JP7167646B2 - Method of adding alloy to molten steel - Google Patents

Description

The present invention relates to a method for adding alloy to molten steel, and more particularly to a method for adding alloy to molten steel, in which a metal wire is continuously supplied to molten steel in a tundish when the molten steel is continuously cast through the tundish. It is about.

In the continuous casting of molten steel, the molten steel is refined to adjust the composition and placed in a ladle, transferred from the ladle to a tundish, and further poured from the tundish into a mold to form a slab. Continuous casting is performed by

The steel composition is basically adjusted at the molten steel stage in the ladle. Patent Literature 1 describes a method of adding Ca wire to molten steel. Further, if necessary, a wire-shaped metal is continuously supplied to the molten steel in the tundish to adjust the composition of the molten steel in the tundish. In addition to Ti, when adding components such as Si, Mn, C, and Cr, wires made of these metals are prepared and supplied to the molten steel in the tundish. When adding easily oxidizable metals such as Ca, Mg, and Al, a wire coated with iron on these metals or metal powders is prepared and supplied to the molten steel in the tundish.

The temperature of the molten steel supplied from the tundish to the mold is a very important factor in continuous casting because it greatly affects the stability of operation and the quality of slabs. When the molten steel contained in the ladle is continuously cast through the tundish, the temperature of the molten steel decreases from the beginning to the end of the supply from the ladle. To do so, it is effective to heat the molten steel in the tundish. Also, since the molten steel temperature varies from ladle to ladle, it is effective to heat the molten steel in the tundish when the actual ladle molten steel temperature is low. Plasma heating is effectively used as means for heating molten steel in a tundish. Patent Documents 2 and 3 disclose methods of heating molten steel in a tundish using plasma heating. In Patent Document 3, a heating chamber is defined by a side wall portion provided on a lid portion of a tundish, a cylindrical graphite electrode is arranged in the upper portion of the heating chamber, and a hollow portion of the graphite electrode serves as a gas flow path. forming A tundish with a capacity of 30 tons is used, and the flow rate of Ar gas supplied to the gas flow path is set at 400 NL/min.

Further, Patent Document 4 discloses a method of spraying an equiaxed crystallization accelerator onto molten steel in a tundish using a working gas of a plasma heating device. Patent Literature 5 discloses a method of adding Mg wire into the tundish through the hollow portion of a hollow carbon electrode for plasma heating while plasma-heating molten steel in the tundish.

In order to prevent reoxidation of the molten steel in the tundish, the tundish was covered with a lid to block it from the outside air as much as possible, and Ar gas was supplied into the tundish to purge the atmosphere inside the tundish with Ar. (Non-Patent Document 1).

JP 2016-023342 A JP 2015-199083 A JP 2018-034180 A Japanese Patent Application Laid-Open No. 2001-225153 JP 2016-198787 A

Iron and Steel Handbook, 5th Edition, Volume 1, Ironmaking and Steelmaking, p.440

When an alloy component of molten steel is added to the molten steel in the tundish as a metal wire, if the metal to be added is a highly oxidizing metal such as Ti, oxygen in the atmosphere in the tundish immediately before entering the molten steel will cause the wire to break. The surface metal is oxidized to form a metal oxide, which is a factor in lowering the yield of alloy addition as a metal component. Moreover, since the produced metal oxide penetrates into the molten steel, the quality of the cast slab may be deteriorated depending on the metal composition. If the metal wire is coated with iron, oxidation can be suppressed, but iron coating should be avoided because it causes an increase in cost. Furthermore, when adding highly oxidizing Ca or the like, an iron-coated wire is used, but even if iron coating is performed, oxidation loss of Ca cannot be avoided.

As described above, the tundish is provided with a lid to be shielded from the outside air as much as possible, and Ar gas is supplied into the tundish to purge the atmosphere in the tundish with Ar. In order to ensure workability, it is difficult to have a completely closed structure, and it is difficult to make the atmosphere in the tundish sufficiently non-oxidizing with ordinary Ar purge.

