Generating High-Accuracy Tool Path for 5-axis Flank Milling of Globoidal Spatial Cam
A new tool path planning method for 5-axis flank
milling of a globoidal indexing cam is developed in this paper. The
globoidal indexing cam is a practical transmission mechanism due
to its high transmission speed, accuracy and dynamic performance.
Machining the cam profile is a complex and precise task. The profile
surface of the globoidal cam is generated by the conjugate contact
motion of the roller. The generated complex profile surface is usually
machined by 5-axis point-milling method. The point-milling method
is time-consuming compared with flank milling. The tool path for
5-axis flank milling of globoidal cam is developed to improve the
cutting efficiency. The flank milling tool path is globally optimized
according to the minimum zone criterion, and high accuracy is
guaranteed. The computational example and cutting simulation finally
validate the developed method.
[1] H Y Chen and H Pottmann. Approximation by ruled surfaces. Journal of
Computational and Applied Mathematics, 1999, 102(1): 143-156.
[2] Liu X W. Five-axis NC cylindrical milling of sculptured surfaces.
Computer-Aided Design, 1995, 27(12): 887-894.
[3] Bohez E L J, Senadhera S D R, Pole K, Duflou J R, Tar T. A geometric
modeling and five-axis machining algorithm for centrifugal impellers.
Journal of Manufacturing Systems, 1997, 16(6): 422-436.
[4] Tsay D M, Her M J. Accurate 5-axis machining of twisted ruled surfaces.
Trans. Of ASME, Journal of Manufacturing Science and Engineering,
2001, 123(4): 731-738
[5] Rubio W, Lagarrigue P, Dessein G, Pastor F. Calculation of tool paths for
a torus mill on free-form surfaces on five-axis machines with detection
and elimination of interference. The International Journal of Advanced
Manufacturing Technology, 1998, 14(1): 13-20.
[6] Redonnet J M, Rubio W, Dessein G. Side milling of ruled surfaces:
Optimum positioning of the milling cutter and calculation of interference.
The International Journal of Advanced Manufacturing Technology, 1998,
14(7): 459-465.
[7] Bedi S, Mann S, Menzel C. Flank milling with flat end milling cutters.
Computer-Aided Design, 2003, 35(3):293-300.
[8] Tsay D M, Her M J. Accurate 5-axis machining of twisted ruled surfaces.
Trans. of ASME, Journal of Manufacturing Science and Engineering,
2001, 123(4): 731-738.
[9] Li C G, Bedi S, Mann S. Flank milling of ruled surface with conical
tools - an optimization approach. The International Journal of Advanced
Manufacturing Technology, 2006, 29(11-12): 1115-1124.
[10] Rong S L, Chen H S. Tool path generation and error control method for
multi-axis nc machining of spatial cam. International Journal of Machine
Tools and Manufacture, 1998, 38 (4) : 277-290
[11] Lee J N, Lee R S. Interference-free toolpath generation using enveloping
element for five-axis machining of spatial cam. Journal of Materials
Processing Technology, 2007, 187-188:10-13
[12] Rong S L, Jeng N L. New method of tool orientation determination by
enveloping element for fiveaxis machining of spatial cam. International
Journal of Production Research, 2002, 40 (10) , :2379-2398
[13] Grant B, Soni A H. Survey of cam manufacture methods. J Mech Des
Trans ASME ,1979,101(3): 455-464
[14] Der M T, Hsien M W. A general approach to the determination of planar
and spatial cam profiles. Journal of Mechanical Design, 1996,118(2):259-
265.
[15] Tsay D M, Ho HC. Consideration of manufacturing parameters in the
design of grooved globoidal cam indexing mechanisms. Proceedings of
the Institution of Mechanical Engineers, Part C: Journal of Mechanical
Engineering Science, 2001, 215 (1) : 95-103.
[16] Kong M, Hu Z H, Li H, et al. Cutter Location Optimization Algorithm
for One-side NC Machining of Globoidal Cams Based on Equidistant
Surfaces. Chinese Journal of Mechanical engineering. 2008, 44(11):277-
282.
[1] H Y Chen and H Pottmann. Approximation by ruled surfaces. Journal of
Computational and Applied Mathematics, 1999, 102(1): 143-156.
