Numerical Simulation Study of the Influence of Turning Depth on the Bending Vibration Mode of Work-Piece

Ming Ming Wu; Shun Cai Li; Qiang Zhang

doi:10.4028/www.scientific.net/AMR.936.1840

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 936Numerical Simulation Study of the Influence of...

Numerical Simulation Study of the Influence of Turning Depth on the Bending Vibration Mode of Work-Piece

Abstract:

The mechanical models with and without thimble constraints for the turning work-piece are built respectively, applying ABAQUS software to analyze the modes of work-piece, then the law of the influence that different turning depth on the bending modes of work-piece is obtained. The study indicates that each-order natural frequency increase gradually in linear form for the work-piece without thimble constraint, while for the work-piece with thimble constraint, the natural frequency of the first four orders decrease linearly with the increase in the turning depth, but the change of high order frequency is relatively complicated.

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Periodical:

Advanced Materials Research (Volume 936)

Pages:

1840-1844

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.936.1840

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Online since:

June 2014

Authors:

Ming Ming Wu, Shun Cai Li*, Qiang Zhang

Keywords:

Bending Vibration, Model, Numerical Simulation, Turning Depth, Turning Work-Piece

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* - Corresponding Author

References

[1] Ren C., Modal analysis of work-piece in turning operation, Mechanical research & application, 2006, 19(4): 32-33 (in Chinese).

Google Scholar

[2] Zheng J., Zhang M., Meng Q., Experimental Modal Analysis and its Application in Structure Dynamic Characters of CNCM machine Tools, Measurement and control technology, 2007, 26(12): 28-31 (in Chinese).

Google Scholar

[3] Li S., Meng H., Time-Varying Characteristics of Bending Deformation of Work-Piece in the Turning Process, Advanced Materials Research, 2011, 337: pp.203-208.

DOI: 10.4028/www.scientific.net/amr.337.203

Google Scholar

[4] Li S., Zhuo S., Jiang H., Meng Hua. Numerical Simulation of Time-dependent Model of Work-piece During Turning, Noise and vibration control, 2012, 32(4): 60-62 (in Chinese).

Google Scholar

[5] Meng H., Li S., Liu Y., Test and analysis of vibration response of turning tool in turning process, The experiment technology and management, 2012. 3, 29(3): 80-83 (in Chinese).

Google Scholar

[6] Zhang Q., Li S., Huang C., Cai C., Experimental Study on Turning Vibration Responses of Cutting Tool on Upper and Lower Surface, Coal mine machinery, 2013, 34(10): 63-65. (in Chinese).

Google Scholar

[7] Huang S., Chen H., Fu P., Gan J., Dynamic tool wear monitoring in CNC turning. Machinery Design & Manufacture, 2010, (2): 191-192. (in Chinese).

Google Scholar

[8] Zhang B., Zhang Q.; Li S., Experimental Study on the Vibration Response of the Work-piece during the Numerical Control Milling. Machine Tool & Hydraulics, 2013, 41(5): 30-32. (in Chinese).

Google Scholar