The vibration analysis of the natural frequencies and mode shapes of a class of doubly-curved shells with different boundary conditions is presented. The doubly-curved shells are geometrically taken from various parts of a hollow torus with annular cross-section. The small strain, three-dimensional, linear elasticity theory is adopted to establish the governing equations of the problem in terms of the toroidal coordinate system (r, θ, ϕ). The Chebyshev-Ritz method is used to set up the eigenvalue equation: displacement in each direction is taken as a triplicate product of the Chebyshev polynomials in r, θ and ϕ, multiplied by a boundary function along with a set of generalized coefficients to yield upper bound values of the natural frequencies. The natural frequencies converge monotonically to the exact values as more terms of Chebyshev polynomials are included in the Ritz approximation. The effects of thickness ratio, radius ratio, toroidal angle in ϕ direction, initial angle and subtended angle in θ direction on natural frequencies and mode shapes are discussed in detail.
BiglariHJafariAA (2010) Higher-order free vibrations of doubly-curved sandwich panels with flexible core based on refined three-layered theory. Composite Structures92: 2685–2694.
2.
ChaudhuriRAKabirHRH (1994) Static and dynamic Fourier analysis of finite cross-ply doubly curved panels using classical shallow shell theories. Composite Structures28: 73–91.
3.
DonnellLH (1934) A new theory for the buckling of thin cylinders under axial compression and bending. Transactions of the ASME56: 795–806.
4.
FlüggeW (1973) Stresses in Shells, Berlin: Springer-Verlag.
5.
FoxLParkerIB (1968) Chebyshev Polynomials in Numerical Analysis, London: Oxford University Press.
6.
Hosseini-HashemiSHFadaeeM (2011) On the free vibration of moderately thick spherical shell panel – a new exact closed-form procedure. Journal of Sound and Vibration330: 4352–4367.
7.
KangJHLeissaAW (2000) Three-dimensional vibrations of thick spherical shell segments with variable thickness. International Journal of Solids and Structures37: 4811–4823.
8.
KangJHLeissaAW (2005) Three-dimensional vibration analysis of thick hyperboloidal shells of revolution. Journal of Sound and Vibration282: 277–296.
9.
LeissaAWKangJH (1999) Three-dimensional vibration analysis of thick shells of revolution. ASCE Journal of Engineering Mechanics125: 1365–1371.
10.
LeissaAWKangJH (2002) Three-dimensional vibration analysis of paraboloidal shells. JSME International Journal Series C – Mechanical Systems Machine Elements and Manufacturing45: 2–7.
11.
LiewKMLimCW (1994a) Vibratory characteristics of cantilevered rectangular shallow shells of variable thickness. AIAA Journal32: 387–396.
12.
LiewKMLimCW (1994b) Vibration of perforated doubly-curved shallow shells with rounded corners. International Journal of Solids and Structures31: 1519–1536.
13.
LiewKMLimCW (1995a) Vibratory characteristics of doubly-curved shallow shells of curvilinear planform. ASCE Journal of Engineering Mechanics121: 203–213.
14.
LiewKMLimCW (1995b) A Ritz vibration analysis of doubly-curved rectangular shallow shells using a refined first-order theory. Computer Methods in Applied Mechanics and Engineering127: 145–162.
15.
LiewKMLimCW (1996a) Vibration of doubly-curved shallow shells. Acta Mechanica114: 95–119.
16.
LiewKMLimCW (1996b) A higher-order theory for vibration of doubly curved shallow shells. ASME Journal of Applied Mechanics63: 587–593.
17.
LiewKMLimCW (1997) Vibration of thick doubly-curved stress free shallow shells of curvilinear planform. ASCE Journal of Engineering Mechanics123: 413–421.
18.
LiewKMBergmanLANgTYLamKY (2000) Three-dimensional vibration of cylindrical shell panels – solution by continuum and discrete approaches. Computational Mechanics26: 208–221.
19.
LiewKMLimCWKitipornchaiS (1997) Vibration of shallow shells: a review with bibliography. ASME Applied Mechanics Reviews50: 431–443.
20.
LiewKMPengLXNgTY (2002) Three-dimensional vibration analysis of spherical shell panels subjected to different boundary conditions. International Journal of Mechanical Sciences44: 2103–2117.
21.
LimCWLiewKM (1994) A pb-2 Ritz formulation for flexural vibration of shallow cylindrical shells of rectangular planform. Journal of Sound and Vibration31: 1519–1536.
