Effect of the Slag Composition on the Process Behavior, Energy Consumption, and Nonmetallic Inclusions during Electroslag Remelting

Electroslag remelting (ESR) is an important process to produce high‐quality tool steels. The slag composition has a strong effect on the remelting behavior, particularly on energy consumption and the removal of nonmetallic inclusions (NMI). The latter aspect is strongly related to chemical reactions...

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Veröffentlicht in:	Steel research international 2023-04, Vol.94 (4), p.n/a
Hauptverfasser:	Schneider, Reinhold, Wiesinger, Valentin, Gelder, Siegfried, Reiter, Gerhard
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Sprache:	eng
Schlagworte:	Aluminum oxide Chemical analysis Chemical reactions Composition Electrical resistivity Electroslag remelting Energy consumption Melting Metallurgical analysis Nonmetallic inclusions Slag slag compositions Specific energy Tool steels
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description	Electroslag remelting (ESR) is an important process to produce high‐quality tool steels. The slag composition has a strong effect on the remelting behavior, particularly on energy consumption and the removal of nonmetallic inclusions (NMI). The latter aspect is strongly related to chemical reactions between the slag and the metal and determines the necessary composition of the slag. Also, the electrical conductivity of the slag is determined by the slag composition, and a high resistivity is desirable. The effect of different slag compositions with 0%–60% CaF2 and a corresponding wide range of electrical conductivities is investigated regarding slag movement, slag surface temperature, and slag skin thickness, as well as their impact on chemical reactions and the removal of NMI. Therefore, a laboratory‐scale ESR unit and the plastic mold steel X40Cr14 are used for the experimental trials. The results show a strong impact on the remelting behavior as well as on the specific energy consumption ranging from ≈900 to over 1700 kWh h−1. The findings from the chemical analysis and detection of NMI indicate that a similar metallurgical behavior is feasible, leading to comparable amounts of dominantly Al2O3–MgO‐type inclusions with some variation due to different activities in the slag. The focus of this investigation is to determine the effect of a wide variation of the CaF2 content in the slag on energy consumption, as well as on nonmetallic inclusion during electroslag remelting. The results indicate the potential to use slags with higher resistivity without significant losses in product quality.
doi_str_mv	10.1002/srin.202200483
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The findings from the chemical analysis and detection of NMI indicate that a similar metallurgical behavior is feasible, leading to comparable amounts of dominantly Al2O3–MgO‐type inclusions with some variation due to different activities in the slag. The focus of this investigation is to determine the effect of a wide variation of the CaF2 content in the slag on energy consumption, as well as on nonmetallic inclusion during electroslag remelting. 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subjects	Aluminum oxide Chemical analysis Chemical reactions Composition Electrical resistivity Electroslag remelting Energy consumption Melting Metallurgical analysis Nonmetallic inclusions Slag slag compositions Specific energy Tool steels
title	Effect of the Slag Composition on the Process Behavior, Energy Consumption, and Nonmetallic Inclusions during Electroslag Remelting
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