3D打印吸音器:紧凑且可在宽带频率下定制

F. Setaki, F. Tian, Michela Turrin, M. Tenpierik, L. Nijs, A. van Timmeren
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引用次数: 3

摘要

本文讨论了一种新颖、紧凑的吸声解决方案,通过有效使用计算设计和增材制造(AM),在包括低频在内的各种频率下都具有高性能。吸声被广泛应用于降低噪声和改善房间声学;然而,它经常受到传统设计、材料特性和生产技术的限制,这些因素为定制性能提供了有限的选择。这项研究强调,AM与计算设计工具相结合,可以支持基于粘热波在棱柱管中传播原理的高性能新型吸声产品的开发。通过对定制吸声板的两项研究,探索了这些设计的潜力,这些吸声板的性能是在混响室中测量的。使用了一种基于对数扫描和高分辨率FFT分析的自定义测量技术。测量结果与粘热波传播理论的比较表明,测量结果符合良好;因此,本研究展示了开发新型房间声学设备的新概念和设计方法的可能性。
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3D-printed sound absorbers: compact and customisable at broadband frequencies

This paper discusses a novel, compact sound absorption solution with high performance at various frequencies, including low frequencies, achieved through the effective use of Computational Design and Additive Manufacturing (AM). Sound absorption is widely applied for reducing noise and improving room acoustics; however, it is often constrained by conventional design, material properties and production techniques, which offer limited options for customising performance. This research highlights that AM, in combination with computational design tools, can support the development of novel sound-absorbing products with high performance based on the principle of viscothermal wave propagation in prismatic tubes. The potential of these designs was explored via two studies of customised sound-absorbing panels whose performance was measured in a reverberation room. A custom measurement technique was used based on logarithmic sweeps with high-resolution FFT analysis. A comparison of the measurement results with the theory of viscothermal wave propagation indicated good agreement; thus, this study demonstrates the possibility of developing new concepts and design methods for novel room acoustic devices.

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