Návrh replikované výroby zvoleného dílu za využití technologie Reverse engineering a Rapid prototyping / Design of replicated production of the selected part using the technology Reverse Engineering and Rapid prototyping

Horňák, Matúš

January 2020

This diploma thesis in theoretical part describes methods of Reverse engineering and Rapid prototyping. Each method describes its characteristics, pros and cons and usability. Practical part deals with application of these methods on part of a ledge of Škoda 1000 MB, digitalization of object, creating a new volume model, analyzing its dimensions and geometry using deviation analysis, creating prototype, choosing suitable manufacturing technology and technical-economical aspects.

Effects of Conformal Cooling Channels on Additively Manufactured Injection Molding Tooling

Whatcott, Tyler Blaine

08 December 2020

This study focuses on the cycle-averaged mold temperature of additively manufactured injection molding tooling and how it is affected by conformal cooling channels. This was done by producing a benchmark mold out of Digital ABS produced by Stratasys, an acrylic based photopolymer, which was then used to produce injection molded parts until tool failure. Another, more cost-effective material, High Temp Resin produced by Formlabs, another acrylic based photopolymer, was also tested but yielded very little success. Then the mold design was altered by adding conformal cooling channels and again tested by producing injection molded parts while tracking the mold temperature. This experimentation was then compared to an injection molding cooling channel model in order to validate the model for use with additively manufactured tooling with conformal cooling channels for use in injection molding. The benchmark Digital ABS mold was able to produce 66 shots in the injection molding machine before complete mold failure. The Digital ABS mold had a cycle-averaged mold temperature of about 155°F. The High Temp Resin mold was able to produce 3 shots before complete mold failure. The High Temp Resin material is much more brittle, and the mold design did not take into account how brittle the material was. The Digital ABS mold with conformal cooling channels had a cycle-averaged mold temperature of 111°F. This is significantly lower than without cooling channels and has a high potential for improving tooling life. The cooling channel model predicted the cycle-averaged mold temperature to be 116°F. This proved to be a very good model and can be used as a design tool when choosing cooling channel geometry and position in additively manufactured tooling. This research shows the potential that conformal cooling channels have to help improve additively manufactured tooling life for injection molding. As shown in other research done, the ability to maintain the mold below 120°F significantly improves the life of additively manufactured tooling. The results of this study demonstrate the effectiveness of conformal cooling channels in controlling mold temperature. It should be researched further, but the use of conformal cooling channels has the potential to produce more production or prototype parts with additively manufactured tooling for injection molding.

additive manufacturing

injection molding

rapid prototyping

soft tooling

conformal cooling channels

tooling life

Engineering