Abstract
This study investigates the applicability and advantages of using additive manufacturing to moderate heat generation in dry milling. Grinding medium balls of different sizes were designed and fabricated using computer-aided design (CAD) and a stereolithographic 3D printer. Milling processes with particle size distribution and warmup measurements were employed with the printed medium balls. The results were compared with the measurements executed with conventional stainless-steel balls. Differential scanning calorimetry (DSC) was employed to evaluate the effect of the warmup of the system during the milling process. A two-variable, three-level experimental design was used for the measurements. We selected two grinding parameters considered critical: speed and time. The effect of these two independent variables on heating was examined. The results show that if printed balls are applied with the same total mass as that of metal balls, the particle size reduction is increased. The greater the number of balls used, the greater the particle size reduction. In this process, where additively manufactured milling bodies were used, the temperature of the system increased by less than when stainless-steel balls were used. The use of 3D-printed medium balls demonstrated beneficial warmup behavior.