Sage Journals: Discover world-class research

Abstract

A computational procedure has been developed to evaluate the influence of the random parameter changes to the dynamic behaviour of rotating Timoshenko beams. Based on the mean-centred second-order perturbation technique and non-linear eigenvalue analysis, the stochastic modal analysis is developed for stochastic sensitivity measures of rotating beams with uncertain material and sectional properties, uncertain geometric parameters and a random rotating velocity. A consistent linearization of the fully geometrically non-linear beam theory and the virtual work principle are used to derive the governing equations of a rotating Timoshenko beam, and a power series method is employed for the non-linear eigenvalue analysis to obtain the natural frequencies and vibration modes. A sensitivity analysis is performed to identify the important factors influencing the variation in frequency responses. To establish the validity of the present probabilistic approach, numerical examples with results obtained by using the Monte Carlo method are given for comparison.

Keywords

rotating Timoshenko beams stochastic modal analysis sensitivity analysis non-linear eigenvalue analysis

Get full access to this article

View all access options for this article.

References

Wang

J. T. S.

Mahrenholtz

Bohm

Extended Galerkin's method for rotating beam vibrations using Legendre polynomials. Solid Mechanics Arch., 1976, 1 (4), 341–365.

Yokoyama

Free vibration characteristics of rotating Timoshenko beam. Int. J. Mech. Sci., 1988, 30 (10), 743–755.

Lee

S. Y.

Lin

S. M.

Bending vibrations of rotating nonuniform Timoshenko beams with an elastically restrained root. Trans. ASME, J. Appl. Mechanics, 1994, 61, 949–955.

Lim

M. K.

Liew

K. M.

A power series solution for vibration of a rotating Timoshenko beam. J. Sound Vibr., 1994, 175 (4), 505–523.

Nagaraj

V. T.

Approximate formula for the frequencies of a rotating Timoshenko beam. J. Aircr., 1996, 33 (3), 637–639.

Boyce

E. W.

Goodwin

B. E.

Random transverse variation of elastic beams. SIAM J., 1964, 12, 613–629.

Soong

T. T.

Bogdanoff

J. L.

On the natural frequencies of a disordered linear chain of N degrees of freedom. Int. J. Mech. Sci., 1963, 5, 237–265.

Nakagiri

Takabatke

Tani

Uncertain eigenvalue analysis of composite laminated plates by the stochastic finite element method. In The Winter Annual Meeting, ASME, 1985, pp. 1–8.

Hien

T. D.

Kleiber

Stochastic design sensitivity in structural dynamics. Int. J. Numer. Meth. Engng, 1991, 32, 1247–1265.

10.

Likins

P. W.

Mathematical modeling of spinning elastic bodies for model analysis. Am. Inst. Aeronaut. Astronaut. J., 1973, 11 (9), 1251–1258.

11.

Jankovic

M. S.

Analytical solutions for the

n-th derivatives of eigenvalues and eigenvectors for a non-linear eigenvalue problem. Am. Inst. Aeronaut. Astronaut. J., 1987, 204–205.

12.

IMSL User's Manual, 1989 (IMSL, Houston, Texas).

Sensitivity of the dynamic behaviour of random rotating Timoshenko beams to system parameter changes

Abstract

Abstract

Keywords

Get full access to this article

References