A consistent corotational formulation for the nonlinear dynamic analysis of sliding beams

This paper presents a consistent corotational formulation for the geometric nonlinear dynamic analysis of 2D sliding beams. Compared with the works of previously published papers, the same cubic shape functions are used to derive the elastic force vector and the inertia force vector. Consequently, t...

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Bibliographic Details
Published in:Journal of sound and vibration 2020-06, Vol.476, p.115298, Article 115298
Main Authors: Deng, Lanfeng, Zhang, Yahui
Format: Article
Language:English
Subjects:
Axial strain
Corotational method
Deformation
Dynamical systems
Equations of motion
Finite element analysis
Hamilton's principle
Inertia
Interpolation
Mathematical analysis
Matrix algebra
Matrix methods
Newton-Raphson method
Nonlinear analysis
Nonlinear dynamic analysis
Nonlinear dynamics
Nonlinear equations
Nonlinear finite elements
Nonlinear systems
Rotary inertia
Shape functions
Shear deformation
Sliding
Sliding beams
Two dimensional analysis
Variable-domain beam elements
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Summary:This paper presents a consistent corotational formulation for the geometric nonlinear dynamic analysis of 2D sliding beams. Compared with the works of previously published papers, the same cubic shape functions are used to derive the elastic force vector and the inertia force vector. Consequently, the consistency of the element is ensured. The shape functions are used to describe the local displacements to establish an element-independent framework. Moreover, all kinds of standard elements can be embedded within this framework. Therefore, the presented method is more versatile than previous approaches. To consider the shear deformation, the sliding beam (a system of changing mass) is discretized using a fixed number of variable-domain interdependent interpolation elements (IIE). In addition, the nonlinear axial strain and the rotary inertia are also considered in this paper. The nonlinear motion equations are derived by using the extended Hamilton's principle and solved by combining the Newton-Raphson method and the Hilber-Hughes-Taylor (HHT) method. Furthermore, the closed-form expressions of the iterative tangent matrix and the residual force vector are obtained. Three classic examples are given to verify the high accuracy and efficiency of this formulation by comparing the results with those of commercial software and published papers. The simulation results also show that the shear deformation and the rotary inertia cannot be neglected for the large-rotation and high-frequency problem.
ISSN:0022-460X
1095-8568
DOI:10.1016/j.jsv.2020.115298