The present invention uses a tundish that has a degree of airtightness that is normally used, and when adding an alloy component of molten steel as a metal wire to the molten steel in the tundish, a problem occurs due to oxidation of the metal wire to be added. It is an object of the present invention to provide a method for adding an alloy to molten steel without causing

As described above, when a tundish having a degree of airtightness that is normally used is used, even if the atmosphere in the tundish is purged with Ar, as has been done conventionally, the molten steel in the tundish will not be affected. Oxidation of the supplied metal wire could not be sufficiently prevented. On the other hand, by greatly increasing the amount of Ar gas supplied into the tundish compared with the conventional one, the atmosphere in the tundish can be made sufficiently non-oxidizing, and the metal addition yield in the tundish can be improved. was found to be adequately secured.

On the other hand, it has also been found that increasing the amount of Ar blown into the tundish significantly lowers the molten steel temperature in the tundish. Plasma heating of the molten steel in the tundish can compensate for the drop in molten steel temperature. However, if the degree of temperature drop due to Ar blowing exceeds the temperature compensation range in plasma heating, the molten steel temperature cannot be maintained. In the present invention, it is clarified that there is an Ar blowing amount range within the temperature compensation range by plasma heating while sufficiently securing the metal addition yield as the Ar blowing amount range into the tundish. did.

The present invention has been made based on the above findings, and the gist thereof is
When continuously casting molten steel via a tundish,
Ar gas is supplied into the tundish, and the Ar gas supply rate per tundish internal volume V (m ³ ) is 600 to 3700 NL/min/m ³ ,
Plasma heating is applied to the molten steel in the tundish,
A method for adding an alloy to molten steel, characterized by adding an alloy to the molten steel by continuously supplying an alloy wire into the molten steel in a tundish.
Here, the internal volume V of the tundish means the volume of the space from the surface of the molten steel to the upper lid where the molten steel does not enter when the tundish receives the molten steel.

In the present invention, when continuously casting molten steel via a tundish, Ar gas is supplied into the tundish, and the Ar gas supply rate per tundish internal volume V (m ³ ) is 600 to 3700 NL/min/m. As ³ , the molten steel in the tundish is plasma-heated, and an alloy wire is continuously supplied to the molten steel in the tundish to add alloy to the molten steel. The addition yield can be increased, and the heat loss due to the Ar gas supply can be sufficiently compensated for by plasma heating while the surface properties of the cast slab are improved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows the continuous casting apparatus which applies this invention. It is a figure which shows the influence of Ar gas supply rate in a simulated tundish experiment, (A) is a molten steel temperature drop amount on a vertical axis|shaft, (B) is an addition Ti yield on a vertical axis|shaft. It is a figure which shows the influence of Ar gas supply speed|velocity|rate in an actual machine continuous casting apparatus, (A) is a molten-steel temperature drop amount on a vertical axis|shaft, (B) is an addition Ti yield on a vertical axis|shaft.

A simulated tundish capable of containing 4.8 tons of molten steel was prepared. The tundish has an internal volume V of 0.449 m ³ and has a lid. The refractory lining of the tundish and the lid imitates the structure of the tundish and lid for continuous casting which are usually used, and the airtightness is the same as that of the usual continuous casting tundish. However, the contained molten steel will not be cast continuously.
A metal wire feeder was installed to continuously feed the metal wire to the molten steel in the tundish. A metal Ti wire with a diameter of 5 mm was used as a wire for addition. When the wire is added to 4.8 tons of molten steel at a feed rate of 100 mm/sec with a yield of 100%, the Ti concentration in the molten steel can be increased to 0.05% by mass after 5 minutes.
The tundish is equipped with a plasma heating device that heats the molten steel in the tundish. A graphite electrode is used as the electrode. The plasma heating apparatus has a maximum heating capacity of 4000A, 300V, and the ability to raise the temperature of 4.8 tons of molten steel by 60°C in 5 minutes.
An Ar gas supply device for blowing Ar gas into the tundish is arranged. The Ar gas supply rate per tundish internal volume V (m ³ ) can be adjusted in the range of 0 to 4013 NL/min/m ³ .

First, 4.8 tons of molten steel having the composition shown in Table 1 and having a predetermined temperature was placed in a tundish without supplying a metal wire and without plasma heating, with a flow rate of 0 to 4013 NL/min/m ³ . A test was conducted in which only Ar gas was supplied at an Ar gas supply rate within the range for 5 minutes, and the amount of molten steel temperature decrease (°C) during 5 minutes was evaluated. The results are shown in FIG. 2(A). The horizontal axis of FIG. 2A is the Ar gas supply rate per tundish internal volume V (m ³ ), and the vertical axis is the molten steel temperature drop. It was found that the molten steel temperature decrease amount increased as the Ar gas supply rate increased.

