Nothing Special   »   [go: up one dir, main page]
Top > IJAT > Study on Machining Vibration Suppression with Multiple Tuned M ...

single-au.php

IJAT Vol.11 No.2 pp. 206-214
doi: 10.20965/ijat.2017.p0206
(2017)

Paper:

Views over last 60 days: 1,034

Study on Machining Vibration Suppression with Multiple Tuned Mass Dampers: Vibration Control for Long Fin Machining

Ippei Kono*1,†, Takayuki Miyamoto*2, Koji Utsumi*1, Kenji Nishikawa*1, Hideaki Onozuka*3, Junichi Hirai*4, and Naohiko Sugita*5

*1Hitachi, Ltd.
292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa, Japan

Corresponding author

*2Mitsubishi Hitachi Power Systems, Ltd., Ibaraki, Japan

*3Hitachi Automotive Systems, Ltd., Kanagawa, Japan

*4Hitachi, Ltd., Ibaraki, Japan

*5The University of Tokyo, Tokyo, Japan

Received:
August 25, 2016
Accepted:
November 4, 2016
Published:
March 1, 2017
Creative Commons License
Keywords:
tuned mass damper, machining, milling, chatter
Abstract
This study aims to suppress vibration during the machining of long and thin fin parts. Typically, fin parts have low stiffness because fixing the fin is impeded by a end-mill, machine tool or other fins. In this study, multiple tuned mass dampers (TMDs) with the same characteristics were applied to the machining of a fin part measuring 18 mm × 180 mm × 2600 mm. The characteristics of the TMDs were optimized by calculation using a lumped-mass-points system model of the fin part. Then, an impact hammer test and a machining test were conducted on the actual fin part. The dynamic stiffness of the fin part was improved by up to 14 times by using five TMDs, and the amplitude of vibration during machining was decreased by more than 90%.
Cite this article as:
I. Kono, T. Miyamoto, K. Utsumi, K. Nishikawa, H. Onozuka, J. Hirai, and N. Sugita, “Study on Machining Vibration Suppression with Multiple Tuned Mass Dampers: Vibration Control for Long Fin Machining,” Int. J. Automation Technol., Vol.11 No.2, pp. 206-214, 2017.
Data files:
References
  1. [1] H. Sato, “On Machine Tool Vibration,” Monthly J. of the Institute of Industrial Science, University of Tokyo, Vol.24, No.8, pp. 349-357, 1972.
  2. [2] Y. Kondo et al., “Behaviour of the Self-Excited Vibration Considering Multiple Regenerative Effect,” Trans. JSME C, Vol.46, No.409, pp. 1024-1032, 1980.
  3. [3] S. A. Tobias, et al., “The chatter of the lathe tool orthogonal cutting condition,” Trans. ASME J. Eng. Ind., Vol.80, No.5, pp. 1079-1088, 1958.
  4. [4] J. Tlusty, “Dynamics of High-Speed Milling,” Trans. ASME J. Eng. Ind., Vol.108, No.2, pp. 59-67, 1986.
  5. [5] Y. Altintas, et al., “Analytical prediction of stability lobes in milling,” Annals CIRP, Vol.44, No.1, pp. 357-362, 1998.
  6. [6] S. Alan, et al., “Analytical Prediction of Part Dynamics for Machining Stability Analysis,” Int. J. of Automation Technology, Vol.4, No.3, pp. 259-267, 2010.
  7. [7] M. F. Zaeh and O. Roesch, “Improvement of the Static and Dynamic Behavior of a Milling Robot,” Int. J. of Automation Technology, Vol.9, No.2, pp. 129-133, 2015.
  8. [8] A. Ito and E. Shamoto, “An Innovative Machining Strategy for Efficient Peripheral Finishing of Hard Materials with Highly-Varied-Helix End Mill,” Int. J. of Automation Technology, Vol.9, No.2, pp. 153-160, 2015.
  9. [9] N. D. Sims, et al., “Analytical prediction of chatter stability for variable pitch and variable helix milling tools,” J. of Sound and Vibration, Vol.317, pp. 664-686, 2008.
  10. [10] S. Smith, et al., “Stabilizing Chatter by Automatic Spindle Speed Regulation,” Annals CIRP, Vol.41, No.1, pp. 433-436, 1992.
  11. [11] M. Zatarain, et al., “Stability of milling processes with continuous spindle speed variation: Analysis in the frequency and time domains, and experimental correlation,” Annals CIRP, Vol.57, No.1, pp. 379-384, 2008.
  12. [12] A. Ertürk, et al., “Selection of design and operational parameters in spindle–holder–tool assemblies for maximum chatter stability by using a new analytical model,” Annals CIRP, Vol.47, No.9, pp. 1401-1409, 2007.
  13. [13] H. Onozuka, et al., “Optimal Design of a Damped Arbor for Heavy-Duty Machining of Giant Parts,” J. of Advanced Mechanical Design, Systems, and Manufacturing, Vol.7, No.2, pp. 171-186, 2013.
  14. [14] H. Onozuka, et al., “Analysis of Dynamic Behavior of Damped Tool Arbor by Finite Element Method,” J. of Advanced Mechanical Design, Systems, and Manufacturing, Vol.8, No.3 pp. 1401-1409, 2014.
  15. [15] Y. Yang, et al., “Optimization of multiple tuned mass dampers to suppress machine tool chatter,” Int. J. of Machine Tools and Manufacture, Vol.50, No.9, pp. 834-842, 2010.
  16. [16] S. Ema, et al., “Suppression of chatter vibration of boring tools using impact dampers,” Int. J. of Machine Tools and Manufacture, Vol.40, No.8, pp. 1141-1156, 2000.
  17. [17] K. Utsumi, et al., “Study on Design Method of Absorber for Controlling Chatter Vibration in Thin Plate Machining,” J. JSPE, Vol.81, No.2, pp. 187-192, 2015.
  18. [18] K. Kolluru, et al., “A solution for minimising vibrations in milling of thin walled casings by applying dampers to workpiece surface,” Annals CIRP, Vol.62, No.1, pp. 415-418, 2013.
  19. [19] S. Bolsunovsky, et al., “Reduction of Flexible Workpiece Vibrations with Dynamic Support Realized as Tuned Mass Damper,” Procedia CIRP, Vol.8, pp. 230-234, 2013.
  20. [20] K. Seto, “Vibration Control of Multi-Degree of Freedom Systems by Dynamic Absorbers : 2nd Report, On the Design of the Dynamic Absorber by the Transfer Matrix Method,” Trans. JSME C, Vol.50, No.458, pp. 1970-1977, 1984.
  21. [21] K. Seto and S. Yamashita, “Vibration Control of Multi-Degree of Freedom Systems by Dynamic Absorbers : 3rd Report, On the Vibration Control of Γ-Shaped Structure,” Vol.52, No.481, pp. 2318-2325, 1986.

Creative Commons License  This article is published under a Creative Commons Attribution-NoDerivatives 4.0 Internationa License.

*This site is desgined based on HTML5 and CSS3 for modern browsers, e.g. Chrome, Firefox, Safari, Edge, Opera.

Last updated on Dec. 17, 2024