Abstract
A combined in-mold decoration and microcellular injection molding (IMD/MIM) method by integrating in-mold decoration injection molding (IMD) with microcellular injection molding (MIM) was proposed in this paper. To verify the effectiveness of the IMD/MIM method, comparisons of in-mold decoration injection molding (IMD), conventional injection molding (CIM), IMD/MIM and microcellular injection molding (MIM) simulations and experiments were performed. The results show that compared with MIM, the film flattens the bubbles that have not been cooled and turned to the surface, thus improving the surface quality of the parts. The existence of the film results in an asymmetrical temperature distribution along the thickness of the sample, and the higher temperature on the film side leads the cell to move toward it, thus obtaining a cell-offset part. However, the mechanical properties of the IMD/MIM splines are degraded due to the presence of cells, while specific mechanical properties similar to their solid counterparts are maintained. Besides, the existence of the film reduces the heat transfer coefficient of the film side so that the sides of the part are cooled asymmetrically, causing warpage.
Highlights
Microcellular injection molding (MIM) technology originated from the idea of Nam Suh [1].Compared with conventional injection molding (CIM), it has some advantages including weight reduction, cost saving, and excellent dimensional stability [2,3,4,5]
The IMD, CIM, in-mold decoration and microcellular injection molding (IMD/microcellular injection molding (MIM)) and MIM experiments were carried out using an injection molding machine
The result is consistent with that of the surface topography, so it can be concluded that the IMD/MIM method does improve surface quality of the foamed samples, which plays a significant role in the promotion and application of microcellular injection molding technology
Summary
Wei Guo 1,2,3 , Qing Yang 1,2,3 , Huajie Mao 2,3,4, *, Zhenghua Meng 1,2,3, *, Lin Hua 1,2,3 and Bo He 2,3,4. Hubei Collaborative Innovation Center for Automotive Components Technology, Wuhan 430070, China
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