Mechanism of the Formation of Slag Particles by the Rotary Cylinder Atomization

Slag is a potential resource of energy and materials because it contains a lot of elements and is at the high temperature of around 1500°C when exhausted. In the previous study, we developed a rotary cylinder atomizing (RCLA) method that can efficiently use the rotation energy for atomizing the molt...

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Published in:ISIJ International 2010/09/15, Vol.50(9), pp.1252-1258
Main Authors: Kashiwaya, Yoshiaki, In-Nami, Yutaro, Akiyama, Tomohiro
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Language:English
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amorphous slag
mechanism of slag atomizing
rotary cylinder atomizing
slag recycle
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description Slag is a potential resource of energy and materials because it contains a lot of elements and is at the high temperature of around 1500°C when exhausted. In the previous study, we developed a rotary cylinder atomizing (RCLA) method that can efficiently use the rotation energy for atomizing the molten slag. The minimum diameter of the slag particle was from 10 to 50% of the nozzle diameter. The obtained slag particles were amorphous spheres with high aspect ratios. The higher rotation speed and smaller nozzle diameter could make smaller particles. In the present study, the mechanism of slag particle formation from spouting slag string through the nozzle was investigated using the high-speed camera and the theoretical approach was performed. The slag was string-shaped when spouted from the nozzle. The relationship between the particle diameter (d) and nozzle diameter (2a) was derived as follows: [ Equation ] Where ρ is density, L is the distance from the center of rotation to the tip of the slag string, Z is rotation speed and γ is surface tension of slag. The flow rate of slag was evaluated using Hagen–Poiseuille's equation and the relationship between the particle diameter and the slag string diameter was obtained using Weber's equation. By comparison between the experimental and calculated results, we concluded that a string diameter of 0.2 mm for a 1.3mm nozzle diameter was adequate in this experiment.
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In the previous study, we developed a rotary cylinder atomizing (RCLA) method that can efficiently use the rotation energy for atomizing the molten slag. The minimum diameter of the slag particle was from 10 to 50% of the nozzle diameter. The obtained slag particles were amorphous spheres with high aspect ratios. The higher rotation speed and smaller nozzle diameter could make smaller particles. In the present study, the mechanism of slag particle formation from spouting slag string through the nozzle was investigated using the high-speed camera and the theoretical approach was performed. The slag was string-shaped when spouted from the nozzle. The relationship between the particle diameter (d) and nozzle diameter (2a) was derived as follows: [ Equation ] Where ρ is density, L is the distance from the center of rotation to the tip of the slag string, Z is rotation speed and γ is surface tension of slag. The flow rate of slag was evaluated using Hagen–Poiseuille's equation and the relationship between the particle diameter and the slag string diameter was obtained using Weber's equation. 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subjects amorphous slag
mechanism of slag atomizing
rotary cylinder atomizing
slag recycle
title Mechanism of the Formation of Slag Particles by the Rotary Cylinder Atomization
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