Effect of impregnated phenolic resin on the properties of Si-SiC ceramic matrix composites fabricated by SLS-RMI

Selective laser sintering (SLS) combined with reaction melt infiltration was used to fabricate Si-SiC ceramic matrix composites, and the effects of different concentrations of phenolic resin (PF) on the properties of the SLS green body and carbonized and final Si-SiC samples were investigated. The results showed that the impregnation with PF can increase the bulk density, reduce the porosity of the samples at all stages, and improve the me-chanical properties of the reactive bonded samples. The degree of densification and mechanical properties of the sample gradually enhanced with an increase in PF concentration. The main phases of the Si-SiC composites were free Si, alpha-SiC, beta-SiC, plus an extremely small amount of Al-Si alloy, and the SiC and the Si phase contents increased and decreased, respectively, as the concentration of PF increased when measured using Rietveld refinement and image analysis software. The macroscopic properties of the samples improved greatly after precursor infiltration pyrolysis (PIP) treatment with 66.7%vol PF-ethanol solution twice. According to the crystal nucleation-growth theory, it was inferred that the infiltrated PF could provide a certain amount of pyrolytic carbon in the carbonized specimen. During the reaction bonded process, the carbon formed by carbonization pyrolysis first dissolves into the molten Si and reaches saturation. With the further dissolution of carbon, [C] and [Si] in the liquid phase contact each other to form beta-SiC nuclei, the nuclei that precipitate at the pore wall position and gradually form a continuous interfacial layer of beta-SiC. The beta-SiC layer prevents the liquid Si from direct contact with C inside the prefabricated body, therefore, further reactants diffuse through the layer. Finally, the fine crystalline beta-SiC grains were fabricated inside the specimen.

Automated summary

Selective laser sintering (SLS) combined with reaction melt infiltration was used to fabricate Si-SiC ceramic matrix composites. The impregnation with phenolic resin (PF) improved the density, reduced the porosity, and enhanced the mechanical properties of the samples. The concentration of PF had an effect on the phases and content of SiC and Si in the composites. Precursor infiltration pyrolysis (PIP) treatment greatly improved the macroscopic properties of the samples. The formation of beta-SiC grains inside the specimen was achieved through a reaction bonded process.