Study of Acoustic Barriers with an Cylindrical Top Edge for Reducing the Noise of Power Equipment

IF 0.9 Q4 ENERGY & FUELS Thermal Engineering Pub Date : 2024-09-26 DOI:10.1134/S0040601524700290
V. B. Tupov, A. B. Mukhametov
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Abstract

Acoustic barriers are used to reduce the noise of power equipment. To increase their efficiency, an cylindrical top edge is installed, which is an add-on on the top edge of the barrier. To study the acoustic properties of the cylindrical top edge, a mathematical model of a 3-m high barrier was built in the COMSOL Multiphysics program. The mathematical model of the barrier without an cylindrical top edge was verified using the Kurze calculation method. The acoustic characteristics of a superstructure in the form of an cylindrical top edge have been studied. It has been determined that the acoustic efficiency of the cylindrical top edge depends both on the position relative to the upper edge of the barrier and on the distance from the noise source to the barrier. The calculation results show that the greatest changes in sound pressure levels when installing an cylindrical top edge are observed at high frequencies, and the minimum at low frequencies. The acoustic efficiency of the cylindrical top edge at geometric mean frequencies corresponding to low frequencies is approximately 1–2 dB and it can reach up to 25 dB at geometric mean frequencies corresponding to high frequencies. The acoustic characteristics of an cylindrical top edge with different installation angles have been studied. It has been shown that the cylindrical top edge with an installation angle of 0° has the highest acoustic efficiency (8–10 dBA) at a distance from the noise source to the barrier of up to 2 m. At distances from 2 to 5 m, the highest acoustic efficiency (4–8 dBA) is observed when using an antidiffraction device with an installation angle of 90°. Using an cylindrical top edge with an installation angle 180° is advisable when the barrier is located next to the design point at a distance from the barrier to it of less than 5 m. When installing an antidiffraction device, a significantly greater acoustic effect is achieved than when increasing the height of the barrier. The results obtained during the research are recommended to be taken into account when implementing noise reduction measures when choosing the location of an acoustic barrier with an cylindrical top edge relative to the noise source and the design point.

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用于降低电力设备噪音的圆柱形顶边隔声屏障研究
隔声屏障用于降低电力设备的噪音。为了提高隔声屏障的效率,在隔声屏障的顶部边缘安装了一个圆柱形顶边。为了研究圆柱形顶缘的声学特性,我们在 COMSOL Multiphysics 程序中建立了一个 3 米高隔声屏障的数学模型。使用 Kurze 计算方法验证了不带圆柱形顶边的屏障数学模型。对圆柱形顶边上部结构的声学特性进行了研究。研究结果表明,圆柱形上边缘的声学效率取决于与护栏上边缘的相对位置以及噪声源到护栏的距离。计算结果表明,安装圆柱形顶边时,高频声压级的变化最大,低频声压级的变化最小。在低频对应的几何平均频率下,圆柱形顶边的声学效率约为 1-2 dB,而在高频对应的几何平均频率下,声学效率可达 25 dB。对不同安装角度的圆柱形顶边的声学特性进行了研究。结果表明,安装角度为 0° 的圆柱形顶缘在噪声源到屏障的距离为 2 米时具有最高的声学效率(8-10 分贝),而在距离为 2 至 5 米时,使用安装角度为 90° 的防衍射装置则具有最高的声学效率(4-8 分贝)。当隔离栅位于设计点旁边,且隔离栅与设计点的距离小于 5 米时,建议使用安装角为 180° 的圆柱形顶边。建议在实施降噪措施时,在选择顶部边缘为圆柱形的隔声屏障与噪声源和设计点的相对位置时,考虑研究得出的结果。
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来源期刊
CiteScore
1.30
自引率
20.00%
发文量
94
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