Abstract
Silicone rubber mold (SRM) is capable of reducing the cost and time in a new product development phase and has many applications for the pilot runs. Unfortunately, the SRM after injection molding has a poor cooling efficiency due to its low thermal conductivity. To improve the cooling efficiency, the thermal conductivity of the SRM was improved by adding fillers into the SRM. An optimal recipe for fabricating a high cooling efficiency low-pressure injection mold with conformal cooling channel fabricated by fused deposition modeling technology was proposed and implemented. This study proposes a recipe combining 52.6 wt.% aluminum powder, 5.3 wt.% graphite powder, and 42.1 wt.% liquid silicon rubber can be used to make SRM with excellent cooling efficiency. The price–performance ratio of this SRM made by the proposed recipe is around 55. The thermal conductivity of the SRM made by the proposed recipe can be increased by up to 77.6% compared with convention SRM. In addition, the actual cooling time of the injection molded product can be shortened up to 69.1% compared with the conventional SRM. The actual cooling time obtained by the experiment is in good agreement with the simulation results with the relative error rate about 20%.
Highlights
The digital manufacturing technology (DMT) plays an important role in the precision machinery
Three phenomena were found: (a) the thermal conductivity of the silicone rubber mold (SRM) was improved significantly when 80 wt.% Fe powder was added into silicone rubber (SR)
The SRM affected by the coolant is prone to rust when the Fe powder was selected as filler
Summary
The digital manufacturing technology (DMT) plays an important role in the precision machinery. A recipe for fabricating high cooling efficiency SRM was investigated.
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