Jieun Yang scite author profile

The purpose of this work is to check if additive manufacturing technologies are suitable for reproducing porous samples designed for sound absorption. The work is an inter-laboratory test, in which the production of samples and their acoustic measurements are carried out independently by different laboratories, sharing only the same geometry codes describing agreed periodic cellular designs. Different additive manufacturing technologies and equipment are used to make samples. Although most of the results obtained from measurements performed on samples with the same cellular design are very close, it is shown that some discrepancies are due to shape and surface imperfections, or microporosity, induced by the manufacturing process. The proposed periodic cellular designs can be easily reproduced and are suitable for further benchmarking of additive manufacturing techniques for rapid prototyping of acoustic materials and metamaterials.

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Multiple slow waves in metaporous layers for broadband sound absorption

Yang

Lee

Kim

2016

J. Phys. D: Appl. Phys.

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Metaporous layer to overcome the thickness constraint for broadband sound absorption

Yang

Lee

Kim

2015

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The sound absorption of a porous layer is affected by its thickness, especially in a low-frequency range. If a hard-backed porous layer contains periodical arrangements of rigid partitions that are coordinated parallel and perpendicular to the direction of incoming sound waves, the lower bound of the effective sound absorption can be lowered much more and the overall absorption performance enhanced. The consequence of rigid partitioning in a porous layer is to make the first thickness resonance mode in the layer appear at much lower frequencies compared to that in the original homogeneous porous layer with the same thickness. Moreover, appropriate partitioning yields multiple thickness resonances with higher absorption peaks through impedance matching. The physics of the partitioned porous layer, or the metaporous layer, is theoretically investigated in this study. V C 2015 AIP Publishing LLC. [http://dx.

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Slow-wave metamaterial open panels for efficient reduction of low-frequency sound transmission

Yang

Lee

et al. 2018

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Sound transmission reduction is typically governed by the mass law, requiring thicker panels to handle lower frequencies. When open holes must be inserted in panels for heat transfer, ventilation, or other purposes, the efficient reduction of sound transmission through holey panels becomes difficult, especially in the low-frequency ranges. Here, we propose slow-wave metamaterial open panels that can dramatically lower the working frequencies of sound transmission loss. Global resonances originating from slow waves realized by multiply inserted, elaborately designed subwavelength rigid partitions between two thin holey plates contribute to sound transmission reductions at lower frequencies. Owing to the dispersive characteristics of the present metamaterial panels, local resonances that trap sound in the partitions also occur at higher frequencies, exhibiting negative effective bulk moduli and zero effective velocities. As a result, low-frequency broadened sound transmission reduction is realized efficiently in the present metamaterial panels. The theoretical model of the proposed metamaterial open panels is derived using an effective medium approach and verified by numerical and experimental investigations.

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Frequency-dependent transmission boundary condition in the acoustic time-domain nodal discontinuous Galerkin model

2020

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Jieun Yang

Reproducibility of sound-absorbing periodic porous materials using additive manufacturing technologies: Round robin study

Multiple slow waves in metaporous layers for broadband sound absorption

Metaporous layer to overcome the thickness constraint for broadband sound absorption

Slow-wave metamaterial open panels for efficient reduction of low-frequency sound transmission

Frequency-dependent transmission boundary condition in the acoustic time-domain nodal discontinuous Galerkin model

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