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Abstract

In most of the direct slicing strategies, the deviation between the computer aided design (CAD) model and the built-up part is estimated as the cusp height in normal vertical sections (NVSs) at points all around the slice contour. In the present investigation, the error is also estimated in inclined normal sections (INSs) in an attempt to maximize the slice height and simultaneously obtain a uniform surface roughness of the part. It is found that the number of slices is drastically reduced by the application of the proposed strategy when compared with first-order approximation with error calculation in NVSs. It is also interesting to note that slice height maximization is not necessarily accompanied with any significant, simultaneous reduction in machining time.

Keywords

layered manufacturing (LM)zero-order approximation first-order approximation slicing direct slicing adaptive slicing laminated object manufacturing (LOM)abrasive waterjet cutting (AWJC)

References

Luo

R. C.

A slicing algorithm for rapid prototyping and manufacturing. IEEE International Conference on Robotics and Automn, 1995.

Jamieson

CAD methods in rapid prototyping. In Proceedings of 3rd European Conference on Rapid Prototyping and Manufacturing (Ed. Dickens

P. M.

), The University of Nottingham, Nottingham, July 1994.

Jamieson

Hacker

Direct slicing of CAD model for rapid prototyping. Rapid Prototyping J., 1995, 1(2), 4–12.

Kulkarni

Dutta

An accurate slicing procedure for layered manufacturing. Computer-Aided Des., 1996, 28(9), 683–697.

Hope

R. L.

Jacobs

P. A.

Roth

R. N.

Rapid prototyping with sloping surfaces. Rapid Prototyping J., 1997, 3(1), 12–19.

Hope

R. L.

Jacobs

P. A.

Roth

R. N.

Adaptive slicing with sloping layer surfaces. Rapid Prototyping J., 1997, 3(3), 89–98.

de Jager

P. J.

Broek

J. J.

Vergeest

J. S. M.

A comparison between zero and first order approximation algorithms for layered manufacturing. Rapid Prototyping J., 1997, 3(4), 144–149.

Kumar

Choudbury

A. Roy

Adaptive slicing with cubic patch approximation. Rapid Prototyping J., 2002, 8(4), 224–232.

An adaptive slicing and selective hatching strategy for layered manufacturing. J. Mater, Processing Technol., 1999, 89-90, 191–197.

10.

Choi

S. H.

Samavedam

Modeling and optimization of rapid prototyping. Computers in Industry, 2002, 47, 39–53.

11.

Y.-T.

Walczyk

D. F.

Development of a computer-aided manufacturing system for profiled edge lamination tooling. Trans. ASME, J. Mfg Sci. Engng, August 2002, 124, 754–761.

12.

Rogers

D. F.

Adams

J. A.

Mathematical Elements for Computer Graphics, 1990 (McGraw-Hill, New York).

13.

Choi

B. K.

Surface Modeling for CAD-CAM, 1991 (Elsevier).

14.

Ohadi

M. M.

Cheng

K. L.

Modeling of temperature distribution in the work piece during abrasive water jet machining. J. Heat Transfer, 1993, 115, 446–452.

15.

Walczyk

D. F.

Hardt

D. E.

Rapid tooling for sheet metal forming using profiled edge laminationsâdesign principles and demonstration. J. Mfg Sci. Engng, 1998, 120, 746–754.

16.

Wang

Wong

W. C. K.

A study of abrasive waterjet cutting of metallic coated sheet steels. Int. J. Mach. Tools Mf., 1999, 39, 855–870.

17.

Louis

Abrasive water jets: A review. In 5th Pacific Rim International Conference on Water Jet Technology, New Delhi, India, 3–5 February 1998, pp. 321–329.

18.

Hoogstrate

A. M.

van Luttervelt

C. A.

Opportunities in abrasive waterjet machining. Ann. CIRP, 1997, 46(2), 697–714.

19.

Hoogstrate

A. M.

Towards high definition abrasive water jet cutting. Doctoral dissertation, TU Delft, The Netherlands, 2000.

20.

Paul

Hoogstrate

A. M.

van Praag

Abrasive water jet machining of glass fibre metal laminate. Proc. Instn Mech. Engrs, Part B: J. Engineering Manufacture, 2002, 216(B11), 1459–1469.

21.

Chen

Siores

Wong

W. C. K.

Kerf characteristics in abrasive waterjet cutting of ceramic materials. Int. J. Mach. Tool Mf., 1996, 36(11), 1201–1206.

Maximization of slice height with uniformity in surface roughness in the direct slicing of freeform surfaces

Abstract

Abstract

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References