Authors: YaoAn Lu, QingZhen Bi, BaoRui Du, ShuLin Chen, LiMin Zhu, Kai Huang

Abstract:

Taking the design tolerance into account, this paper presents a novel efficient approach to generate iso-scallop tool path for five-axis strip machining with a barrel cutter. The cutter location is first determined on the scallop surface instead of the design surface, and then the cutter is adjusted to locate the optimal tool position based on the differential rotation of the tool axis and satisfies the design tolerance simultaneously. The machining strip width and error are calculated with the aid of the grazing curve of the cutter. Based on the proposed tool positioning algorithm, the tool paths are generated by keeping the scallop height formed by adjacent tool paths constant. An example is conducted to confirm the validity of the proposed method.

Keywords: Strip machining, barrel cutter, iso-scallop tool path, sculptured surfaces, differential motion.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1337984

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2478

References:

[1] Mullins S, Jensen C, Anderson D (1993) Scallop elimination based on precise 5-axis tool placement, orientation, and step-over calculations. ASME Adv Des Autom 65:535-544.
[2] Jensen C, Anderson D (1993) Accurate tool placement and orientation for finish surface machining. Journal of Design and Manufacturing 59:127-127
[3] Rao N, Ismail F, Bedi S (1997) Tool path planning for five-axis machining using the principal axis method. International Journal of Machine Tools and Manufacture 37 (7):1025-1040
[4] Bedi S, Gravelle S, Chen Y (1997) Principal curvature alignment technique for machining complex surfaces. Journal of manufacturing science and engineering 119 (4B):756-765
[5] Rao N, Bedi S, Buchal R (1996) Implementation of the principal-axis method for machining of complex surfaces. The International Journal of Advanced Manufacturing Technology 11 (4):249-257
[6] Wang X, Wu X, Li Y (1992) Curvature catering—a new concept for machining sculptured surfaces. Journal of Xi’an Jiaotong University 26 (5):51-58
[7] Gong H, Cao LX, Liu J (2008) Second order approximation of tool envelope surface for 5-axis machining with single point contact. Computer-Aided Design 40 (5):604-615
[8] Zhu LM, Ding H, Xiong YL (2010) Third-order point contact approach for five-axis sculptured surface machining using non-ball-end tools (I): Third-order approximation of tool envelope surface. SCIENCE CHINA Technological Sciences 53 (7):1904-1912
[9] Zhu LM, Ding H, Xiong YL (2010) Third-order point contact approach for five-axis sculptured surface machining using non-ball-end tools (II): Tool positioning strategy. SCIENCE CHINA Technological Sciences 53 (8):2190-2197
[10] Warkentin A, Ismail F, Bedi S (2000) Multi-point tool positioning strategy for 5-axis mashining of sculptured surfaces. Computer Aided Geometric Design 17 (1):83-100
[11] Warkentin A, Ismail F, Bedi S (2000) Comparison between multi-point and other 5-axis tool positioning strategies. International Journal of Machine Tools and Manufacture 40 (2):185-208
[12] Gray P, Bedi S, Ismail F (2003) Rolling ball method for 5-axis surface machining. Computer-Aided Design 35 (4):347-357
[13] Gray PJ, Bedi S, Ismail F (2005) Arc-intersect method for 5-axis tool positioning. Computer-Aided Design 37 (7):663-674
[14] Zhang H (1987) The developing trend of sculptured surface machining in increasing the strip width and decrease the scallop height. Surface Machining and Checking
[15] Wang D, Chen WY, Li T, Xu RF (2009) Five-Axis Flank Milling of Sculptured Surface with Barrel Cutters. Key Engineering Materials 407-408:292-297
[16] Lee YS (1998) Non-isoparametric tool path planning by machining strip evaluation for 5-axis sculptured surface machining. Computer-Aided Design 30 (7):559-570
[17] Fard MJB, Feng H-Y (2009) Effect of tool tilt angle on machining strip width in five-axis flat-end milling of free-form surfaces. The International Journal of Advanced Manufacturing Technology 44 (3-4):211-222
[18] Chiou C-J, Lee Y-S (2002) Swept surface determination for five-axis numerical control machining. International Journal of Machine Tools and Manufacture 42 (14):1497-1507
[19] Chiou JCJ, Lee YS (2005) Optimal tool orientation for five-axis tool-end machining by swept envelope approach. Journal of manufacturing science and engineering 127 (4):810-818
[20] Zhu LM, Zhang XM, Zheng G, Ding H (2009) Analytical expression of the swept surface of a rotary cutter using the envelope theory of sphere congruence. Journal of manufacturing science and engineering 131 (4):0410171-0410177
[21] Lin Z, Fu J, Shen H, Gan W (2014) A generic uniform scallop tool path generation method for five-axis machining of freeform surface. Computer-Aided Design 56:120-132
[22] Xu J, Zhang S, Tan J, Liu X (2012) Non-redundant tool trajectory generation for surface finish machining based on geodesic curvature matching. The International Journal of Advanced Manufacturing Technology 62 (9-12):1169-1178
[23] Zhu LM, Zhang XM, Ding H, Xiong YL (2010) Geometry of signed point-to-surface distance function and its application to surface approximation. Journal of computing and information science in engineering 10 (4):0410031-04100310