Low-frequency sound insulation of honeycomb membrane-type acoustic metamaterials with different interlayer characteristics

The membrane-type structure that can achieve excellent sound insulation characteristics under lightweight conditions is widely concerned, but it generally involves a small mass block attached to a thin membrane. Although this kind of design can obtain better acoustic insulation performance, the mass block will cause installation and manufacturing issues in industrial applications. This paper presents a multilayer honeycomb membrane-type acoustic metamaterial with an interlayer structure. Similar to the mass block, the interlayer structure makes less sound energy transmitted by varying the eigenmode characteristics of the membrane. Considering the integrated design of the interlayer structure, the issues of installation and manufacturing are solved and the sound transmission loss is enhanced on the fixed overall dimension and small additional mass. The results indicate that the design of interlayer structures can break the bottleneck of ultrathin and lightweight requirements. Meanwhile, the symmetry of interlayer position can lead to the shift in transmission loss valley to a higher frequency, achieving high sound insulation in a wide frequency range.

Automated summary

This paper presents a multilayer honeycomb membrane-type acoustic metamaterial with an interlayer structure, which can effectively reduce sound energy transmission by varying the eigenmode characteristics of the membrane. The design of interlayer structures can break the bottleneck of ultrathin and lightweight requirements and achieve high sound insulation in a wide frequency range by shifting the transmission loss valley to a higher frequency.