Origami-based metamaterial with switchable abnormal expansion function

The coefficient of thermal expansion (CTE) is an important parameter for the thermophysical properties of materials. Mostly, in aerospace engineering, satellites, hypersonic vehicles, precision instruments and microelectronic packages, numerous thermal deformation structures in severe environment full of drastic temperature changes are required to be controlled precisely. Therefore, the development of adjustable thermal expansion materials is of significance in engineering applications. Based on the Miura-ori structure, this paper adopts materials with respectively diverse CTEs as components to generate thermal stresses mismatch principle and proposes a design method for origami metamaterials with adjustable in situ positive/negative/zero expansion functions. Employing the methods of finite element calculation and deformation analysis, the deformation results of this metamaterial are displayed and discussed. Also, an origami metamaterial with adjustable positive/negative/zero expansion function can be obtained by adjusting the material distribution of the structure. Moreover, the mapping relationship between the folding angle and the geometric parameter of the structure is established. In the light of this design method of tunable CTE metamaterials, additionally, the metamaterial can achieve precise control of thermal deformation and optimize service reliability in extreme environments.

Automated summary

This paper presents a design method for adjustable coefficient of thermal expansion metamaterials based on the Miura-ori structure. By using materials with diverse CTEs as components, it achieves precise control of thermal deformation structures in severe environments. The metamaterials can optimize service reliability by adjusting the material distribution and folding angles.