Relative Dynamic Stiffness Testing and Vibration Suppression Technology for the Complete Set of High-Precision CNC

Feng Tao Wang; Bin Zhang; Yang Yang Zhang; Xing Hai Fu; Liu Hai He

doi:10.4028/www.scientific.net/AMR.430-432.1636

Paper Titles

Research on Mechanism of Two Phase Flow Lifting Pressure Equipment and Output Regulation
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Sensitivity Analysis of Input Parameters of Cartesian Serial-Parallel Manipulator
p.1624

Analysis on Quality Issues for External Thermal Insulation System on Outer Walls
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The Non-Linear Analysis of Cable
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Relative Dynamic Stiffness Testing and Vibration Suppression Technology for the Complete Set of High-Precision CNC
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The Creation of the Special Characters Based on AutoCAD
p.1641

Reliability Evaluation on Machining Center Based on Three-Parameter Weibull Distribution
p.1645

Depth Control of an Electro-Hydraulic Servo System Based on Fractional Order PID
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Upwind Finite Element Method for Solving Radiative Heat Transfer in Graded Index Media
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 430-432Relative Dynamic Stiffness Testing and Vibration...

Relative Dynamic Stiffness Testing and Vibration Suppression Technology for the Complete Set of High-Precision CNC

Abstract:

This thesis proposed a method of testing the relative dynamic stiffness for the whole machine of the high-precision CNC. That is to cut the specimen, then to test the cutting force in all directions and the spindle vibration of the actual processing respectively. It can determine the relative dynamic stiffness of the machine. According to testing results of the relative dynamic stiffness and the structural characteristics of the machine, it can make a program to restrain the suppression vibration. Comparing the dynamic stiffness before vibration suppression and after, vibration resistance of the machine significantly has been improved which validate the effectiveness of the program.

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Periodical:

Advanced Materials Research (Volumes 430-432)

Pages:

1636-1640

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.430-432.1636

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Online since:

January 2012

Authors:

Feng Tao Wang, Bin Zhang, Yang Yang Zhang, Xing Hai Fu, Liu Hai He

Keywords:

High-Precision CNC, Mechanical Vibration Suppression, Relative Dynamic Stiffness, Vibration Testing

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