miura-ori sheets with sparsely installed thin-sheet parallelogram-like linkages. To explore how this connectivity approach affects the behavior of the origami system, we model the rigid-folding kinematics using analytic trigonometry and rigid-body transformations, and we characterize the elastic-folding mechanics by generalizing a reduced order bar and hinge model for these 3D assemblies. The orientation of the linkages in the multi-layered spaced origami determines which of three folding paths the system will follow including a flat foldable type, a self-locking type, and a double-branch type. When the origami is flat foldable, a maximized packing ratio and a uniform in-plane shear stiffness can be achieved by strategically choosing the link orientation. We show possible applications by demonstrating how the multi-layered spaced origami can be used to build deployable acoustic cloaks and heat shields.