[2] Liu X W. Five-axis NC cylindrical milling of sculptured surfaces.
Computer-Aided Design, 1995, 27(12): 887-894.
[3] Bohez E L J, Senadhera S D R, Pole K, Duflou J R, Tar T. A geometric
modeling and five-axis machining algorithm for centrifugal impellers.
Journal of Manufacturing Systems, 1997, 16(6): 422-436.
[4] Tsay D M, Her M J. Accurate 5-axis machining of twisted ruled surfaces.
Trans. Of ASME, Journal of Manufacturing Science and Engineering,
2001, 123(4): 731-738
[5] Rubio W, Lagarrigue P, Dessein G, Pastor F. Calculation of tool paths for
a torus mill on free-form surfaces on five-axis machines with detection
and elimination of interference. The International Journal of Advanced
Manufacturing Technology, 1998, 14(1): 13-20.
[6] Redonnet J M, Rubio W, Dessein G. Side milling of ruled surfaces:
Optimum positioning of the milling cutter and calculation of interference.
The International Journal of Advanced Manufacturing Technology, 1998,
14(7): 459-465.
[7] Bedi S, Mann S, Menzel C. Flank milling with flat end milling cutters.
Computer-Aided Design, 2003, 35(3):293-300.
[8] Tsay D M, Her M J. Accurate 5-axis machining of twisted ruled surfaces.
Trans. of ASME, Journal of Manufacturing Science and Engineering,
2001, 123(4): 731-738.
[9] Li C G, Bedi S, Mann S. Flank milling of ruled surface with conical
tools - an optimization approach. The International Journal of Advanced
Manufacturing Technology, 2006, 29(11-12): 1115-1124.
[10] Rong S L, Chen H S. Tool path generation and error control method for
multi-axis nc machining of spatial cam. International Journal of Machine
Tools and Manufacture, 1998, 38 (4) : 277-290
[11] Lee J N, Lee R S. Interference-free toolpath generation using enveloping
element for five-axis machining of spatial cam. Journal of Materials
Processing Technology, 2007, 187-188:10-13
[12] Rong S L, Jeng N L. New method of tool orientation determination by
enveloping element for fiveaxis machining of spatial cam. International
Journal of Production Research, 2002, 40 (10) , :2379-2398
[13] Grant B, Soni A H. Survey of cam manufacture methods. J Mech Des
Trans ASME ,1979,101(3): 455-464
[14] Der M T, Hsien M W. A general approach to the determination of planar
and spatial cam profiles. Journal of Mechanical Design, 1996,118(2):259-
265.
[15] Tsay D M, Ho HC. Consideration of manufacturing parameters in the
design of grooved globoidal cam indexing mechanisms. Proceedings of
the Institution of Mechanical Engineers, Part C: Journal of Mechanical
Engineering Science, 2001, 215 (1) : 95-103.
[16] Kong M, Hu Z H, Li H, et al. Cutter Location Optimization Algorithm
for One-side NC Machining of Globoidal Cams Based on Equidistant
Surfaces. Chinese Journal of Mechanical engineering. 2008, 44(11):277-
282.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:63681", author = "Li Chen and ZhouLong Li and Qing-zhen Bi and LiMin Zhu", title = "Generating High-Accuracy Tool Path for 5-axis Flank Milling of Globoidal Spatial Cam", abstract = "A new tool path planning method for 5-axis flank
milling of a globoidal indexing cam is developed in this paper. The
globoidal indexing cam is a practical transmission mechanism due
to its high transmission speed, accuracy and dynamic performance.
Machining the cam profile is a complex and precise task. The profile
surface of the globoidal cam is generated by the conjugate contact
motion of the roller. The generated complex profile surface is usually
machined by 5-axis point-milling method. The point-milling method
is time-consuming compared with flank milling. The tool path for
5-axis flank milling of globoidal cam is developed to improve the
cutting efficiency. The flank milling tool path is globally optimized
according to the minimum zone criterion, and high accuracy is
guaranteed. The computational example and cutting simulation finally
validate the developed method.", keywords = "Globoidal cam, flank milling, LSQR, MINIMAX.", volume = "6", number = "12", pages = "2852-8", }
