Acoustic response of bi-directional functionally graded beam under axially varying load

Q3 Physics and Astronomy

Noise and Vibration Worldwide Pub Date : 2023-09-26 DOI:10.1177/09574565231203258

Somi Naidu Balireddy, Jeyaraj Pitchaimani, Lenin Babu Mailan Chinnapandi

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Abstract

This paper investigates the effects of bi-directional gradation, length-to-height ratio, and end conditions on the acoustic behaviour of bi-directionally varying functional graded beams. The acoustic responses, including sound-power level (dB), sound-pressure level (dB), and sound-radiation efficiency, are evaluated using Rayleigh’s integral and modal superposition method. The sound power levels are presented up to the selected bandwidth, as well as the octave band center frequency. In contrast, the sound pressure levels are presented as contour plots and in directivity pattern. The buckling load, calculated for quadratically decreasing axial load, is applied in increments from 0 to its highest value. The study reveals that the highest value in the gradation indexes in both directions significantly influences the sound power levels. It is also evident from the study that thin beams have higher sound power levels compared to thick beams. The directivity pattern reveals that bi-directional functionally graded beams predict higher sound pressure levels at the critical buckling load. From the current acoustic study, it is observed that both structural and end stiffness are influential factors in sound power levels (dB) and sound pressure levels (dB).

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轴向载荷作用下双向功能梯度梁的声响应

本文研究了双向梯度、长高比和端部条件对双向变化功能梯度梁声学特性的影响。采用瑞利积分和模态叠加法对声功率级、声压级和声辐射效率等声学响应进行了评价。声功率级显示到所选带宽，以及倍频带中心频率。相反，声压级以等高线图和指向性图表示。屈曲载荷，计算为二次减少轴向载荷，施加从0到其最大值的增量。研究表明，两个方向的级配指标的最大值对声功率级有显著影响。研究还表明，细光束比粗光束具有更高的声功率级。指向性图表明，双向功能梯度梁在临界屈曲载荷下预测更高的声压级。从目前的声学研究中可以看出，结构刚度和端部刚度都是影响声功率级和声压级的因素。

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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来源期刊

Noise and Vibration Worldwide Physics and Astronomy-Acoustics and Ultrasonics

CiteScore

1.90

自引率

0.00%

发文量

期刊介绍： Noise & Vibration Worldwide (NVWW) is the WORLD"S LEADING MAGAZINE on all aspects of the cause, effect, measurement, acceptable levels and methods of control of noise and vibration, keeping you up-to-date on all the latest developments and applications in noise and vibration control.