The Vibration Isolation Design of a Re-Entrant Negative Poisson's Ratio Metamaterial

An improved re-entrant negative Poisson's ratio metamaterial based on a combination of 3D printing and machining is proposed. The improved metamaterial exhibits a superior load-carrying and vibration isolation capacity compared to its traditional counterpart. The bandgap of the proposed metamaterial can be easily tailored through various assemblies. Additionally, particle damping is introduced to enhance the diversity of bandgap design, improve structural damping performance, and achieve better vibration isolation at low and medium frequencies. An experiment and simulation were conducted to assess the static and vibration performances of the metamaterial, and consistent results were obtained. The results indicate a 300% increase in the bearing capacity of the novel structure compared to traditional structural metamaterials. Furthermore, by increasing the density of metal assemblies, a vibration-suppressing bandgap with a lower frequency and wider bandwidth can be achieved. The introduction of particle damping significantly enhanced the vibration suppression capability of the metamaterial in the middle- and low-frequency range, effectively suppressing resonance peaks. This paper establishes a vibration design method for re-entrant metamaterials, which is experimentally validated and provides a foundation for the vibration suppression design of metamaterials.

Automated summary

An improved re-entrant negative Poisson's ratio metamaterial combining 3D printing and machining is proposed, which exhibits superior load-carrying and vibration isolation capacity compared to traditional materials. The bandgap of the metamaterial can be easily adjusted through different assemblies, and particle damping enhances the diversity of bandgap design and improves structural damping performance. Experimental and simulation results demonstrate a 300% increase in bearing capacity compared to traditional metamaterials, and increasing the density of metal assemblies achieves a vibration-suppressing bandgap with a lower frequency and wider bandwidth.