Abstract
The difficult-to-cut characteristics of silicon carbide (SiC) ceramic has limited its processing quality and forming process of functional surfaces. Comparing to direct laser machining (DLM), waterjet-assisted laser micromachining (WJALM) is an alternative technique for SiC ceramic that is capable of reducing thermal-induced damages. In this paper, high-aspect-ratio (HAR) microchannels are fabricated on silicon carbide ceramic by WJALM, and its effectiveness is verified through comparative experiments with DLM. The effects of parametric combination of waterjet and laser parameters on machining responses of geometric structural features and sidewall surface quality are investigated by controlled variable experiments. Results revealed that HAR microchannels with almost no recast layers could be obtained when SiC workpiece was fabricated by a nanosecond laser under the flowing water medium layer. And higher average laser power of 27W, lower scanning speed of 600m/s and medium waterjet velocity of 12/16m/s contributed to larger aspect ratio, more ablation area and superior sidewall quality of HAR microchannels.