论文信息 - Determining fabrication orientations for rapid prototyping with Stereolithography apparatus

Determining fabrication orientations for rapid prototyping with Stereolithography apparatus

Abstract Traditionally, prototypes are built manually by skilled workers with the help of machine tools, which is very time consuming. The advent of rapid prototyping technology greatly eases the effort required for making prototypes. In this research we investigate geometric issues involved while using a particular rapid prototyping system, called Stereolithography Apparatus (SLA). SLA creates prototypes layer by layer, each layer being formed (solidified) by scanning a laser beam across the x-y surface of a vat of liquid monomer mix. In contrast to traditional methods, the planning of prototyping with SLA is done directly with the computer models of designed parts and requires little experience. The performance of SLA is influenced by the orientation in which a design is fabricated. For example, sloped surfaces produced by the SLA process inherently have an undesirable stepped surface texture. Such surface texture can, however, be reduced by orienting as many faces as possible vertically or horizontally. This prompts us to establish decision criteria and develop algorithms—based on the considerations of surface quality, build time, and the complexity of support structure—for identifying desirable fabrication orientations for a given design.

Shuo-Yan Chou | Douglas D. Gemmill | Lin-Lin Chen | Po-Ting Lan

[1] Godfried T. Toussaint,et al. Feasability of Design in Stereolithography , 1993, FSTTCS.

[2] Godfried T. Toussaint,et al. Computing the Width of a Set , 1988, IEEE Trans. Pattern Anal. Mach. Intell..

[3] Scott Odette. Complex Prototype Assemblies from Stereolithography and RTV Tooling , 1992 .

[4] J. H. Dripps,et al. Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society , 1989 .

[5] T. Renault,et al. Photolithography for composites manufacturing: Continuous glass fiber/polyacrylate composites , 1991 .

[6] Leonidas J. Guibas,et al. Computing convolutions by reciprocal search , 1986, SCG '86.

[7] Xiaoming Chen,et al. Computer Aided Prosthetic And Surgical Rehabilitation Of The Ear , 1991, Proceedings of the Annual International Conference of the IEEE Engineering in Medicine and Biology Society Volume 13: 1991.

[8] Alan S. Brown. Rapid prototyping - Parts without tools , 1991 .

[9] Fritz B. Prinz,et al. Rapid Prototyping of Tools , 1989 .

[10] Prosenjit Bose,et al. Feasibility of Design in Stereolithography , 1997, Algorithmica.

[11] Kevin Q. Brown. Geometric transforms for fast geometric algorithms , 1979 .

[12] F. P. Preparata,et al. Convex hulls of finite sets of points in two and three dimensions , 1977, CACM.

[13] S. W. Thomas. Stereolithography simplifies tooling for reinforced rubber parts , 1992 .