Next, 4.8 tons of molten steel having the same composition and temperature is placed in a tundish, plasma heating is performed, and a metal Ti wire of φ5 mm is supplied at a supply rate of 100 mm / sec, while supplying 0 to 4013 NL / min / m A test was conducted in which Ar gas was supplied at an Ar gas supply rate within the range of ³ for 5 minutes. Since heat is taken from the molten steel by wire supply and Ar gas supply, the plasma heating output was adjusted so as to keep the molten steel temperature constant. However ^, if the Ar gas supply rate is too high, the temperature cannot be compensated by plasma heating, and the molten steel temperature will drop after 5 minutes. , the temperature can be compensated by plasma heating.

As described above, the metal Ti wire was supplied into the molten steel for 5 minutes, the molten steel sample was collected, and the solid solution Ti amount in the molten steel sample was analyzed. The Ti addition yield was calculated from the ratio of the increase in solid solution Ti amount to the added Ti amount. The results are shown in FIG. 2(B). The horizontal axis of FIG. 2B is the Ar gas supply rate per tundish internal volume V (m ³ ), and the vertical axis is the Ti yield. While the Ti yield remained at 70% when no Ar gas was supplied ^, the Ti yield improved as the Ar gas supply rate increased. , the Ti yield was found to be 80% or more. If the Ti yield is less than 80%, the alloy cost increases, and inclusions increase to cause slab cracking, which is not desirable.

From the above results, when continuously supplying an alloy wire (especially an alloy wire of a metal that is easily oxidized such as Ti, Ca, Mg, Al, etc.) into the molten steel in the tundish, Ar gas is supplied into the tundish. Then, by setting the Ar gas supply rate per tundish internal volume V (m ³ ) to 600 to 3700 NL/min/m ³ , while maintaining the addition yield of the wire-added alloy at a high value, Ar gas supply It has been found that the lost heat of the molten steel can be compensated for by plasma heating.

Next, the effect of the present invention was confirmed using an actual continuous casting apparatus as shown in FIG.
The amount of molten steel in the ladle 5 is 300t. The tundish 1 has an internal volume of 2.96 m ³ , a molten steel capacity of 30 t, and a lid 9 . The refractory lining of the tundish 1 and the lid 9 has the structure of the tundish 1 for continuous casting and the lid 9 which are normally used, and the airtightness is the same as that of the tundish for normal continuous casting. The molten steel in the ladle 5 is transferred to the tundish 1 via the long nozzle 6, and the molten steel in the tundish is injected via the submerged nozzle 8 into the 1-strand mold 7, casting at 1.0 m/min. Cast at speed. The throughput of the molten steel 12 is 2.5t/min.

A metal wire feeder 3 for continuously feeding a metal wire 11 to the molten steel in the tundish was arranged. A metal Ti wire with a diameter of 12 mm was used as the metal wire for addition. During continuous casting of molten steel at a throughput of 2.5 t/min, when the wire is added at a feed rate of 40 mm/sec with a yield of 100%, the Ti concentration in the molten steel can be increased to 0.05% by mass. At the start of casting, the wire was fed into the tundish at a feed rate of 100 mm/sec for 5 minutes before starting casting, and then molten steel transfer from the ladle to the tundish was started. As a result, when the amount of molten steel in the tundish reaches 30 tons, the Ti concentration in the molten steel can be made 0.05% by mass.

The tundish is provided with a plasma heating device 4 for heating molten steel in the tundish. A graphite electrode is used as the electrode. The maximum heating capacity of the plasma heating device 4 is 4000A, 300V, and has the capacity to raise the molten steel temperature by 23.0°C during continuous casting with a throughput of 2.5t/min.

An Ar gas supply device 2 for blowing Ar gas into the tundish is arranged. The Ar gas supply rate per tundish internal volume V (m ³ ) can be adjusted in the range of 0 to 4054 NL/min/m ³ .

First, molten steel having the components shown in Table 1 was continuously cast at a throughput of 2.5 t/min, and in a steady state, Ar gas was supplied into the tundish at an Ar gas rate of 0 to 4054 NL/min/m ³ . supplied. After 5 minutes from the start of supply, the amount of decrease in molten steel temperature compared to before the start of Ar supply was measured. The results are shown in Table 2 and FIG. 3(A). The horizontal axis of FIG. 3A is the Ar gas supply rate per tundish internal volume V (m ³ ), and the vertical axis is the molten steel temperature drop. As in the experiment using the simulated tundish described above, it was found that the molten steel temperature decrease amount increased as the Ar gas supply rate increased.

