Effect of temperature on sound transmission loss of laminated composite plate

Pham Ngoc Thanh, Tran Ich Thinh, Ta Thi Hien
Author affiliations

Authors

  • Pham Ngoc Thanh Viet tri University of Industry, Phu Tho, Vietnam https://orcid.org/0000-0002-2647-3258
  • Tran Ich Thinh Hanoi University of Science and Technology, Hanoi, Vietnam
  • Ta Thi Hien University of Transport and communications, Hanoi, Vietnam

DOI:

https://doi.org/10.15625/0866-7136/17917

Keywords:

vibroacoustic behavior, simply supported laminated composite plate, sound transmission loss, thermal loads

Abstract

In this investigation, by an analytical approach, the influence of several key parameters, especially the temperature on the sound isolation capacity of the symmetrically finite orthotropic laminated composite plate is studied. The plate is modeled with classic thin-plate theory and is assumed to be simply supported on all four sides. The incident acoustic pressure is modeled as a harmonic plane wave impinging on the plate at an arbitrary angle. The sound transmission loss is calculated from the ratio of incident to transmitted acoustic powers

Downloads

Download data is not yet available.

References

L. R. Koval. Field-Incident transmission of treated orthotropic and laminated composite panels. National Aeronautics and Space Administration, Langley Research Center, Hampton, VA, (1983).

H.-J. Lin, C.-N. Wang, and Y.-M. Kuo. Sound transmission loss across specially orthotropic laminates. Applied Acoustics, 68, (2007), pp. 1177–1191.

Y.-M. Kuo, H.-J. Lin, and C.-N. Wang. Sound transmission across orthotropic laminates with a 3D model. Applied Acoustics, 69, (2008), pp. 951–959.

T. Lu and F. Xin. Vibro-acoustics of lightweight sandwich structures. Springer Berlin Heidelberg, (2014).

T. I. Thinh and P. N. Thanh. Vibroacoustic response of a finite clamped laminated composite plate. In Advances in Engineering Research and Application, pp. 589–600. Springer International Publishing, (2018).

L. C. Trinh, T. P. Vo, H.-T. Thai, and T.-K. Nguyen. An analytical method for the vibration and buckling of functionally graded beams under mechanical and thermal loads. Composites Part B: Engineering, 100, (2016), pp. 152–163.

S. S. Akavci. Mechanical behavior of functionally graded sandwich plates on elastic foundation. Composites Part B: Engineering, 96, (2016), pp. 136–152.

J. L. Mantari, A. S. Oktem, and C. G. Soares. A new higher order shear deformation theory for sandwich and composite laminated plates. Composites Part B: Engineering, 43, (2012), pp. 1489–1499.

Y. Liu and Y. Li. Vibration and acoustic response of rectangular sandwich plate under thermal environment. Shock and Vibration, 20, (5), (2013), pp. 1011–1030.

Y. Liu and Y. Li. Analyses of dynamic response and sound radiation of sandwich plate subjected to acoustic excitation under thermal environment. In 13th International Conference on Fracture Beijing, China, (2013).

J. Han, K. Yu, X. Li, and R. Zhao. Modal density and mode counts of sandwich panels in thermal environments. Composite Structures, 153, (2016), pp. 69–80.

W. Yuan, H. Song, and C. Huang. Thermal post-buckling behavior of simply supported sandwich panels with truss cores. Journal of Thermal Stresses, 39, (2016), pp. 156–169.

X. Li, K. Yu, J. Han, R. Zhao, and Y. Wu. A piecewise shear deformation theory for free vibration of composite and sandwich panels. Composite Structures, 124, (2015), pp. 111–119.

X. Li and K. Yu. Vibration and acoustic responses of composite and sandwich panels under thermal environment. Composite Structures, 131, (2015), pp. 1040–1049.

Downloads

Published

30-12-2022

Issue

Section

Research Article

Categories

Most read articles by the same author(s)

<< < 1 2 3 > >>