Thermo-elastic vibration analysis and optimization of a nanoresonator composed of a coupled nanotube system for acoustic liner application using the hybrid deep neural network–based white shark algorithm

IF 2.3 3区工程技术 Q2 ACOUSTICS

Journal of Vibration and Control Pub Date : 2024-08-31 DOI:10.1177/10775463241272934

TJ Prasanna Kumar, K Sivajibabu, B Durga Prasad

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Abstract

This study explores the potential of nanoresonator systems composed of coupled nanotubes with graphene nanoparticles for enhancing the performance of acoustic liners in aircraft engines. The objective of this study is to develop an analytical model and predict its behavior under various conditions. The acoustic liners consist of perforated metal sheets and honeycomb cavities, which are essential for noise reduction in aircraft engines. The model is tested for variations in natural frequency, mode number (m), size effects (e0a), viscous constant (C), temperature (T), localness factor (L), and stiffness constant (K). A hybrid deep neural network–based white shark algorithm (DNN-WSA) is used to predict and optimize the performance of nanoresonator-coupled nanotube systems. Four theories were compared, such as wave propagation theory, nonlocal elasticity theory, polynomial eigenvalue approach, and governing equations with respect to natural frequencies in nanoresonator-coupled nanotube systems. The wave propagation theory yielded the lowest natural frequency, which was selected for detailed analysis. The optimized values of size effect of 2 nm, temperature of 5 K, and frequency of 1.971975 THz were obtained. When C = 0.3, K = 10, T = 300, and L = 10×e−9, the root mean square error (RMSE) value is 0.8421, which indicates improved predictive performance as it continues to decrease. The study’s findings showed that changes in viscous constants impact natural frequencies, while size effects have a minor influence. Temperature variations also affect natural frequencies, with higher temperatures leading to higher frequencies. The optimized model demonstrates enhanced predictive performance, which contributes to a better understanding of nanoresonator systems and their application in noise reduction for aircraft engines.

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利用基于混合深度神经网络的白鲨算法，对由耦合纳米管系统组成的纳米声纳进行热弹性振动分析和优化，用于声衬垫应用

本研究探讨了由耦合纳米管和石墨烯纳米颗粒组成的纳米声纳系统在提高飞机发动机声衬性能方面的潜力。本研究的目的是建立一个分析模型，并预测其在各种条件下的行为。隔音衬垫由穿孔金属板和蜂窝空腔组成，对飞机发动机降噪至关重要。该模型针对固有频率、模态数 (m)、尺寸效应 (e0a)、粘性常数 (C)、温度 (T)、局部系数 (L) 和刚度常数 (K) 的变化进行了测试。基于深度神经网络的混合白鲨算法（DNN-WSA）用于预测和优化纳米谐振器耦合纳米管系统的性能。比较了四种理论，如波传播理论、非局部弹性理论、多项式特征值方法以及纳米谐振器耦合纳米管系统固有频率的治理方程。波传播理论得出了最低的固有频率，因此被选中进行详细分析。得到了尺寸效应为 2 nm、温度为 5 K、频率为 1.971975 THz 的优化值。当 C = 0.3、K = 10、T = 300 和 L = 10×e-9 时，均方根误差（RMSE）值为 0.8421，这表明随着均方根误差的不断减小，预测性能得到了改善。研究结果表明，粘性常数的变化会影响固有频率，而尺寸效应的影响较小。温度变化也会影响固有频率，温度越高，频率越高。优化后的模型显示出更强的预测性能，有助于更好地了解纳米谐振器系统及其在飞机发动机降噪中的应用。

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来源期刊

Journal of Vibration and Control 工程技术-工程：机械

CiteScore

5.20

自引率

17.90%

发文量

336

审稿时长

6 months

期刊介绍： The Journal of Vibration and Control is a peer-reviewed journal of analytical, computational and experimental studies of vibration phenomena and their control. The scope encompasses all linear and nonlinear vibration phenomena and covers topics such as: vibration and control of structures and machinery, signal analysis, aeroelasticity, neural networks, structural control and acoustics, noise and noise control, waves in solids and fluids and shock waves.