Effect of nanobubbles on powder morphology in the spray drying process
Abstract
This study investigated the influence of gas-injected nanobubbles on the morphology of particles during spray drying under various experimental conditions. The nanoparticle tracking system was used to measure the generation, size, and concentration of nanobubbles. Experiments were conducted at different temperatures (160 degrees C-260 degrees C) and feed rates (0.2-0.26 g/s) to examine the effect of nanobubbles on spray drying and present diverse results. The deionized (DI) water with generated nanobubbles had a particle concentration of 1.8 x 10(8) particles/mL and a mean particle size of 242.6 nm, which was similar to 3.31 x 10(7) particles/mL higher untreated DI water. The maltodextrin solution containing nanobubbles also showed a significant increase in particle generation, with a concentration of 1.62 x 10(9) particles/mL. The viscosity of the maltodextrin solution containing nanobubbles decreased by similar to 18%, from 9.3 mPas to 7.5 mPas. Overall, the size of the generated particles was similar regardless of nanobubble treatment, but there was a tendency for particle size to increase under specific temperature (260 degrees C) and feed flow rate (0.32 g/s) conditions. Furthermore, it was observed that the Hausner ratio significantly varied with increasing temperature and feed flow rate, and these results were explained through scanning electron microscopy images. These findings confirm that the gas nanobubbles mixed in the feed can exert diverse effects on the spray drying system and powder characteristics depending on the operating conditions. This study suggests that nanobubbles can contribute to a more efficient process in spray drying and can influence the morphological characteristics of particles depending on the spray drying conditions.
