Sage Journals: Discover world-class research

Abstract

According to the framework of the Flügge’s shell theory, the Winkler and Pasternak foundations model, the transfer matrix approach and the Romberg integration method, the vibration behavior of an isotropic and orthotropic cylindrical shell with variable thickness is investigated. The governing equations of the shell based on the Pasternak foundation model are formulated and solved. The analysis is formulated to overcome the mathematical difficulties related to mode coupling which comes from the variable curvature and thickness of the shell. The vibration equations of the shell are reduced to eight first order differential equations in the circumferential coordinate. Using the transfer matrix of the shell, these equations can be written in a matrix differential equation. The proposed model is adopted to get the vibration frequencies and the corresponding mode shapes for the symmetrical and antisymmetrical modes of vibration. The sensitivity of the frequency parameters and the bending deformations to the Winkler and Pasternak foundations moduli, the thickness ratio, and the orthotropic parameters are demonstrated.

Keywords

Orthotropic cylindrical shells symmetric and antisymmetric modes transfer matrix method variable thickness vibration behavior Winkler-Pasternak foundation

Get full access to this article

View all access options for this article.

References

Bagherizadeh

Kiani

Eslami

(2011) Mechanical buckling of functionally graded material cylindrical shells surrounded by Pasternak elastic foundation. Composite Structures 93: 3063–3071.

Flügge

(1973) Stress in Shells, New York: Springer-Verlag.

Golovko

Lugovoi

Meish

(2007) Solution of axisymmetric dynamics problems for cylindrical shells on an elastic foundation. International Journal of Applied Mechanics 43(12): 1390–1395.

Gunawan

Sato

Kanie

Mikami

(2004) Static and free vibration analysis of cylindrical shells on elastic foundation. Journal of Structural Engineering 50A: 25–34.

Gunawan

Mikami

Kanie

Sato

(2006) Free vibration characteristics of cylindrical shells partially buried in elastic foundations. Journal of Sound and Vibration 290(3–5): 785–793.

Kerr

(1964) Elastic and visco-elastic foundation models. Journal of Applied Mechanics 31: 491–498.

Khalifa

(2010) A study of free vibration of a circumferentially non-uniform cylindrical shell with a four-lobed cross-section. Journal of Vibration and Control 17(8): 1158–1172.

Khalifa

(2011a) A new vibration approach of an elastic oval cylindrical shell with varying circumferential thickness. Journal of Vibration and Control 18(1): 117–131.

Khalifa

(2011b) Exact solutions for the vibration of circumferentially stepped orthotropic circular cylindrical shells. Comptes Rendus Mecanique 339: 708–718.

10.

Novozhilov

(1964) The Theory of Thin Elastic Shells, Groningen, The Netherlands: P. Noordhoff Ltd.

11.

Paliwal

Bhalla

(1993a) Large deflection analysis of cylindrical shells on a Pasternak foundation. International Journal of Pressure Vessels and Piping 53: 261–271.

12.

Paliwal

Bhalla

(1993b) Large amplitude free vibrations of a cylindrical shell on Pasternak foundations. International Journal of Pressure Vessels and Piping 54: 387–398.

13.

Paliwal

Pandey

(1998) The Free vibrations of a cylindrical shell on an elastic foundation. Journal of Vibration and Acoustics 120(1): 63–71.

14.

Paliwal

Pandey

(2001) Free vibrations of an orthotropic thin cylindrical shell on a Pasternak foundation. AIAA Journal 39(11): 2188–2191.

15.

Paliwal

Singh

(1999) Free vibrations of orthotropic cylindrical shell on elastic foundation. AIAA Journal 37(9): 1135–1139.

16.

Paliwal

Srivastava

(1994) Large deflections of a cylindrical shell on a Kerr foundation. International Journal of Pressure Vessels and Piping 57(1): 1–5.

17.

Paliwal

Kanagasabapathy

Gupta

(1995) The large deflection of an orthotropic cylindrical shell on a Pasternak foundation. Composite Structures 31: 31–37.

18.

Paliwal

Pandey

Nath

(1996) Free vibrations of circular cylindrical shell on Winkler and Pasternak foundations. International Journal of Pressure Vessels and Piping 69(1): 79–89.

19.

Pasternak

(1954) On a New Method of Analysis of an Elastic Foundation by Means of Two Foundation Constants, Moscow: Gos Izd. Lit. Stroit. Arkhit.

20.

Shah

Mahmood

Naeem

Iqbal

Arshad

(2010) Vibrations of functionally graded cylindrical shells based on elastic foundations. Acta Mechanica 211(3): 293–307.

21.

Sofiyev

(2011) Thermal buckling of FGM shells resting on at two-parameter elastic foundation. Thin-walled Structures 49: 1304–1311.

22.

Sofiyev

Keskina

(2004) Effects of elastic foundation on the vibration of laminated non-homogeneous orthotropic circular cylindrical shells. Shock and Vibration 11: 89–101.

23.

Sofiyev

Halilov

Kuruoglu

(2011) Analytical solution of the dynamic behavior of non-homogenous orthotropic cylindrical shells on elastic foundations under moving loads. Journal of Engineering Mathematics 69: 359–371.

24.

Tesar

Fillo

(1988) Transfer Matrix Method, Dordrecht, The Netherlands: Kluwer Academic.

25.

Uhrig

(1973) Elastostatikund Elastokinetikin Matrizenschreibweise, Berlin: Springer.

Natural frequencies and mode shapes of variable thickness elastic cylindrical shells resting on a Pasternak foundation

Abstract

Keywords

Get full access to this article

References