Zein, a subproduct of the food industry and a protein, possesses limited applications due to its high hydrophobic character. The objective of this research was to investigate the influence of homogenization pressure and cycles on the volumetric mean diameter (D4,3), span values, and Turbiscan Stability Index (TSI) using the response surface methodology for microfluidized emulsions containing zein as a unique stabilizer. Results showed that homogenization pressure seems to be the most influential parameter to obtain enhanced physical stability and droplet size distributions, with the optimum being 20,000 psi. Interestingly, the optimum number of cycles for volumetric diameter, span value, and TSI is not the same. Although a decrease of D4,3 with number of cycles is observed (optimum three cycles), this provokes an increase of span values (optimum one cycle) due to the recoalescence effect. Since physical stability is influenced by D4,3 and span, the minimum for TSI is observed at the middle level of the cycles (2 cycles). This work highlights that not only volumetric diameter, but also span value must be taken into consideration in order to obtain stable zein emulsions. In addition, this study wants to extend the limited knowledge about zein-based emulsions processed with a Microfluidizer device.
The desulfurization rate in a Peirce-Smith converter (which works as a well-mixed reactor) was obtained during the copper blow. Conversion data of the copper sulfide as a function of the operation time were correlated distinguishing between two kinetic steps; in both cases, the conversion was proportional to time. The variation of the matte temperature was not influential, so the chemical resistance in the bulk of the melt can be considered negligible. The variation in the global volumetric coefficient deduced from the experimental data was justified by a model having two resistances to mass transfer, the gas-side resistance being constant and the liquidside resistance increasing when the sulfide concentration decreased.
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