Fluid catalytic cracking (FCC) riser reactors have complex hydrodynamics, which depend not only on operating conditions, feedstock quality, and catalyst particles characteristics, but also on the geometric configurations of the reactor. This paper presents a numerical study of the influence of different riser outlet designs on the dynamic of the flow and reactor efficiency. A three-dimensional, three-phase flow model and a four-lump kinetic scheme were used to predict the performance of the reactor. The phenomenon of vaporization of the liquid oil droplets was also analyzed. Results showed that small changes in the outlet configuration had a significant effect on the flow patterns and consequently, on the reaction yields.
Particle deposition in the human lungs is mainly influenced by the fluid dynamics and the particle properties, such as the size and the deposition mechanisms. A three-dimensional gas particle flow model to predict particle deposition and flow patterns in four generations of the human lung, located in the bronchial region, is presented in this paper. Four breathing conditions (sleep, resting, moderate activity, and intense activity) were simulated, using the commercial code ANSYS Fluent ® version 14.5. The particle diameter was varied from 1 to 10 μm. The results showed that deposition in each of the three bifurcations was not uniform and should be analyzed separately based on particle diameter. The influence of gravitational settling and Brownian diffusion on particle deposition was also investigated and quantified. The greater difference in the deposition between cases considering these physical mechanisms and not considering it occurred in situations involving lower velocity, showing a value of 172 % for gravitational settling mechanism and a difference of 11 % for Brownian diffusion. Furthermore, it was observed that the total deposition increased with the Reynolds and Stokes numbers, suggesting that exercise practices should be avoided in situations with high levels of suspended particulate matter.
-Respiratory diseases have received increasing attention in recent decades. Airway bifurcations are difficult regions to study, and computational fluid dynamics (CFD) offers an alternative way of evaluating the behavior of pharmaceutical aerosols used in the treatment of respiratory disorders. In this work, particle deposition was analyzed using a three-dimensional model with four ramifications (three bifurcations), under different respiratory conditions: inhalation, exhalation, and breath holding. The main aim of the work was to verify the medical recommendation to hold one's breath during a few seconds after inhaling pharmaceutical aerosols, rather than exhaling immediately after the inhalation. The deposition of particles with 5 µm diameter was considered. The results showed that the number of aerosols collected on the airway walls was higher for the situation of breath holding, which supported the medical recommendation.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.