Frontiers of Mechanical Engineering >

2009 , Vol. 4 >Issue 1: 71 - 76

DOI: https://doi.org/10.1007/s11465-009-0010-4

RESEARCH ARTICLE

Five-axis rough machining for impellers

  • Ruolong QI ,
  • Weijun LIU ,
  • Hongyou BIAN ,
  • Lun LI
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  • Laboratory of Advanced Manufacture Technology, Shenyang Institution of Automation, Chinese Academy of Sciences, Shenyang 10016, China

Received date: 30 Jun 2008

Accepted date: 28 Aug 2008

Published date: 05 Mar 2009

Copyright

2014 Higher Education Press and Springer-Verlag Berlin Heidelberg
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Abstract

The most important components used in aerospace, ships, and automobiles are designed with free form surfaces. An impeller is one of the most important components that is difficult to machine because of its twisted blades. Rough machining is recognized as the most crucial procedure influencing machining efficiency and is critical for the finishing process. An integrated rough machining course with detailed algorithms is presented in this paper. An algorithm for determining the minimum distance between two surfaces is applied to estimate the tool size. The space between two blades that will be cleared from the roughcast is divided to generate CC points. The tool axis vector is confirmed based on flank milling using a simple method that could eliminate global interference between the tool and the blades. The result proves that the machining methodology presented in this paper is useful and successful.

Key words: five-axis; impeller; tool-path; planning; flank milling; ruled surface

Cite this article

Ruolong QI , Weijun LIU , Hongyou BIAN , Lun LI . Five-axis rough machining for impellers[J]. Frontiers of Mechanical Engineering, 2009 , 4(1) : 71 -76 . DOI: 10.1007/s11465-009-0010-4

Acknowledgements

This project was supported by the Liaoning Provincial Science and Technology Plan (No. 07L2160201).

References

Publishing order | Descend order by publishing year | Descend order by cited within
1
Young H T, Chuang L C. An integrated machining approach for a centrifugal impeller. Advanced Manufacturing Technology, 2003, 21: 556–63

DOI

2
Wu Pinghan, Li Yuwei. Tool path planning for 5-axis flank milling based on dynamic programming techniques, The International Journal of Advanced Manufacturing Technology,2008, 52(9): 195–00

3
Choi B K, Park J W, Jun C S. Cutter-Location data optimization in 5-axis surface machining. Computer-Aided Design, 1993, 25 (6): 377–86

DOI

4
Li S X, Jerard R B. 5-axis machining of sculptured surfaces with a flat-end cutter. Computer-Aided Design, 1994, 26(3): 165–78

DOI

5
Kim D W, Heo E Y. Machining region division for impeller rough cut considering tool configuration. Journal of the Korean Society of Machine Tool Engineers, 1997, 25(6): 421–22

6
Young H T, Chuang L C, Gerschwiler K. A five-axis rough machining approach for a centrifugal impeller. Advanced Manufacturing Technology, 2004, 23: 233–239

DOI

7
Yu Yuan, Yu Min, Wang Xiaochun. Several-stage tool-path scheduling in 5-axis roughing of impeller. Journal of Xi'an Jiaotong University, 2002, 36(1): 39–42 (in Chinese)

8
Wang Guangkuan, Xi Guang. Machining of 3-d sculptured surface impeller. Journal of Xi'an Jiaotong University, 2005, 39(7): 731–734 (in Chinese)

9
Li Kang, Guo Lianshui. Research on method of 5-axis NC rough machining of turbine blade. ACTA Aeronautica ET Astronautica Sinica, 2006, 27(3): 505–508

10
Gershon E, Russ F. 5-axis freeform surface milling using piecewise ruled surface approximation. Journal of Manufacturing Science and Engineering (USA), 1997, 119(8): 383–387

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