材料科学
吸收(声学)
微尺度化学
声学
激光器
降噪系数
衰减系数
融合
复合材料
压缩(物理)
声能
光电子学
能量(信号处理)
金属
聚变能
亥姆霍兹自由能
机械工程
磁场
声波
领域(数学)
工程物理
光学
电磁辐射
复合数
金属粉末
作者
Zhicheng Wei,Y ZHAO,Shixiang Zhou,F F Lei,Weilin Liu,Wentao Yan,Jun Ding
出处
期刊:3D printing and additive manufacturing
[Mary Ann Liebert, Inc.]
日期:2026-06-26
标识
DOI:10.1177/23297662261458117
摘要
Noise-induced hearing loss often results in a characteristic notch within the 3–6 kHz frequency range, which is crucial for speech intelligibility. However, traditionally fabricated metallic sound-absorbing structures designed for harsh environments frequently suffer from issues such as large structural dimensions, low manufacturing precision, and inadequate programmability and repeatability. In this study, we developed a microscale resonator-similar structure incorporating a Helmholtz resonator, which was fabricated utilizing laser powder bed fusion technique for applications in harsh environments. These structures not only demonstrate a pronounced sound absorption peak around 3022 Hz, achieving a coefficient of 0.92, but also maintain an impressive average sound absorption coefficient of 0.69 within the critical 3–6 kHz range. Compression tests indicate that the specific energy absorption of these resonator-similar structures reaches 45.8 J/g, demonstrating a significant advantage in energy absorption capabilities, providing dual protection against mechanical stress and noise. This research seeks to explore the application of metal AM technologies in the field of sound absorption, contributing to the development of lightweight and effective metallic sound-absorbing structural components suitable for industry, vehicles, and military fields.
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