Low Frequency Absorption of Additively Manufactured Cylinders

Volume 11: Acoustics, Vibration, and Phononics Pub Date : 2019-11-11 DOI:10.1115/imece2019-11338

Sophie R. Kaye, Ethan D. Casavant, Paul E. Slaboch

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引用次数: 1

Abstract

Attenuating low frequencies is often problematic, due to the large space required for common absorptive materials to mitigate such noise. However, natural hollow reeds are known to effectively attenuate low frequencies while occupying relatively little space compared to traditional absorptive materials. This paper discusses the effect of varied outer diameter, and outer spacing on the 200–1600 Hz acoustic absorption of additively manufactured arrays of hollow cylinders. Samples were tested in a 10 cm diameter normal incidence impedance tube such that cylinder length was oriented perpendicular to the incoming plane wave. By varying only one geometric element of each array, the absorption due to any particular parameter can be assessed individually. The tests confirmed the hypothesis that minimizing cylinder spacing and maximizing cylinder diameter resulted in increased overall absorption and produced more focused absorption peaks at specific low frequencies. Wider cylinder spacing produced a broader absorptive frequency range, despite shifting upward in frequency. Thus, manipulating these variables can specifically target absorption for low frequency noise that would otherwise disturb listeners.

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增材制造汽缸的低频吸收

低频衰减通常是有问题的，因为普通吸收材料需要很大的空间来减轻这种噪声。然而，与传统的吸收材料相比，天然中空芦苇可以有效地衰减低频，同时占用相对较少的空间。本文讨论了不同外径和外距对增材制造空心圆柱阵列200 ~ 1600 Hz吸声性能的影响。样品在直径为10厘米的法向阻抗管中进行测试，使圆柱体长度垂直于入射平面波。通过仅改变每个阵列的一个几何元素，可以单独评估任何特定参数引起的吸收。测试证实了最小化圆柱间距和最大化圆柱直径可以增加整体吸收，并在特定低频产生更集中的吸收峰的假设。更宽的圆柱间距产生更宽的吸收频率范围，尽管频率向上移动。因此，操纵这些变量可以专门针对低频噪声的吸收，否则会干扰听众。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 11: Acoustics, Vibration, and Phononics

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