Next, when continuously casting molten steel of the same composition and temperature at the same throughput, plasma heating is performed, and a metal Ti wire of φ12 mm is supplied at a supply rate of 40 mm / sec, and 0 to 4054 NL / min into the tundish. Ar was supplied at an Ar gas supply rate within the range of /m ³ . Since heat is taken from the molten steel by wire supply and Ar gas supply, the plasma heating output was adjusted so as to keep the molten steel temperature constant. Even in the actual machine experiment ^, if the Ar gas supply rate is too high, the temperature cannot be compensated by plasma heating, and the molten steel temperature decreases. Heating could compensate for the temperature drop.

A steel component sample was taken from a cast slab after casting at the same Ar gas supply rate for 5 minutes, and the solid solution Ti amount was analyzed. Ti yield was calculated in the same manner as described above. The results are shown in Table 2 and FIG. 3(B). The horizontal axis of FIG. 3B is the Ar gas supply rate per tundish internal volume V (m ³ ), and the vertical axis is the Ti yield. While the Ti yield remained at 71% when no Ar gas was supplied ^, the Ti yield increased as the Ar gas supply rate increased. , the Ti yield was found to be 80% or more.

The surface properties of the cast slabs were inspected to confirm the presence or absence of surface cracks. When surface cracks were confirmed, the surface was cleaned. For each level of Ar gas supply rate, "○" indicates that almost no surface maintenance is required, "△" indicates that the quality level is satisfied by surface maintenance although surface cracks exist, and surface cracks exist and surface maintenance is required. Those that did not satisfy the quality standard were judged as "x". Table 2 shows the results. As is clear from Table 2, the surface texture was found to be "good" at all levels where the Ti yield was 80% or higher (Ar gas supply rate was 600 NL/min/m ³ or higher).

In view of the above results, in the present invention, when continuously casting molten steel via a tundish, Ar gas is supplied into the tundish, and the Ar gas supply rate per tundish internal volume V (m ³ ) is At 600 to 3700 NL/min/m ³ , the molten steel in the tundish is plasma-heated, and an alloy wire is continuously supplied to the molten steel in the tundish to add an alloy to the molten steel. As a result, the addition yield of wire addition to the molten steel in the tundish is 80% or more, and the surface properties of the cast slab can be improved, while the heat loss due to the Ar gas supply can be sufficiently compensated by plasma heating. can.

When plasma heating is performed, Ar gas is used in the atmosphere between the molten steel and the plasma electrode in order to generate plasma. Furthermore, if graphite is used for the plasma heating electrode, the graphite electrode is oxidized and consumed during heating, generating CO gas. Such non-oxidizing gas such as Ar gas and CO gas supplied into the tundish accompanying plasma heating is also added to the Ar gas supplied from the Ar gas supply device in the present invention. This is because it can be counted as a gas for making the atmosphere in the tundish non-oxidizing.

The type of metal wire supplied into the tundish is not limited to Ti, and the following metals can be used. When adding components such as Si, Mn, C, and Cr, wires made of these metals are prepared and supplied to the molten steel in the tundish. When adding easily oxidizable metals such as Ca, Mg, and Al, a wire coated with iron on these metals or metal powders is prepared and supplied to the molten steel in the tundish.

Reference Signs List 1 tundish 2 Ar gas supply device 3 metal wire supply device 4 plasma heating device 5 ladle 6 long nozzle 7 mold 8 immersion nozzle 9 lid 11 metal wire 12 molten steel

Claims (1)

When continuously casting molten steel via a tundish,
Ar gas is supplied into the tundish, and the Ar gas supply rate per tundish internal volume V (m ³ ) is 600 to 3700 NL/min/m ³ ,
Plasma heating is applied to the molten steel in the tundish,
A method for adding an alloy to molten steel, comprising adding an alloy to molten steel by continuously supplying an alloy wire into the molten steel in a tundish.
Here, the tundish internal volume V means the volume of the space from the surface of the molten steel to the upper lid where molten steel is not contained when the tundish receives the molten steel.

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