In this study, a commercially available foam injection-molding machine was enhanced with a mold opening technique to produce polypropylene open-cell acoustic foams. Gas counter-pressure was used to
improve the cell morphology and uniformity of the injection-molded foams. Their structure and thickness were controlled by applying different degrees of mold opening. The sample structure, the cell morphology, and the acoustic behavior of the foams were characterized. A foamed structure with an open-cell
content of 67% and an expansion ratio of 4.6 was obtained when the mold was opened by 4.5 mm.
Although further opening of the mold did not significantly increase the open-cell content, it triggered
crack creation in the middle of the foams, where the creation of cavities was also facilitated. The injection-molded foams with a cavity and a high open-cell content, presented remarkable acoustic properties:
a peak absorption coefficient of 0.95 was observed for foam with a 73% open-cell content and a 9 mm
cavity. An automated system was also developed to perforate the acoustic foams, and the acoustic properties of foams both with and without perforation were studied. While perforating the foams widened
their absorption coefficient frequency spectrum, it did not improve their transmission loss.