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Abstract

Increasing the efficiency of rough machining operations can produce significant productivity improvement in mould and die making because most of the metal is removed in the roughing stage. In this paper, a high-efficiency 2.5-dimensional rough milling strategy for mould core machining is presented. The strategy consists of three different tool paths. The first tool path is generated on the basis of the convex hull boundary of a machining region. Owing to the absence of concave tool path segments, the convex hull based tool path can eliminate the chip load fluctuation problem encountered in corner cutting. The second tool path is an enhanced unidirectional straight-line tool path, which has the virtue of maintaining a steady cutting resistance throughout. The large staircases left behind by these two tool paths are refined by using the third tool path which is a contour-parallel tool path that cuts the mould core layer by layer in an upward manner. After applying these three tool paths, the stock material left on the mould core surface can be post-processed by the subsequent finish milling operation. A case study is illustrated to demonstrate the practicality of the presented rough milling strategy.

Keywords

high-efficiency machining tool path planning cornering cut convex hull rough milling

References

Fallbohmer

Rodriguez

C. A.

Ozel

Altan

High-speed machining of cast iron and alloy steels for die and mold manufacturing. J. Mater. Processing Technol., 2000, 98, 104–115.

Taylan

Blaine

Yen

Y. C.

Manufacturing of dies and molds (keynote paper). Ann. CIRP, 2001, 50(2), 405–423.

Merchant

M. E.

Mechanics of the cutting process I. J. Appl. Phys., 1945, 16, 267–275.

Lee

E. H.

Shaffer

B. W.

Theory of plasticity applied to the problem of machining. J. Appl. Mechanics, 1951, 18, 405–413.

Tlusty

MacNeil

Dynamics of cutting forces in end milling. Ann. CIRP, 1975, 24(1), 21–25.

Kline

W. A.

Devor

R. E.

Lindberg

J. R.

The prediction of cutting forces in end milling with application to cornering cuts. Int. J. Mach. Tool Des. Res., 1982, 22, 7–22.

Tlusty

Smith

Zamudio

New NC routines for quality in milling. Ann. CIRP, 1990, 39(1), 517–521.

Kramer

T. R.

Pocket milling with tool engagement detection. J. Mfg Syst., 1992, 11(2), 114–123.

Smith

Tlusty

Current trends in high-speed machining. Trans. ASME, J. Mfg Sci. Engng, 1997, 119, 664–666.

10.

Wang

W. P.

Solid modeling for optimizing metal removal of three-dimensional NC end milling. J. Mfg Syst., 1988, 7(1), 57–65.

11.

Altinas

Spence

End milling force algorithms for CAD systems. Ann. CIRP, 1991, 40(1), 31–34.

12.

Schulz

Bimschas

Optimization of precision machining by simulation of the cutting process. Ann. CIRP, 1993, 42(1), 55–58.

13.

Tarng

Y. S.

Shyur

Y. Y.

Lee

B. Y.

Computer-aided generation of the cutting conditions in pocket machining. J. Mater. Processing Technol., 1995, 51, 223–234.

14.

Choi

B. K.

Kim

B. H.

Die-cavity pocketing via cutting simulation. Computer-Aided Des., 1997, 29(12), 837–846.

15.

Liang

S. Y.

Cutting force analysis in transient state milling processes. Int. J. Advd Mfg Technol., 1999, 15, 785–790.

16.

Fussell

B. K.

Jerard

R. B.

Hemmett

J. G.

Robust feed-rate selection for 3-axis NC machining using discrete models. Trans. ASME, J. Mfg Sci. Engng, 2001, 123, 214–224.

17.

Smith

Tlusty

An overview of modeling and simulation of the milling process. Trans. ASME, J. Engng for Industry, 1991, 113, 160–175.

18.

Smith

Tlusty

Update on high-speed milling dynamics. Trans. ASME, J. Engng for Industry, May 1990, 112, 142–149.

19.

Davies

M. A.

Dutterer

Pratt

J. R.

Schaut

A. J.

On the dynamics of high-speed milling with long, slender endmills. Ann. CIRP, 1998, 47(1), 55–60.

20.

Jerard

Fussell

B. K.

Ercan

M. T.

Hemmett

J. G.

Integration of geometric and mechanistic models of NC machining into an open-architecture machine tool controller. In Proceedings of ASME International Mechanical Engineering Congress and Exposition, 5–10 November 2000, pp. 1–8.

21.

Iwabe

Fujii

Y. K.

Saito

Kishinami

Study on corner cut by end millâanalysis of cutting mechanism and new cutting method at inside corner (in Japanese). J. Jap. Soc. Precision Engng, 1989, 55(5), 841–846.

22.

Tsai

M. D.

Takata

Inui

Kimura

Sata

Operation planning based on cutting process models. Ann. CIRP, 1991, 40(1), 95–98.

23.

Hansen

Arbab

An algorithm for generating NC tool paths for arbitrarily shaped pockets with island. ACM Trans. Graphics, 1992, 11(2), 152–182.

24.

Jeong

Kim

Generating tool paths for free-form pocket machining using Z-buffer-based Voronoi diagrams. Int. J. Advd Mfg Technol., 1999, 15, 182–187.

25.

Choi

B. K.

Park

S. C.

A pair-wise offset algorithm for 2D point-sequence curve. Computer-Aided Des., 1999, 31, 735, 745.

26.

Stori

J. A.

Wright

P. K.

Constant engagement tool-path generation for convex geometries. J. Mfg Syst., 2000, 19(3), 172–184.

27.

Yuen

M. F.

Tan

S. T.

Sze

W. S.

Wong

W. Y.

An octree approach to rough machining. Proc. Instn Mech. Engrs, Part B: J. Engineering Manufacture, 1987, 201(B3), 157–163.

28.

Chuang

S. H.

Pan

C. C.

Rough cut tool path planning for B-spline surfaces using convex hull boxes. Int. J. Advd Mfg Technol., 1998, 14, 85–92.

29.

Lin

A. C.

Gian

A multiple-tool approach to rough machining of sculptured surfaces. Int. J. Advd Mfg Technol., 1999, 15, 387–398.

30.

Day

A. M.

The implementation of an algorithm to find the convex hull of a set of three-dimensional points. ACM Trans. Graphics, 1990, 9(1), 105–132.

31.

Barber

C. B.

Dobkin

D. P.

Huhdanpaa

The quickhull algorithm for convex hulls. ACM Trans. Math. Software, 1996, 22(4), 469–483.

32.

Jarvis

R. A.

On the identification of the convex hull of a finite set in the plane. Information Processing Lett., 1973, 1(1), 18–21.

33.

Yue

Murray

J. L.

Corney

J. R.

Clark

D. E. R.

Convex hull of a planar set of straight and circular line segments. Engng Computations, 1999, 16(8), 858–875.

A high-efficiency rough milling strategy for mould core machining

Abstract

Abstract

Keywords

References