Effect of the Slag Composition and a Protective Atmosphere on Chemical Reactions and Non‐Metallic Inclusions during Electro‐Slag Remelting of a Hot‐Work Tool Steel

Schneider, Reinhold; Molnar, Manuel; Gelder, Siegfried; Reiter, Gerhard; Martínez, Carlos

doi:10.1002/srin.201800161

Cited by 28 publications

(24 citation statements)

References 19 publications

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“…However, there are controversial findings on whether the oxygen content in the remelted ingot is dependent on the original oxygen content of the steel electrode or not. 1,14,16,18,20,[38][39][40][41][42][43][44] Plöckinger 1) claimed that the oxygen content level was dependent only on the reactions between slag and liquid steel, and not concerned with the initial oxygen content of steel electrode. In recent decades, the oxygen content in the steel used as the electrode for ESR could be reduced to a low level because of the improvement of steelmaking technologies.…”

Section: Initial Oxygen Content Of Steel Electrodementioning

confidence: 99%

“…A low initial oxygen content of the steel electrode (13 ppm) was reduced to 8 ppm-12 ppm after open air atmosphere ESR in the case where the FeO content in the slag was at a low level (0.1-0.2 mass%). 43) It is really a tough case to lower the oxygen content to a lower level after ESR of low oxygen steel. In order to further lower the oxygen during ESR of the steel with low oxygen content, the strategic point is to prevent the oxygen pickup during the ESR process, in which the oxygen potential of slag is the key source.…”

Section: Initial Oxygen Content Of Steel Electrodementioning

confidence: 99%

“…In general, a majority of the original oxide inclusions in the steel electrode are removed during the ESR process, especially a preferential elimination of large inclusions. 6,43,44) Apart from some types of original oxide inclusions in the steel electrode (for example, MnO-SiO 2 -Al 2 O 3 inclusions 45) ), other types of the original oxide inclusions could partially survive from the steel electrode to ESR ingot. 46,47) The factors, which affect the oxide inclusion evolution during ESR, greatly influence the oxygen content of ESR ingot.…”

Section: Oxide Inclusions In Steel Electrodementioning

confidence: 99%

“…The ESR practice conducted in open air atmosphere normally leads to higher FeO content in the slag than the remelting in protective atmosphere, 43) which results in a higher oxygen content of liquid steel. For protective atmosphere ESR, inert gas is introduced into the gas protective cap of protective atmosphere ESR equipment to protect the remelting atmosphere against the surrounding air.…”

Section: Remelting Atmospherementioning

confidence: 99%

“…The laboratory-scale ESR trials with a frequency of 4.5 Hz show that even though the ESR trials of the low oxygen steel electrode are performed in open air atmosphere, the oxygen content is reduced, instead increased, from 13 ppm in the steel electrode to 8 ppm-12 ppm in the ingots of 165 mm in diameter because of a low FeO content in the slag (0.1-0.2 mass%). 43) Continuous or periodic addition of deoxidizing agents into the slag pool is widely used for deoxidation of ESR. 4,5,7,8,12,38,[74][75][76] The main function of deoxidizing agents addition during the ESR process is to reduce the concentration of FeO in the slag.…”

Section: Deoxidation Schemes Of Esrmentioning

confidence: 99%

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Deoxidation of Electroslag Remelting (ESR) – A Review

Shi

2020

ISIJ Int.

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Deoxidation of liquid steel and alloy during electroslag remelting (ESR) is always an ongoing concern for producing advanced clean steel and alloy. The increasing demands for more excellent performance of steel urge metallurgists to further improve the steel cleanliness. Lowering the oxygen content and nonmetallic inclusions amount during the ESR process is of great importance as ESR is the last processing procedure for refining liquid steel in the steel product manufacturing process. Deoxidation of ESR is dependent on one or more aspects including the initial oxygen content and oxide inclusions in the electrode, remelting atmosphere, deoxidation schemes, slag compositions, reoxidation degree, melting rate and filling ratio. This paper reviews the state of the art in the deoxidation of ESR and deoxidation-related oxide inclusions. The oxygen transfer behavior during ESR process is described first. Deoxidation of liquid steel during ESR is discussed based on the thermodynamic and kinetic considerations. The dependence of the oxygen on the processing parameters of ESR is reviewed and discussed. The influence of these parameters on the oxide inclusions associated with the deoxidation of ESR is also assessed. The suggestions for the future work are proposed in this article.

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Section: Initial Oxygen Content Of Steel Electrodementioning

confidence: 99%

Section: Initial Oxygen Content Of Steel Electrodementioning

confidence: 99%

Section: Oxide Inclusions In Steel Electrodementioning

confidence: 99%

Section: Remelting Atmospherementioning

confidence: 99%

Section: Deoxidation Schemes Of Esrmentioning

confidence: 99%

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Deoxidation of Electroslag Remelting (ESR) – A Review

Shi

2020

ISIJ Int.

