Research on Noise Test and Distribution Model of Different Groove Inserts in Dry Milling Process

Yao Nan Cheng; Hai Ting Wang; Hong Zhao; Ming Yang Wu; Li Liu

doi:10.4028/www.scientific.net/KEM.568.31

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 568Research on Noise Test and Distribution Model of...

Research on Noise Test and Distribution Model of Different Groove Inserts in Dry Milling Process

Abstract:

For 45steel, the noise test of different groove milling inserts in milling processing is carried on and the distribution model is studied. Firstly, the cutting noise test system is designed and the acquisition scheme of the test points is determined; secondly, the noise tests in the dry milling process are carried on and the test results are analyzed. Also the influence degree of different milling parameters on the noise of milling inserts is analyzed and the distribution situation of the noise size with different milling parameters is compared; finally, using stepwise regression analysis method, the milling noise distribution models of different groove inserts are set up. Research shows that: in the same machining conditions, different groove inserts, which with complex grooves and a periodic function grooves have the best machining performance. All above study results will provide a certain theoretic base for improving the workshop environment, controlling and predicting the noise and optimizing the design of insert groove.

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Periodical:

Key Engineering Materials (Volume 568)

Pages:

31-36

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.568.31

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Online since:

July 2013

Authors:

Yao Nan Cheng, Hai Ting Wang, Hong Zhao, Ming Yang Wu, Li Liu

Keywords:

Dry Milling, Groove Optimization, Milling Insert, Noise Distribution

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References

[1] J.L. Hong, Y.C. Shi and M.H. Sang, Noise source identification of a BLDC moter[J]. Journal of Mechanical Science and Technology. 22(4)(2008)708-713.

Google Scholar

[2] K.P. Zhu, Y.S. Wong and G. S. Hong. Noise-Robust Tool Condition Monitoring in Micro-milling with Hidden Markov Models. Springer Berlin/Heidelberg. 226 (2008)23-46.

DOI: 10.1007/978-3-540-77465-5_2

Google Scholar

[3] Y.H. Guo, et al. Managing way of several typical machine tool noises, Journal of Jiamusi University. 17(2)(1997)130-132.

Google Scholar

[4] X.S. Zhao, et al. Research on Noise Reduction for Vertical Milling Machine, Mechanical drive. 27(2)(2003)56-58.

Google Scholar

[5] Sweden laborer protection fund knitting . Noise control principle and technology, China environmental science press, Beijing, (1991).

Google Scholar

[6] Z.X. Liu, R.H. Huang, A.M. Tian, Experiment design and data processing, Chemical industry press, Beijing, (2004).

Google Scholar

[7] K. Jemielniak, O. Otman, Catastrophic tool failure detectionbased on acoustic emission signal analysis. Annals of the CIRP, 47(1)(1998)31-34.

DOI: 10.1016/s0007-8506(07)62779-6

Google Scholar

[8] J.S. Zhang, Turning acoustic radiation mathematical model. Journal of Xiamen Radio Television University. 12(2)(2000).

Google Scholar