Enhancement of the sound absorption of closed-cell mineral foams by perforations: Manufacturing process and model-supported adaptation (2408.14933v1)

Abstract: Thin low-frequency acoustic absorbers that are economical to produce in large quantities are scarce, and their efficiency is often limited to a narrow frequency range. In this paper, we present opportunities to use highly porous mineral foams, in particular optimally designed gypsum foams, to achieve high absorption levels for layers of less than 1/10 of a wavelength thick. To reach this goal, we perforate a fraction of the initially closed pores using thin needles. Finite element simulations of the fluid flow in a representative volume element show how the combination of foam properties (cell size and wall thickness) and perforation pattern (hole diameter and perforation distance) can be chosen such that sub-wavelength absorption is obtained. In particular two transport parameters used in the approximate but robust Johnson-Champoux-Allard model for porous media have to be optimized: the flow resistivity and high-frequency tortuosity. The fluid flow modeling results are successfully compared with sound absorption measurements, showing indeed that the proposed material, once appropriately perforated, yields a remarkable low-frequency sound absorption peak. On a more fundamental level, this paper shows how the multiporosity, the presence of microcracks, and the material's surface roughness can be exploited to enhance its acoustic absorption at very low frequencies.