CFD Modeling and Cold Physical Model Simulation on Single Molten Slag Ligament Disintegration into Droplets

• Published in: Minerals (Basel) Vol. 13; no. 2; p. 139
• Main Authors: Zhao, Ming, Pan, Yuhua, Zhao, Aifu, Zhang, Shili, Ma, Ping, Feng, Xin
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.01.2023
• Subjects: Analysis; Blast furnace slags; Boundary conditions; Breakup; Centrifugal force; centrifugal granulation of molten slag; CFD numerical simulation; Cold; cold physical model simulation; Diameters; Disintegration; droplet; Droplets; Energy; Free surfaces; Granulation; Gravity; Inertia; Ligaments; liquid ligament; Liquid paraffins; Liquids; Mathematical models; Multiphase flow; Numerical analysis; Paraffin; Partial differential equations; Physical properties; Rayleigh Disintegration Mechanism; Simulation; Simulation methods; Slag; Surface tension; Temperature; Three dimensional models; Turbulence models; Two phase flow; Viscosity; Water
• ISSN: 2075-163X; 2075-163X
• DOI: 10.3390/min13020139

Aiming at the mode of liquid ligament disintegration into droplets in the process of the centrifugal granulation of molten blast furnace slag using a spinning cup, in order to gain an in-depth understanding of the behavior and mechanism of droplet formation by liquid ligament disintegration and to obtain appropriate conditions to control the size of the produced slag granules, a three-dimensional CFD model describing water–air two-phase flow with a free surface was established in this work for simulating the process of a single water ligament breakup into droplets under the action of gravity, surface tension and inertial forces, so as to compare with the process of a molten slag ligament disintegration into droplets due to centrifugal force exerted by the spinning cup. By studying the disintegration behavior and mechanism of a single water ligament, the similar phenomenon of a molten slag ligament disintegration is examined. The numerical simulation results on the breakup of a single water ligament show that the length of the ligament before its disintegration and the diameter of the droplets formed both increase with the increase of the velocity of the ligament initially exiting a capillary nozzle. In addition, an experimental set-up was established in the laboratory to conduct cold physical model simulation experiments on single water or liquid paraffin ligament disintegration. The experimental results are compared with the numerical simulation results so that the reliability of the CFD model is verified. The results of the present study show that, in the centrifugal granulation process of blast furnace slag using a spinning cup operated in the ligament disintegration mode, the breakup of a single molten slag ligament is very similar to that of a single water or liquid paraffin ligament, and both approximately follow the Rayleigh Disintegration Mechanism, which provides a theoretical basis for analyzing the breakup process of the ligaments of different liquids as references for guiding the operation of centrifugal granulation of molten slag.