Erosion behavior of SiC–WC composites

Abstract

Dense silicon carbide (SiC) ceramics were prepared with 0, 10, 30 or 50wt% WC particles by hot pressing powder mixtures of SiC, WC and oxide additives at 1800°C for 1h under a pressure of 40MPa in an Ar atmosphere. Effects of alumina or SiC erodent particles and the WC content on the erosion performance of sintered SiC–WC composites were assessed. Microstructures of the sintered composites consisted of WC particles distributed in the equi-axed grain structure of SiC. Fracture surfaces showed a mixed mode of fracture, with a large extent of transgranular fracture observed in SiC ceramics prepared with 30wt% WC. Crack bridging by WC enhanced toughening of the SiC ceramics. A maximum fracture toughness of 6.7 MPa*m1/2 was observed for the SiC ceramics with 50wt% WC, whereas a high hardness of 26GPa was obtained for the SiC ceramics with 30wt% WC. When eroded at normal incidence, two orders of magnitude less erosion occurred when SiC–WC composites were eroded by alumina particles than that eroded by SiC particles. The erosion rate of the composites increased with increasing angle of SiC particle impingement from 30° to 90°, and decreased with WC reinforcement up to 30wt%. A minimum erosion wear rate of 6.6mm3/kg was obtained for SiC–30wt% WC composites. Effects of mechanical properties and microstructure on erosion of the sintered SiC–WC composites are discussed, and the dominant wear mechanisms are also elucidated.