Microstructure, transport, and acoustic properties of open-cell foam samples: Experiments and three-dimensional numerical simulations

Perrot, Camille; Chevillotte, Fabien; Hoang, Minh Tan; Bonnet, Guy; Bécot, François‐Xavier; Gautron, Laurent; Duval, Arnaud

doi:10.1063/1.3673523

Cited by 93 publications

(70 citation statements)

References 51 publications

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“…As in our previous paper, 14 Stokes flow, potential flow, and heat conduction in the generated fiber webs were simulated using a finite element (FEM) scheme. 14 In the context of diffusion-controlled processes, u pr ð Þ is a scaled concentration field and is defined as the rate of diffusion of the diffusing species divided by the diffusion coefficient of the reactive particles.…”

Section: B Simulation Of Transport Propertiesmentioning

confidence: 99%

“…14 In the context of diffusion-controlled processes, u pr ð Þ is a scaled concentration field and is defined as the rate of diffusion of the diffusing species divided by the diffusion coefficient of the reactive particles. For thermal diffusion, u pr ð Þ is a "temperature field", defined as the ratio of the time derivative of the acoustic pressure over the thermal conductivity of the solid frame.…”

Section: B Simulation Of Transport Propertiesmentioning

confidence: 99%

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Three-dimensional reconstruction of a random fibrous medium: Geometry, transport, and sound absorbing properties

Luu

Perrot

Monchiet

et al. 2017

The Journal of the Acoustical Society of America

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The main purpose of this article is to present, within a unified framework, a technique based on numerical homogenization, to model the acoustical properties of real fibrous media from their geometrical characteristics and to compare numerical results with experimental data. The authors introduce a reconstruction procedure for a random fibrous medium and use it as a basis for the computation of its geometrical, transport, and sound absorbing properties. The previously ad hoc “fiber anisotropies” and “volume weighted average radii,” used to describe the experimental data on microstructure, are here measured using scanning electron microscopy. The authors show that these parameters, in conjunction with the bulk porosity, contribute to a precise description of the acoustical characteristics of fibrous absorbents. They also lead to an accurate prediction of transport parameters which can be used to predict acoustical properties. The computed values of the permeability and frequency-dependent sound absorption coefficient are successfully compared with permeability and impedance-tube measurements. The authors' results indicate the important effect of fiber orientation on flow properties associated with the different physical properties of fibrous materials. A direct link is provided between three-dimensional microstructure and the sound absorbing properties of non-woven fibrous materials, without the need for any empirical formulae or fitting parameters.

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Section: B Simulation Of Transport Propertiesmentioning

confidence: 99%

Section: B Simulation Of Transport Propertiesmentioning

confidence: 99%

Three-dimensional reconstruction of a random fibrous medium: Geometry, transport, and sound absorbing properties

Luu

Perrot

Monchiet

et al. 2017

The Journal of the Acoustical Society of America

Self Cite

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“…25. This limits the analysis to PU foam with a log-normal and sharply peaked distribution of the mean strut length 11 and thus justifies the use of the idealized isotropic cell shape shown in Fig. 1.…”

Section: Microstructure Characterizationmentioning

confidence: 98%

“…[7][8][9][10][11] A detailed description of these approaches has been recently given by a) the authors. 12 A combination of empirical and analytical methods was also presented in Ref.…”

Section: Introductionmentioning

confidence: 99%

“…The inverse method is based on measurements of macroscopic non-acoustic properties (e.g., porosity, airflow resistivity…) coupled to calculations from the three aforementioned micro-/macro models; i.e., empirical, analytical, or numerical models. 11 This latter method provides an effective representative unit-cell that captures the complex microstructure of the porous aggregate being isotropic or anisotropic, fully or partially reticulated. However, this representative unit-cell is not real and its characteristic properties depend on the model used for the inversion.…”

Section: Introductionmentioning

confidence: 99%

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A semi-phenomenological model to predict the acoustic behavior of fully and partially reticulated polyurethane foams

Doutres¹,

Atalla²,

Dong³

2013

Journal of Applied Physics

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This paper proposes simple semi-phenomenological models to predict the sound absorption efficiency of highly porous polyurethane foams from microstructure characterization. In a previous paper [J. Appl. Phys. 110, 064901 (2011)], the authors presented a 3-parameter semi-phenomenological model linking the microstructure properties of fully and partially reticulated isotropic polyurethane foams (i.e., strut length l, strut thickness t, and reticulation rate R w ) to the macroscopic non-acoustic parameters involved in the classical Johnson-Champoux-Allard model (i.e., porosity /, airflow resistivity r, tortuosity a / , viscous K, and thermal K 0 characteristic lengths). The model was based on existing scaling laws, validated for fully reticulated polyurethane foams, and improved using both geometrical and empirical approaches to account for the presence of membrane closing the pores. This 3-parameter model is applied to six polyurethane foams in this paper and is found highly sensitive to the microstructure characterization; particularly to strut's dimensions. A simplified micro-/macro model is then presented. It is based on the cell size C s and reticulation rate R w only, assuming that the geometric ratio between strut length l and strut thickness t is known. This simplified model, called the 2-parameter model, considerably simplifies the microstructure characterization procedure. A comparison of the two proposed semi-phenomenological models is presented using six polyurethane foams being either fully or partially reticulated, isotropic or anisotropic. It is shown that the 2-parameter model is less sensitive to measurement uncertainties compared to the original model and allows a better estimation of polyurethane foams sound absorption behavior. V C 2013 American Institute of Physics. [http://dx

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Effects of Silicone Surfactant on the Properties of Open‐Cell Flexible Polyurethane Foams

et al. 2016

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In this paper, the effects of silicone surfactant on the mechanical, thermal, and acoustical properties of flexible polyurethane foams are studied. At first, by introducing the reactions of the foam production and expressing the stoichiometric relationships, a method is provided to select the amounts of the basic compounds for getting the desirable properties. By knowing the OH number of polyol and the NCO content of isocyanate after selecting an amount of a blowing agent for the reaction, the quantity of each compound to produce the desirable foam can be found. Then different foams with various amounts of surfactant are produced. By preparing proper samples, the mechanical, thermal, nonacoustical, and acoustical properties of the foams are measured or calculated by using different instruments. The nonacoustical properties are obtained based on two distinct methods, i.e., a semiphenomenological method and an indirect method. The obtained properties are validated by comparing the calculated theoretical sound absorption coefficients with the measured ones. The results show that with a small increase of surfactant, the acoustical properties of foam samples improve by about 50% without any significant changes in other mechanical and thermal properties of the foams. This improvement results from the variations of reticulation rate and cell size. In addition, the initial desirable porosity and density considered in the stoichiometric relations are fairly achieved in produced samples. These results validate the accuracy of the stoichiometric relations.

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Microstructure, transport, and acoustic properties of open-cell foam samples: Experiments and three-dimensional numerical simulations

Cited by 93 publications

References 51 publications

Three-dimensional reconstruction of a random fibrous medium: Geometry, transport, and sound absorbing properties

Three-dimensional reconstruction of a random fibrous medium: Geometry, transport, and sound absorbing properties

A semi-phenomenological model to predict the acoustic behavior of fully and partially reticulated polyurethane foams

Effects of Silicone Surfactant on the Properties of Open‐Cell Flexible Polyurethane Foams

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