Mr. Mingkai Zhang Profile

Mingkai Zhang

at Beijing Institute of Technology

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Proceedings Article | 22 March 2021 Presentation

Study of topological interface state in chiral tensegrity metastructures

Mingkai Zhang, Yitian Wang, Guoliang Huang, Rui Zhu

Proceedings Volume 11593, 1159320 (2021) https://doi.org/10.1117/12.2584198

KEYWORDS: Interfaces

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In this research, we study the topological effect in both 1D and 2D metastructures consisting of chiral-shape prismatic tensegrity units. The unique axial-torsional motion introduces coupled local resonance which produces the needed Dirac degeneracy for the topological states at low frequency. A multi-resonantor design is also proposed for additional Dirac cones which can be opened for mutiple non-trivial bandgaps. Further research shows that topological phase transition can be also achieved through the adjustment of chirality. Finally, prestress control on the topological interface states is studied in both 1D and 2D cases.

Proceedings Article | 1 April 2019 Presentation + Paper

Flexural wave control via origami-based elastic metamaterials

Mingkai Zhang, Jinkyu Yang, Rui Zhu

Proceedings Volume 10972, 109720Q (2019) https://doi.org/10.1117/12.2514179

KEYWORDS: Metamaterials, Wave propagation, Bistability, Adaptive control

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The overall mechanical properties of an origami can be programed by its pattern of crease, which introduces various interesting mechanical properties, such as tunable stiffness, multistability and coupled deformations. Once obtaining the knowledge about the properties of the side plates, the creases and the folding procedure, the mechanical response of origami can be completely determined. Therefore, origami with highly designable and tunable abilities offers new possibilities for the metamaterial design. In this research, we aim to combine origami with elastic metamaterials. By introducing the tunable twisting origami structure into the subwavelength-scale resonator design, a three-dimensional elastic metamaterial with low-frequency dynamic performance has been proposed, which, at the same time, has the advantages of lightweight and controllablility. The geometrical nonlinearity of the origami building block is first studied, which indicates that the large structural deformation can be harnessed to tune the effective stiffness of the origami. Further research discovers the quantitative relationship between the overall stiffness and each geometric parameter through the potential energy analysis. Then, the designed origami cell is used as an attachable resonator to control the flexural wave propagation in a metamaterial beam. Finally, both static and dynamic experiments are conducted on the origami cell and the metamaterial beam to verify the tunable stiffness and the on-demand bandgaps, respectively.

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