本研究是對邱士軒教授實驗室研究團隊過去所研發之新型面成型快速原型系統進行改善，透過面成型快速原型系統的機構設計研發出改良型面成型快速原型系統。邱士軒教授實驗室研究團隊過去所研發之新型面成型快速原型系統使用兩組攪拌裝置的供料槽控制添加物的分散性，而每次實驗至少需消耗4000ml的原料，且機台是屬於半自動的供料方式，清理機台也較耗時。
為了克服這樣的問題，本研究以一組攪拌裝置，以及自動回抽餘料的方式，改善了實驗需消耗大量原料的問題，改善後的面成型快速原型系統，實驗時只需要300ml的原料，且機台供料方式為自動化系統，也大幅縮短清理機台的時間。
最後，本研究將光硬化樹脂添加銅粉製作出快速模具，並利用材料機械性質試驗、材料熱性質試驗、材料表面分析試驗、3D元件製作等實驗進行系統改善的驗證與分析，以落實本研究之目標。

The purpose of this research is to develop an improved photo-mask rapid prototyping system based on novel photo-mask rapid prototyping system which is made by Professor Chiu’s research team in the past. The system utilizes mixing tank with two stirrers to control the dispersibility of additives. Each experiment needs to consume 4000ml of raw materials. Besides, the system is half-automated, so it spends more time to clean after doing the experiments.
In order to overcome the problem, this research utilizes mixing tank with one stirrers and automated system. After improvement, the feeder system is automated and it only needs 300ml of raw materials for consumption.
Finally, the improved system made rapid tooling with copper/photo-resin composite materials. In order to optimization, the process parameters are adjusted by the experiments which consist of the mechanical properties, thermal properties, morphology analysis and 3D component production.

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