Analytical evaluation of the acoustic insulation provided by double infinite walls

António, Julieta; Tadeu, A.; Godinho, L.

doi:10.1016/s0022-460x(02)01100-8

Cited by 53 publications

(26 citation statements)

References 23 publications

(26 reference statements)

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“…In this work, a generalization of the technique proposed by Tadeu et al [11][12][13] is performed in order to handle multilayer systems and the application of impact loads. The referenced authors derived a procedure to calculate the pressure field generated by a single panel, based on knowing the solid layer displacement potentials and the pressure potentials due to excitation by a spatially varying harmonic line load.…”

Section: Formulation Of the 25d Problemsmentioning

confidence: 99%

“…The sum of airborne and impact sound insulation is computed for the single concrete layer and integrations in the 1/3 octave band frequency are performed. Responses provided by the analytical model, experimental results and expression (13) are plotted in Fig. 7c.…”

Section: Impact Sound Pressure Levelmentioning

confidence: 99%

“…The formulation of a set of analytical solutions for calculating the acoustic insulation provided by single and double walls when submitted to incident pressure fields has been presented in earlier work [11][12][13]. This paper generalizes that model to solve structures with an arbitrary number of elastic and acoustic layers, also allowing the application of three-dimensional impact loads.…”

Section: Introductionmentioning

confidence: 99%

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Prediction of airborne sound and impact sound insulation provided by single and multilayer systems using analytical expressions

et al. 2007

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In this work, the authors use analytical solutions to assess the airborne sound and impact insulation provided by homogeneous partitions that are infinite along their plane. The algorithm uses Green's functions, derived on the basis of previous work by the authors on the prediction of airborne sound insulation provided by single and double panels. The model is now extended to handle multilayer systems, allowing the simulation of three-dimensional loads applied in both the acoustic and solid media.The model is validated against experimental results and compared with simplified expressions for single, double and triple panels. The results provided by the analytical model were found to provide a good agreement with the experimental results, except in the vicinity of the coincidence effect in the presence of thicker panels.The applicability of the proposed tool is then illustrated by analyzing the acoustic behavior provided by single layers and by a suspended ceiling. Different variables are studied, such as the mass, the stiffness of the layers, the position and direction of the load within the elastic medium and the presence of porous material in the fluid layers. It was found that the model is able to simulate the acoustic phenomena involved in single and multilayer systems.

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Section: Formulation Of the 25d Problemsmentioning

confidence: 99%

Section: Impact Sound Pressure Levelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Prediction of airborne sound and impact sound insulation provided by single and multilayer systems using analytical expressions

et al. 2007

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“…This is due to the geometrical criteria of transmission suites and standardized conditions of acoustic fields that lead to specific acoustic loading of the test specimen under fluid-structure interaction (FSI) [13]. Moreover, predicting the airborne sound transmission through multilayer structures with cavities and structural links, under the influence of FSI, is a rather difficult task due to the complex dynamic system involved [13][14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

A Computationally-Efficient Numerical Model to Characterize the Noise Behavior of Metal-Framed Walls

Arjunan

Wang

English³

et al. 2015

Metals

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Architects, designers, and engineers are making great efforts to design acoustically-efficient metal-framed walls, minimizing acoustic bridging. Therefore, efficient simulation models to predict the acoustic insulation complying with ISO 10140 are needed at a design stage. In order to achieve this, a numerical model consisting of two fluid-filled reverberation chambers, partitioned using a metal-framed wall, is to be simulated at one-third-octaves. This produces a large simulation model consisting of several millions of nodes and elements. Therefore, efficient meshing procedures are necessary to obtain better solution times and to effectively utilise computational resources. Such models should also demonstrate effective Fluid-Structure Interaction (FSI) along with acoustic-fluid coupling to simulate a realistic scenario. In this contribution, the development of a finite element frequency-dependent mesh model that can characterize the sound insulation of metal-framed walls is presented. Preliminary results on the application of the proposed model to study the geometric contribution of stud frames on the overall acoustic performance of metal-framed walls are also presented. It is considered that the presented numerical model can be used to effectively visualize the noise behaviour of advanced materials and multi-material structures.

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“…Influence of air-cavity on sound reduction has been found to be dependent on frequency. At low frequencies, a better performance is achieved for thicker layers; while at higher frequencies a thinner air-layer is preferable (António et al, 2003). Attachment via resilient channels and steel studs is instrumental in increasing sound transmission loss.…”

Section: Introductionmentioning

confidence: 99%

Parametric Sensitivity Analysis of Factors Affecting Sound Transmission Loss of Multi-Layered Building Elements Using Taguchi Method

Garg¹,

Kumar²,

Maji³

2015

Archives of Acoustics

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The paper presents application of Taguchi method in optimizing the sound transmission loss through sandwich gypsum constructions and those comprising of masonry concrete blocks and gypsum boards in order to investigate the relative influence of the various parameters affecting the sound transmission loss. The application of Taguchi method for optimizing sound transmission loss has been rarely reported. The present work uses the results analytically predicted on "Insul" software for various sandwich material configurations as desired by each experimental run in an L8 orthogonal array. The relative importance of the parameters on single-number rating, Rw (C, Ctr) is evaluated in terms of percentage contribution using Analysis of Variance (ANOVA). The ANOVA method reveals that type of studs, steel stud frame and number of gypsum layers attached are the key factors controlling the sound transmission loss characteristics of sandwich multi-layered constructions.

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Analytical evaluation of the acoustic insulation provided by double infinite walls

Cited by 53 publications

References 23 publications

Prediction of airborne sound and impact sound insulation provided by single and multilayer systems using analytical expressions

Prediction of airborne sound and impact sound insulation provided by single and multilayer systems using analytical expressions

A Computationally-Efficient Numerical Model to Characterize the Noise Behavior of Metal-Framed Walls

Parametric Sensitivity Analysis of Factors Affecting Sound Transmission Loss of Multi-Layered Building Elements Using Taguchi Method

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