Description of sub- and superharmonic motion in rotor-stator contact using Fourier series

This paper deals with the description of steady‐state sub‐ and superharmonic motion in rotor‐stator contact using truncated complex Fourier series. Two different approaches are presented with different stages of simplification. In particular, a kinematic contact condition describing continuous conta...

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Bibliographic Details
Published in:Zeitschrift für angewandte Mathematik und Mechanik 2014-11, Vol.94 (11), p.945-950
Main Authors: Alber, O., Mahner, M.
Format: Article
Language:English
Subjects:
Contact
Fourier analysis
Fourier series
harmonic balance
Kinematics
Mathematical models
Nonlinearity
Rotor stator contact
rub
Simplification
subharmonics
Superharmonics
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Summary:This paper deals with the description of steady‐state sub‐ and superharmonic motion in rotor‐stator contact using truncated complex Fourier series. Two different approaches are presented with different stages of simplification. In particular, a kinematic contact condition describing continuous contact is used. The multi‐harmonic balance method is applied to solve the differential algebraic system of equations. A further simplification is implemented which uses the triangular inequality to approximate the nonlinear term in the kinematic contact condition. The Fourier coefficients of the nonlinear term are calculated using an integral expression. Reasonable initial values of the Fourier coefficients for the numerical solution are obtained by a hybrid approach. Results show good agreement with calculations by direct numerical integration using a pseudo‐linear viscoelastic contact model. This paper deals with the description of steady‐state sub‐ and superharmonic motion in rotor‐stator contact using truncated complex Fourier series. Two different approaches are presented with different stages of simplification. In particular, a kinematic contact condition describing continuous contact is used. The multi‐harmonic balance method is applied to solve the differential algebraic system of equations. A further simplification is implemented which uses the triangular inequality to approximate the nonlinear term in the kinematic contact condition. The Fourier coefficients of the nonlinear term are calculated using an integral expression. Reasonable initial values of the Fourier coefficients for the numerical solution are obtained by a hybrid approach. Results show good agreement with calculations by direct numerical integration using a pseudo‐linear viscoelastic contact model.
ISSN:0044-2267
1521-4001
DOI:10.1002/zamm.201300250