On fractional modeling of viscoelastic foams

•A no resonance technique based on a forced vibrations procedure in the range 0.1–500 Hz in shear configuration is achieved to avoid the coupling effects and to neglect the air flow resistivity in the foam sample.•A comparative study is developed on known fractional approaches: it is shown that Havr...

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Bibliographic Details
Published in:Mechanics research communications 2019-03, Vol.96, p.62-66
Main Authors: Sahraoui, Sohbi, Zekri, Nouredine
Format: Article
Language:English
Subjects:
Acoustics
Dynamic modulus
Engineering Sciences
Fractional models
Loss modulus
Polyurethane foams
Wide frequency range
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Summary:•A no resonance technique based on a forced vibrations procedure in the range 0.1–500 Hz in shear configuration is achieved to avoid the coupling effects and to neglect the air flow resistivity in the foam sample.•A comparative study is developed on known fractional approaches: it is shown that Havriliak–Negami model gives a better result on viscoelastic behavior of polyurethane foams having sound absorbing properties.•Original experimental setup and fractional model approach for mechanical constants prediction in wide frequency range. Empiric models have been introduced to describe frequency dependence of dielectric permittivity. Simple exponential models are often not satisfactory, while advanced non-exponential models (usually referred as “anomalous relaxation”) are commonly required to better explain experimental observations of complex systems. For viscoelastic materials, the so-called fractional derivatives models are powerful for both dynamic and loss moduli prediction. In this paper, the analysis of the main models used in the characterization of dielectric and viscoelastic materials such as five-parameter fractional Zener model and empiric Havriliak–Negami model are analysed. The fractional shape parameters describing the symmetric and asymmetric broadening of the complex modulus don't have the same influence in low and high frequencies. In contrast to the five-parameter Zener model, the empiric model asymmetry parameter has an influence on complex modulus at low frequencies comparing to the loss modulus peak frequency. A no resonance technique based on a forced vibrations procedure is used to investigate the frequency dependent complex shear modulus of a polyurethane foam, not influenced by its fluid phase, in the range 0.1–500 Hz. It is shown that the Havriliak–Negami model can predict the frequency dependence for a wide frequency range.
ISSN:0093-6413
1873-3972
DOI:10.1016/j.mechrescom.2019.03.004