Nonlinear Dynamic Analysis of the Cutting Process of a Nonextensible Composite Boring Bar

A nonlinear dynamic analysis of the cutting process of a nonextensible composite cutting bar is presented. The cutting bar is simplified as a cantilever with plane bending. The nonlinearity is mainly originated from the nonextensible assumption, and the material of cutting bar is assumed to be visco...

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Bibliographic Details
Published in:Shock and vibration 2020, Vol.2020 (2020), p.1-13
Main Authors: Ma, Bole, Ren, Yongsheng
Format: Article
Language:English
Subjects:
Advanced manufacturing technologies
Aspect ratio
Boring
Carbon fibers
Chatter
Composite materials
Coordinates
Cutting force
Cutting parameters
Cutting tools
Damping
Dynamical systems
Equations of motion
Galerkin method
Hamilton's principle
Investigations
Methods
Multiscale analysis
Nonlinear analysis
Nonlinear differential equations
Nonlinear dynamics
Nonlinearity
Partial differential equations
Resonance
Viscoelasticity
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Summary:A nonlinear dynamic analysis of the cutting process of a nonextensible composite cutting bar is presented. The cutting bar is simplified as a cantilever with plane bending. The nonlinearity is mainly originated from the nonextensible assumption, and the material of cutting bar is assumed to be viscoelastic composite, which is described by the Kelvin–Voigt equation. The motion equation of nonlinear chatter of the cutting system is derived based on the Hamilton principle. The partial differential equation of motion is discretized using the Galerkin method to obtain a 1-dof nonlinear ordinary differential equation in a generalized coordinate system. The steady forced response of the cutting system under periodically varying cutting force is approximately solved by the multiscale method. Meanwhile, the effects of parameters such as the geometry of the cutting bar (including length and diameter), damping, the cutting coefficient, the cutting depth, the number of the cutting teeth, the amplitude of the cutting force, and the ply angle on nonlinear lobes and primary resonance curves during the cutting process are investigated using numerical calculations. The results demonstrate that the critical cutting depth is inversely proportional to the aspect ratio of the cutting bar and the cutting force coefficient. Meanwhile, the chatter stability in the milling process can be significantly enhanced by increasing the structural damping. The peak of the primary resonance curve is bent toward the right side. Due to the cubic nonlinearity in the cutting system, primary resonance curves show the characteristics of typical Duffing’s vibrator with hard spring, and jump and multivalue regions appear.
ISSN:1070-9622
1875-9203
DOI:10.1155/2020/5971540