Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-26T06:59:12.541Z Has data issue: false hasContentIssue false

Application of Vectorial Wave Method in Free Vibration Analysis of Cylindrical Shells

Published online by Cambridge University Press:  11 July 2017

R. Poultangari
Affiliation:
Department of Mechanical Engineering, Dezful Branch, Islamic Azad University, Dezful 64616-45165, Iran
M. Nikkhah-Bahrami*
Affiliation:
Department of Mechanical and Aerospace Engineering, Science and Research Branch, Islamic Azad University, Tehran 14515-775, Iran
*
*Corresponding author. Email:[email protected] (M. N. Bahrami)
Get access

Abstract

The vectorial form of the Wave Propagation Method (VWM), regarding the dispersion of harmonic plain (elasto-dynamic) waves within certain wave-guides, is developed for the vibration analysis of circular cylindrical shells. To obtain this goal, all plain waves are divided into positive-negative going wave vectors along with the shell axis. Based on the Flügge thin shell theory, the shell continuity as well as boundary conditions are well satisfied by introducing the propagation and reflection matrices. Furthermore, all elements of the reflection matrix are derived for certain classical supports. As an example, for demonstrating the feasibility of VWM in the shell vibration analysis, a circular cylindrical shell with two ended flexible support is adopted. The natural frequencies of the systemaswell asmode shapes are obtained using VWM. The aquired results are compared with those of the previous works and found in excellent agreement. It is also found that VWM could mathematically provide a reduced dimensional matrix (dominant matrix) to calculate the natural frequencies of the system. Accordingly, the proposed method can provide high computational efficiency and remarkable accuracy, simultaneously.

MSC classification

Type
Research Article
Copyright
Copyright © Global-Science Press 2017 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

[1] Qatu, M. S., Recent research advances in the dynamic behavior of shells: 1989-2000, Part 2: homogeneous shells, ASME Appl. Mech. Rev., 55 (2002), pp. 415434.CrossRefGoogle Scholar
[2] Salahifar, R. and Mohareb, M., Finite element for cylindrical thin shells under harmonic forces, Finite Elem. Anal. Des., 52 (2012), pp. 8392.CrossRefGoogle Scholar
[3] Qu, Y., Chen, Y., Long, X., Hua, H. and Meng, G., Free and forced vibration analysis of uniform and stepped circular cylindrical shells using a domain decomposition method, Appl. Acoust., 74 (2013), pp. 425439.CrossRefGoogle Scholar
[4] Loy, C. T., Lam, K. Y. and Shu, C., Analysis of cylindrical shells using generalized differential quadrature, Shock Vib., 4 (1997), pp. 193198.CrossRefGoogle Scholar
[5] Chen, Y., Jin, G. and Liu, Z., Free vibration analysis of circular cylindrical shell with non-uniform elastic boundary conditions, Int. J. Mech. Sci., 74 (2013), pp. 120132.CrossRefGoogle Scholar
[6] Chang, S. D. and Greif, R., Vibrations of segmented cylindrical shells by a fourier series component mode method, J. Sound Vib., 67 (1979), pp. 315328.CrossRefGoogle Scholar
[7] Chen, M., Xie, K., Xu, K., Yu, P. and Yan, Y., Wave based method for free and forced vibration analysis of cylindrical shells with discontinuity in thickness, J. Vib. Acoust., 107 (2015), 051004.CrossRefGoogle Scholar
[8] Zhou, J. and Yang, B., Distributed transfer function method for analysis of cylindrical shells, AIAA J., 33 (1995), pp. 16981708.CrossRefGoogle Scholar
[9] Li, X. B., Study on Free vibration analysis of circular cylindrical shells using wave propagation, J. Sound Vib., 311 (2008), pp. 667682.Google Scholar
[10] Xuebin, L., Study on free vibration analysis of circular cylindrical shell using wave propagation, J. Sound. Vib., 311 (2008), pp. 667682.CrossRefGoogle Scholar
[11] Zhou, H., Li, W., Lv, B. and Li, W. L., Free vibration of cylindrical shells with elastic-support boundary conditions, Appl. Acoust., 73 (2012), pp. 751756.CrossRefGoogle Scholar
[12] Zhang, L. and Xiang, Y., Exact solution for vibration of stepped circular cylindrical shells, J. Sound. Vib., 299 (2007), pp. 948964.CrossRefGoogle Scholar
[13] Nikkhah-Bahrami, M., Khoshbayani-Arani, M. and Rasekh-Saleh, N., Modified wave approach for calculation of natural frequencies and mode shapes in arbitrary non-uniform beams, Scientia Iranica, 18 (2011), pp. 10881094.CrossRefGoogle Scholar
[14] Mei, C. and Mase, B. R., Wave reflection and transmission in Timoshenko beams and wave analysis of Timoshenko beam structures, J. Vib. Acoust., 127 (2005), pp. 382394.CrossRefGoogle Scholar
[15] Mei, C., Hybrid wave/mode active control of bending vibrations in beams based on the advanced Timoshenko theory, J. Sound Vib., 322 (2009), pp. 2938.CrossRefGoogle Scholar
[16] Huang, D., Tang, L. and Cao, R., Free vibration analysis of planar rotating rings by wave propagation, J. Sound Vib., 332 (2013), pp. 49794997.CrossRefGoogle Scholar
[17] Lee, S.-K., Mace, B. R. and Brennan, M. J., Wave propagation, reflection and transmission in curved Beams, J. Sound. Vib., 309 (2007), pp. 639656.Google Scholar
[18] Bahrami, A., Ilkhani, M. R. and Nikkhah-Bahram, M., Wave propagation technique for free vibration analysis of annular circular and sectorial membranes, J. Vib. Cont., 0 (2012), pp. 17.Google Scholar
[19] Ma, Y., Zhang, Y. and Kennedy, D., A symplectic analytical wave based method for the wave propagation and steady state forced vibration of rectangular thin plates, J. Sound Vib., 339 (2015), pp. 196214.CrossRefGoogle Scholar