22.
LimCWLiewKM (1995) A higher order theory for vibration of shear deformable cylindrical shallow shells. International Journal of Mechanical Sciences37: 277–295.
23.
LimCWLiewKM (1996) Vibration of moderately thick cylindrical shallow shells. Journal of the Acoustics Society of America100: 3665–3673.
24.
LimCWKitipornchaiSLiewKM (1997) Comparative accuracy of shallow and deep shell theories for vibration of cylindrical shells. Journal of Vibration and Control3: 119–143.
25.
LimCWLiewKMKitipornchaiS (1998) Vibration of open cylindrical shells: a three-dimensional elasticity approach. Journal of the Acoustics Society of America104: 1436–1443.
26.
LoveAEH (1934) The Mathematical Theory of Elasticity, London: Cambridge University Press.
27.
McGeeOGSprySC (1997) A three-dimensional analysis of the spherical and toroidal elastic vibrations of thick-walled spherical bodies of revolution. International Journal for Numerical Methods in Engineering40: 1359–1382.
28.
MelaragnoM (1991) An Introduction to Shell Structures, New York: Van Nostrand Reinhold.
29.
NaritaYLeissaA (1986) Vibrations of completely free shallow shells of curvilinear planform. ASME Journal of Applied Mechanics53: 647–651.
30.
PradyumnaSBandyopadhyayJN (2008) Free vibration analysis of functional graded curved panels using a higher-order finite element formulation. Journal of Sound and Vibration318: 176–192.
31.
QutaMSLeissaAW (1992) Effects of edge constraints upon shallow shell frequencies. Thin-Walled Structures14: 347–379.
32.
QutaMSLeissaAW (1993) Vibration of shallow shells with 2 adjacent edges clamped and the others free. Mechanics of Structures and Machines21: 285–301.
33.
ReddyJN (1983) Exact solutions of moderately thick laminated shells. ASCE Journal of Engineering Mechanics110: 794–809.
34.
ReddyJNLiuCF (1985) A higher-order shear deformation theory for laminated elastic shells. International Journal of Engineering Science23: 319–330.
35.
ReissnerE (1941) A new derivation of the equations of the deformation of elastic shells. American Journal of Mathematics63: 177–184.
36.
TornabeneFViolaE (2007) Vibration analysis of spherical structural elements using the GDQ method. Computers and Mathematics with Applications53: 1538–1560.
37.
YoungPG (2000) Application of a three-dimensional shell theory to the free vibration of shells arbitrarily deep in one direction. Journal of Sound and Vibration238: 257–269.
38.
ZhaoXNgTYLiewKM (2004) Free vibration of two-side simply-supported laminated cylindrical panels via the mesh-free kp-Ritz method. International Journal of Mechanical Sciences46: 123–142.
39.
Zhou D (2003) Three-Dimensional Vibration Analysis of Structural Elements Using Chebyshev-Ritz Method. PhD thesis, University of Hong Kong, Hong Kong.
40.
ZhouDLoSH (2012) Three-dimensional vibrations of annular thick plates with linearly varying thickness. Archive of Applied Mechanics82: 111–135.
41.
ZhouDAuFTKLoSHCheungYK (2002) Three-dimensional vibration analysis of a torus with circular cross-section. Journal of the Acoustical Society of America112: 2831–2840.
42.
ZhouDCheungYKLoSH (2010a) 3-D vibration analysis of circular rings with sectorial cross-sections. Journal of Sound and Vibration329: 1523–1535.
43.
ZhouDCheungYKLoSH (2010b) Three-dimensional vibration analysis of toroidal sectors with solid circular cross-section. ASME Journal of Applied Mechanics77: 555–562.
44.
ZhouDCheungYKLoSHAuFTK (2003) 3-D vibration analysis of thick, solid and hollow circular cylinders via Chebyshev-Ritz method. Computer Methods in Applied Mechanics and Engineering192: 1575–1589.
45.
ZhouDLiuWMcGeeOGIII (2011) On the three-dimensional vibrations of a hollow elastic torus of annular cross-section. Archive of Applied Mechanics81: 473–487.
46.
ZhouDLoSHCheungYK (2009) 3-D vibration analysis of annular sector plates using the Chebyshev–Ritz method. Journal of Sound and Vibration320: 421–437.
