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Researchers Prepare Silicon Carbide-Polymer Composite Materials for SLS 3D Printing https://ift.tt/2Dcf75B Silicon carbide, or SiC, has a lot of potential for use in industrial applications, like aeronautic and aerospace engineering, the automotive industry, and the machinery industry, due to its excellent physical and chemical properties. But, because of the high production costs that come with mold manufacturing, machining, and high temperature and pressure sintering processes, this industrial use is rather limited. Selective laser sintering (SLS) 3D printing could be used to help lower these costs, and a collaborative team of Chinese researchers from the Southern University of Science and Technology, Southeast University, and the Harbin Institute of Technology recently published a paper, titled “Development of SiC/PVB Composite Powders for Selective Laser Sintering Additive Manufacturing of SiC,” that explains how they prepared SiC-polymer composites with good dispersity and flowability, using a ball milling method, for SLS 3D printing. By combining multiple materials into a composite material, completed components can benefit from the respective strengths of each material.
There are two approaches to manufacturing ceramic parts using SLS technology: direct and indirect. For this study, the researchers created their composite powder materials, using polyvinyl butyral (PVB) as a binder in order to investigate its effect on the powders’ surface modification, for indirect SLS processing.
As many commercial ceramic powders have irregular morphology and poor flowability, they’re not great for use in 3D printing. So the most important step of indirect SLS processing is the actual production of the polymer-ceramic composite powder agglomerates. The team combined PVB, polyvinylpyrrolidone (PVP), and commercial SiC powder with anhydrous alcohol, and then ball milled the mixture at 120 rpm for 12 hours. The resulting powders were sieved through a 120 mesh screen, before a Concept Laser M2 was used to complete the composite’s preliminary spreading and forming tests. The composite powder’s laser absorptivity was studied, and scanning electron microscopy (SEM) was used to examine the granulated particles’ morphology and microstructure, while X-ray diffraction identified the phase composition of the composite powders, laser diffraction measured the size of the agglomerates, and the materials’ UV-Vis analysis was also tested. The researchers successfully prepared subsphaeroidal SiC/polymer composite granules, complete with good flowability, for SLS 3D printing, and added PVB binder to include surface modification. They investigated the effects of PVB on the distributions, flowability, shapes, and sizes of polymer-ceramic composite powder agglomerates, and determined some important information. First, the added PVB has an optimal value (~3 wt. %), and the SiC granules modified with this material showed good spreading performance and flowability. In addition, when the wavelength is below 500 nm, the composite powder had good laser absorptivity, which suggests that using SLS 3D printing to fabricate the material could work with systems of a corresponding wavelength.
Co-authors of the paper are Peng Zhou, Huilin Qi, Zhenye Zhu, Huang Qin, Hui Li, Chenglin Chu, and Ming Yan. Discuss this research and other 3D printing topics at 3DPrintBoard.com or share your thoughts in the Facebook comments below. Printing via 3DPrint.com | The Voice of 3D Printing / Additive Manufacturing https://3dprint.com October 30, 2018 at 04:15AM
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