An approach on the vibro-acoustic properties of composite sandwich plates with foam core

Tran Ich Thinh
Author affiliations

Authors

  • Tran Ich Thinh Hanoi University of Science and Technology, Ha Noi, Viet Nam

DOI:

https://doi.org/10.15625/0866-7136/16846

Keywords:

vibroacoustic properties, composite sandwich plate, foam core, sound transmission loss, apparent bending stiffness

Abstract

In this paper, an approach is proposed and presented to tackle the vibro-acoustic properties of finite clamped composite sandwich plates with foam core. Composite sandwich plates are treated as being orthotropic and the apparent bending stiffnesses are calculated for the two principal directions. The apparent bending stiffnesses of composite sandwich plate are estimated by finite element calculation on beam elements cut from the considered composite sandwich plates. The sound transmission loss of clamped composite sandwich plates is predicted using orthotropic Kirchhoff’s plate theory, together with the obtained bending stiffnesses in two principal directions. Several sound transmission loss measurements were conducted in the laboratory on fiberglass/polyester composite sandwich plates with polyurethane foam core. The predicted sound transmission loss is compared with measured data and the agreement is reasonable.

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References

R. D. Ford, P. Lord, and A. W. Walker. Sound transmission through sandwich constructions. Journal of Sound and Vibration, 5, (1967), pp. 9–21.

J. A. Moore and R. H. Lyon. Sound transmission loss characteristics of sandwich panel constructions. The Journal of the Acoustical Society of America, 89, (1991), pp. 777–791.

J. S. Bolton, N.-M. Shiau, and Y. J. Kang. Sound transmission through multi-panel structures lined with elastic porous materials. Journal of Sound and Vibration, 191, (1996), pp. 317–347.

R. Cherif and N. Atalla. Experimental investigation of the accuracy of a vibroacoustic model for sandwich-composite panels. The Journal of the Acoustical Society of America, 137, (2015), pp. 1541–1550.

S. Hwang, J. Kim, S. Lee, and H. Kwun. Prediction of sound reduction index of double sandwich panel. Applied Acoustics, 93, (2015), pp. 44–50.

K. C. Sahu, J. Tuhkuri, and J. N. Reddy. Active attenuation of sound transmission through a soft-core sandwich panel into an acoustic enclosure using volume velocity cancellation. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 229, (2015), pp. 3096–3112.

V. D'Alessandro, G. Petrone, F. Franco, and S. D. Rosa. A review of the vibroacoustics of sandwich panels: Models and experiments. Journal of Sandwich Structures & Materials, 15, (2013), pp. 541–582.

C. Shen, F. X. Xin, and T. J. Lu. Theoretical model for sound transmission through finite sandwich structures with corrugated core. International Journal of Non-Linear Mechanics, 47, (2012), pp. 1066–1072.

C. J. Naify, C. Huang, M. Sneddon, and S. Nutt. Transmission loss of honeycomb sandwich structures with attached gas layers. Applied Acoustics, 72, (2011), pp. 71–77.

R. D. Mindlin. Influence of rotatory inertia and shear on flexural motions of isotropic, elastic plates. Journal of Applied Mechanics, 18, (1951), pp. 31–38.

W. Shengchun, D. Zhaoxiang, and S. Weidong. Sound transmission loss characteristics of unbounded orthotropic sandwich panels in bending vibration considering transverse shear deformation. Composite Structures, 92, (2010), pp. 2885–2889.

J. Zhou, A. Bhaskar, and X. Zhang. Sound transmission through a double-panel construction lined with poroelastic material in the presence of mean flow. Journal of Sound and Vibration, 332, (2013), pp. 3724–3734.

E. Nilsson and A. C. Nilsson. Prediction and measurement of some dynamic properties of sandwich structures with honeycomb and foam cores. Journal of Sound and Vibration, 251, (2002), pp. 409–430.

Y. Qu, Z. Peng, W. Zhang, and G. Meng. Nonlinear vibro-acoustic behaviors of coupled sandwich cylindrical shell and spring-mass-damper systems. Mechanical Systems and Signal Processing, 124, (2019), pp. 254–274.

B. R. Mace and E. Manconi. Modelling wave propagation in two-dimensional structures using finite element analysis. Journal of Sound and Vibration, 318, (2008), pp. 884–902.

C. Droz, C. Zhou, M. N. Ichchou, and J.-P. Lain´e. A hybrid wave-mode formulation for the vibro-acoustic analysis of 2D periodic structures. Journal of Sound and Vibration, 363, (2016), pp. 285–302.

D. Chronopoulos, M. Ichchou, B. Troclet, and O. Bareille. Computing the broadband vibroacoustic response of arbitrarily thick layered panels by a wave finite element approach. Applied Acoustics, 77, (2014), pp. 89–98.

Y. Yang, B. R. Mace, and M. J. Kingan. Prediction of sound transmission through, and radiation from, panels using a wave and finite element method. The Journal of the Acoustical Society of America, 141, (2017), pp. 2452–2460.

Y. Yang, B. R. Mace, and M. J. Kingan.Wave and finite element method for predicting sound transmission through finite multi-layered structures with fluid layers. Computers & Structures, 204, (2018), pp. 20–30.

T. J. Lu and F. X. Xin. Vibro-acoustics of lightweight sandwich. Science Press Beijing and Springer-Verlag Berlin Heidenberg, (2014).

ISO 140-4. Acoustics - Measurement of sound insulation in buildings and of building elements – Part 4: Field measurements of airborne sound insulation between rooms. (1998).

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Published

29-06-2022

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Research Article

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