Band Gaps and Transmission Characteristics Analysis on a Two-Dimensional Multiple-Scatter Phononic Crystal Structure

Xiang, Hang; Ma, Xingfu; Xiang, Jiawei

doi:10.3390/ma13092106

Cited by 9 publications

(5 citation statements)

References 30 publications

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“…However, the experimental method needs to spend a lot of manpower, material resources, and time to make it, and it is difficult to guarantee the accuracy of the experiment results. Fortunately, the finite element method is an effective and efficient calculation method of band gaps and vibration attenuation properties, the numerical calculation of finite array periodic structures by finite element method has been widely used to demonstrate the effectiveness of the band gaps calculation methods of periodic structures in the scholars’ research [ 47 , 48 , 49 , 50 ]. Thus, to validate the existence of the flexural wave vibration band gaps of the infinite long periodic oscillator coupled damping beam and study the vibration attenuation performance in the frequency ranges of band gaps, we investigated the band gaps and vibration attenuation characteristics by using the finite element method.…”

Section: Resultsmentioning

confidence: 99%

Band Gaps Characteristics Analysis of Periodic Oscillator Coupled Damping Beam

Tang

Yao

et al. 2020

Materials

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The vibration of the periodic oscillator coupled damping beam model is reduced through the band gaps designing method, which can be applied in equivalent engineering structures. In this paper, the flexural wave dispersion relations of the infinite long periodic oscillator coupled damping beam were calculated using the reverberation-ray matrix method combined with the Bloch theorem. The flexural wave vibration frequency response function of the finite long periodic oscillator coupled damping beam was carried out using the finite element method. The flexural wave vibration band gaps occur in the infinite long periodic oscillator coupled damping beam model in both the analytical and numerical results. In these band gaps, flexural waves’ propagation is prohibited, and flexural vibration is significantly suppressed. Furthermore, the effects of structure and material parameters on the flexural wave vibration band gaps characteristics are studied. Thus, the structural vibration reduction design can be realized by adjusting the related parameters of the periodic coupled damping beam structures and the equivalent 2D periodic stiffened plate structures.

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Section: Resultsmentioning

confidence: 99%

Band Gaps Characteristics Analysis of Periodic Oscillator Coupled Damping Beam

Tang

Yao

et al. 2020

Materials

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“…To verify the effectiveness of the flexural wave band gaps characteristics calculation method obtained in this paper and demonstrate the existences of the flexural wave band gaps and vibration attenuation characteristics in the proposed periodic beam-oscillators coupling system, a structural dynamic characteristic analysis of a finite long homogeneous beam coupled with periodic oscillators with 12 unit cells based on finite element method is conducted in this section. The flexural wave band gaps and vibration attenuation characteristics of various periodic structures had been analyzed by the numerical calculation of the finite array periodic structures, the numerical calculation method is an effective and efficient calculation method of band gaps and vibration attenuation characteristics and has been widely used to demonstrate the effectiveness of the band gaps calculation methods (Waki et al, 2009;Zhou et al, 2015;Nobrega et al, 2016;Xiang et al, 2020). As shown in Figure 3A, the finite array finite element model with 12 unit cells of the proposed periodic beam-oscillators coupling system is established in Abaqus CAE at the beginning of the numerical calculation, the finite element model is constituted of a homogeneous beam with a rectangular section and coupled with 12 periodic oscillators in parallel connection, which the separation distance is 1.0 m and each unit cell contains 400 beam elements, the vibration direction of the periodic oscillators is vertical direction and the length direction of the homogeneous beam is along X-axis with 12.0 m dimensions.…”

Section: Numerical Calculation Validation Based On Finite Element Met...mentioning

confidence: 99%

Band Gaps and Vibration Attenuation Characteristics Analysis in Homogeneous Beam Coupled With Periodic Oscillators Based on the Method of Reverberation-Ray Matrix

Tang

Yao

et al. 2022

Front. Mater.

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A periodic beam-oscillators coupling system is proposed as a physical model in this paper for analyzing the dynamic characteristics of periodic support beams and low-frequency flexural wave vibration of slender stiffened plate structures. The dispersion relation of flexural wave in the infinite long homogeneous beam coupled with periodic oscillators is calculated using the method of reverberation-ray matrix combined with the Bloch theorem. The accuracy and effectiveness of the method of reverberation-ray matrix in analyzing the band gaps and vibration characteristics of the homogeneous beam coupled with periodic oscillators are verified by the numerical results of the finite long homogeneous beam coupled with periodic oscillators. Both the analytical and numerical results show the existences of flexural wave band gaps in the homogeneous beam coupled with periodic oscillators, in which the propagation of the flexural waves is prohibited and flexural wave vibration is significantly suppressed. Furthermore, the effects of structural and material parameters on the flexural wave band gaps characteristics are respectively investigated. The flexural wave band gaps can be adjusted and optimized manually by adjusting structural and material parameters, which can be applied to vibration and noise control design of periodic support beams and slender stiffened plate structures.

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“…Also, the existence of flat bands implies that the wave propagation pattern is identical in most wave vector directions, under the excitation of the corresponding frequency. These two conditions provide a new approach to low-frequency energy harvesting using LRPnCs [ 25 , 26 ]. Through these previous studies of locally resonant energy self-sufficient PnCs, a 3D super-cell PnC with local resonance spiral structure is investigated by COMSOL, using FEM to build a physical field control grid; thus, parameterized scanning in specified combinations is performed subsequently.…”

Section: Introductionmentioning

confidence: 99%

An Investigation of the Energy Harvesting Capabilities of a Novel Three-Dimensional Super-Cell Phononic Crystal with a Local Resonance Structure

Xiang,

Chai,

Kou

et al. 2024

Sensors

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Using the piezoelectric (PZT) effect, energy-harvesting has become possible for phononic crystal (PnC). Low-frequency vibration energy harvesting is more of a challenge, which can be solved by local resonance phononic crystals (LRPnCs). A novel three-dimensional (3D) energy harvesting LRPnC is proposed and further analyzed using the finite element method (FEM) software COMSOL. The 3D LRPnC with spiral unit-cell structures is constructed with a low initial frequency and wide band gaps (BGs). According to the large vibration deformation of the elastic beam near the scatterer, a PZT sheet is mounted in the surface of that beam, to harvest the energy of elastic waves using the PZT effect. To further improve the energy-harvesting performance, a 5 × 5 super-cell is numerically constructed. Numerical simulations show that the present 3D super-cell PnC structure can make full use of the advantages of the large vibration deformation and the PZT effect, i.e., the BGs with a frequency range from 28.47 Hz to 194.21 Hz with a bandwidth of 142.7 Hz, and the maximum voltage output is about 29.3 V under effective sound pressure with a peak power of 11.5 µW. The present super-cell phononic crystal structure provides better support for low-frequency vibration energy harvesting, when designing PnCs, than that of the traditional Prague type.

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Band Gaps and Transmission Characteristics Analysis on a Two-Dimensional Multiple-Scatter Phononic Crystal Structure

Cited by 9 publications

References 30 publications

Band Gaps Characteristics Analysis of Periodic Oscillator Coupled Damping Beam

Band Gaps Characteristics Analysis of Periodic Oscillator Coupled Damping Beam

Band Gaps and Vibration Attenuation Characteristics Analysis in Homogeneous Beam Coupled With Periodic Oscillators Based on the Method of Reverberation-Ray Matrix

An Investigation of the Energy Harvesting Capabilities of a Novel Three-Dimensional Super-Cell Phononic Crystal with a Local Resonance Structure

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