Abstract
A transient coupled mathematical model has been proposed to predict the motion and distribution of nonmetallic inclusions in the electroslag remelting process. The electromagnetic field, temperature distribution, flow pattern, solidification, and inclusion behavior were solved simultaneously. The Euler-Lagrange approach was used to describe the interaction between continuous phase and inclusions. The discrete phase model (DPM) was adopted to track the particles acted by a number of forces. An experiment under argon protection was implemented, and it agrees well with the simulation. The effect of inclusion diameter was also discussed. The experiment result shows that the typical inclusions in final ingot are Al2O3 core surrounded by an outer sulfide layer and pure MnS inclusions. The total area of inclusions increases from center toward ingot surface, while the average equivalent diameter decreases. The simulated result indicates a denser distribution of inclusions locations at the region ranging from 0.7 to 0.9 radii. Few inclusions are entrapped near the mold due to the strong descending flow. Moreover, the inclusion amount increases with height. The total amounts of inclusions with diameter of 2 μm, 5 μm, and 10 μm in ingot are 2199, 1871, and 1704, respectively. The imposed buoyancy and floatation contribute to this phenomenon.
Highlights
Nonmetallic inclusions in steel cause serious defects and affect the mechanical properties of final ingots negatively [1]
The results show that TiN inclusion is found content of in slag leads to a lower ingot due to the
The results indicate that the one with 1 Hz alternating current (AC) power supply has a better the type and content of non-metallic inclusions in Electroslag remelting (ESR) ingots [8]
Summary
Nonmetallic inclusions in steel cause serious defects and affect the mechanical properties of final ingots negatively [1]. The molten slag is electrically heated by an alternating current (AC) to melt the consumable electrode in the ESR process under argon protection. There are two main sources of nonmetallic inclusions in ESR ingots, one is the original inclusion of the electrode and the other is the newly precipitated inclusion at the solidification front during the solidification. The former is supposed to be mainly removed at the liquid metal film and the growing droplet on the electrode tip through washing out mechanically and dissolution [4]. A further reduction of original inclusions is found during the falling of metal droplet, despite of the very short time about
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