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Effect of the Al₂O₃ Content in the Slag on the Remelting Behavior of a Bearing Steel

Schneider

Molnar

Klösch

et al. 2020

steel research int.

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The service life of roller bearings strongly depends on nonmetallic inclusions (NMIs). Therefore, these steels request highest metallurgical standards in their production. To determine the effect of the Al2O3 content and a protective atmosphere (N2) on the electroslag remelting (ESR) behavior, laboratory scale experiments are conducted. Changes in the composition of the remelted materials and in the slag are determined. In addition, the amount and composition of the NMI prior and after remelting are investigated, and thermodynamic simulations on the formation of NMI are conducted. Changes in the chemical composition can largely be explained by well‐known equilibrium reactions between the slag and the metal. Lowest Al contents in the remelted steel can only be achieved with the Al2O3‐free slag. Higher Al2O3 contents in the slag lead to higher oxygen and sulfur contents in the steel and corresponding higher amounts of NMI after remelting. The use of a protective gas mainly reduced the loss of Si and led to lower O and S contents after remelting with the Al2O3‐free slag. The composition of the NMI changed from alumina type to MgO–Al2O3 (MA)‐spinel type and finally mixed MgO–SiO2 oxides with decreasing Al2O3 contents. These results are confirmed by thermodynamic calculations.

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

Schneider

Wiesinger

Gelder

et al. 2022

steel research int.

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Electroslag remelting (ESR) is a well-established secondary refining process for many steels and Ni-base alloys with highest requirements regarding material properties. The main purposes are a dense solidification of ingots with a low degree of segregation as well as the reduction of medium-sized and especially complete removal of large nonmetallic inclusions (NMI). The specific energy consumption of ESR is documented in the range from 880 to over 2000 kWh t À1 . [1][2][3][4][5][6][7] Rising requirements regarding sustainability, emission control, and environmental protection have triggered new awareness for this topic. [4,8,9] Besides plant geometry and design, the customarily CaF 2 -based slag plays the key role in the heat generation and energy consumption of ESR. Key properties are the melting point as well as the electrical and thermal conductivity. [2,10] Other factors such as fill ratio and the amount of slag, or the melt rate can also have a strong effect. [4,8,[11][12][13][14][15][16] According to Holzgruber, [16] rising fill ratios up to 0.4 lead to a reduction in specific energy consumption due to a better heat transfer into the electrode and less radiation losses at the free slag surface. A further increase in fill ratio surprisingly resulted in a reversed trend due to changing immersion depths. Results from Li et al., [14] both laboratory scale and industrial size, demonstrate the strong effects of fill ratio (0.24 and 0.6) and electrical conductivity on the specific energy consumption with values below 1000 kWh t À1 at higher fill ratios combined with low or no CaF 2 -containing slags. CaF 2 -free slags in Brückmann and Schwerdtfeger [17] confirmed their particular advantage in specific energy consumption with values below 1000 kWh t À1 .There are only few reports of systematic research on energy consumption in ESR on the industrial scale. A recent investigation with a wider variation of slags is documented in refs. [5][6][7], and confirms an almost linear increase with electrical conductivity. A similar but less pronounced increase is reported in Jäger and Kühnelt [18] for slag composition with a wide variety of CaF 2 contents and a significantly higher fill ratio. A recent summary on the different effects of the fill ratio and the electrical conductivity on the specific energy consumption can be found in Schneider et al., [4] indicating that the energy consumption data from laboratory scale

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Effect of the Slag Composition and a Protective Atmosphere on Chemical Reactions and Non‐Metallic Inclusions during Electro‐Slag Remelting of a Hot‐Work Tool Steel

Cited by 28 publications

References 19 publications

Deoxidation of Electroslag Remelting (ESR) – A Review

Deoxidation of Electroslag Remelting (ESR) – A Review

Effect of the Al₂O₃ Content in the Slag on the Remelting Behavior of a Bearing Steel

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

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Effect of the Slag Composition and a Protective Atmosphere on Chemical Reactions and Non‐Metallic Inclusions during Electro‐Slag Remelting of a Hot‐Work Tool Steel

Cited by 28 publications

References 19 publications

Deoxidation of Electroslag Remelting (ESR) – A Review

Deoxidation of Electroslag Remelting (ESR) – A Review

Effect of the Al2O3 Content in the Slag on the Remelting Behavior of a Bearing Steel

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

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Product

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Effect of the Al₂O₃ Content in the Slag on the Remelting Behavior of a Bearing Steel