The goal of fabricating functional prototypes quickly is hindered by a mismatch of material properties between production materials and those used in rapid prototyping (RP) machines, such as stereolithography. Even when rapid tooling (RT) technologies are utilized for injection molded parts, differences in mold materials cause differences in molded part properties. To compensate for these material and process differences, a design for manufacturing (DFM) method is introduced, called geometric tailoring. The idea is to modify dimensions of prototype parts to match key characteristics of production parts, such as stress and deflection behaviors. For RP parts, the geometric tailoring DFM method integrates two sub-problems, one for achieving functional requirements by matching part behaviors, and one for RP process planning to incorporate manufacturing capabilities and limitations. For parts fabricated by RT, an additional sub-problem is integrated, namely injection molding process planning. Problem decomposition is critical due to the coupled nature of the sub-problems. A problem decomposition and solution procedure is presented. The geometric tailoring method is shown to enable the matching of prototype to production part behaviors, while improving manufacturability.

Issue Section:
Technical Papers
Keywords:
design for manufacture, process planning, injection moulding, rapid prototyping (industrial)
Topics:
Design, Design for Manufacturing, Dimensions, Engineering prototypes, Geometry, Manufacturing, Materials properties, Production planning, Rapid prototyping, Rapid tooling, Stress, Machinery, Injection molding, Young's modulus, Finishes, Weight (Mass), Displacement, Tensile strength
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 by ASME
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