JP5965186B2 - Continuous casting method - Google Patents

Description

  The present invention relates to a continuous casting method.

  In the manufacturing process of stainless steel, which is a kind of metal, molten iron is produced by melting raw materials in an electric furnace, and the produced molten iron removes carbon that deteriorates the properties of stainless steel in a converter and a vacuum degassing device. Refining including decarburization is performed to form molten steel, and then the molten steel is continuously cast to solidify to form a plate-like slab or the like. In the refining process, the final components of the molten steel are adjusted.

In the continuous casting process, molten steel is poured from a ladle into a tundish, and further poured from a tundish into a casting mold for continuous casting. At this time, in order to prevent the molten steel after final component adjustment from reacting with nitrogen and oxygen in the atmosphere to increase the content of nitrogen and being oxidized, around the molten steel from the ladle to the mold In this case, an inert gas that does not easily react with molten steel is supplied as a sealing gas, and the surface of the molten steel is cut off from the atmosphere.
For example, Patent Document 1 describes a method for producing a continuous casting (continuous casting) slab using argon gas as an inert gas.

JP-A-4-284945

  However, when argon gas is used as the sealing gas as in the manufacturing method of Patent Document 1, the argon gas taken into the molten steel remains as bubbles, and the surface of the continuous cast slab has bubble defects due to argon gas, that is, the surface. There is a problem that defects are likely to occur. Furthermore, when a surface defect occurs in the continuous cast slab, it is necessary to scrape the surface in order to ensure the required quality, which increases the cost.

  The present invention has been made to solve such problems, and provides a continuous casting method that suppresses an increase in nitrogen content when casting a slab (metal piece) and reduces surface defects. With the goal.

In order to solve the above-mentioned problems, the continuous casting method according to the present invention injects molten metal in a ladle into a lower tundish, continuously injects the molten metal in the tundish into a mold, and releases metal pieces. In the continuous casting method for casting, as an injection nozzle for injecting the molten metal in the ladle into the tundish, a long nozzle installation step in which a long nozzle extending into the tundish is provided in the ladle, and in the tundish through the long nozzle Injecting the molten metal into the molten metal and immersing the long nozzle spout into the molten metal in the tundish, and supplying an inert gas as a sealing gas around the molten metal in the tundish in the injection step Pass the long nozzle through the seal gas supply step and the long nozzle spout while immersing it in the molten metal in the tundish. Injecting the molten metal into the tundish and injecting the molten metal in the tundish into the mold, and in the casting step, nitrogen gas is substituted for the inert gas as the sealing gas in the tundish. The tundish powder is applied so as to cover the surface of the molten metal in the tundish before the second seal gas supply step, between the second seal gas supply step supplied to the surroundings and the injection step to the casting step. And a spreading step for spreading .

The inert gas in the first sealing gas supply step may be argon .
In Casting Step, while sequentially replacing multiple ladle and continuously cast molten metal in a plurality of ladle, replace the ladle while immersed spout of the long nozzle to the molten metal in the tundish Also good.
In the casting step, the spout of the long nozzle may penetrate the molten metal in the tundish at a depth of 100 to 150 mm.
The cast metal piece may be stainless steel having a nitrogen concentration of 400 ppm or less.

  According to the continuous casting method of the present invention, it is possible to suppress an increase in the nitrogen content when casting a metal piece and reduce surface defects.

It is a schematic diagram which shows the structure of the continuous casting apparatus used with the continuous casting method which concerns on Embodiment 1 of this invention. It is a schematic diagram which shows the state of the tundish in the continuous casting method which concerns on Embodiment 1 of this invention. It is a schematic diagram which shows the state of the tundish in the continuous casting method which concerns on Embodiment 2 of this invention. It is the figure which compared the number of air bubbles which arise in a stainless steel piece between Example 3 and Comparative Example 3. FIG. It is the figure which compared the bubble number which arises in a stainless steel piece between Example 4 and Comparative Example 4. FIG. It is the figure which compared the bubble number which arises in a stainless steel piece between the case where a long nozzle is used in the comparative example 3 and the comparative example 3. FIG.

Embodiment 1 FIG.
Hereinafter, a continuous casting method according to Embodiment 1 of the present invention will be described with reference to the accompanying drawings. In the following embodiments, a method for continuously casting stainless steel will be described.

First, stainless steel is manufactured by performing a melting process, a primary refining process, a secondary refining process, and a casting process in this order.
In the melting step, scrap or alloy, which is a raw material for stainless steel, is melted in an electric furnace to generate hot metal, and the generated hot metal is poured into the converter. Furthermore, in the primary refining process, a rough decarburization process is performed to remove carbon contained by blowing oxygen into the molten iron in the converter, thereby producing a stainless steel molten steel and slag containing carbon oxides and impurities. Produces. In the primary refining process, the components of the molten stainless steel are analyzed, and the components are coarsely adjusted by introducing an alloy so as to approach the target components. Furthermore, the molten stainless steel produced in the primary refining process is delivered to the ladle and transferred to the secondary refining process.

  In the secondary refining process, the molten stainless steel is put into a vacuum degassing device together with a ladle, and a finish decarburization process is performed. And pure stainless molten steel produces | generates by carrying out finish decarburization processing of the molten stainless steel. Further, in the secondary refining process, the components of the molten stainless steel are analyzed, and final adjustment of the components is also performed, in which an alloy is introduced to bring the components closer to the target components.

  In the casting process, referring to FIG. 1, the ladle 1 is taken out from the vacuum degassing apparatus and set in the continuous casting apparatus (CC) 100. The molten stainless steel 3 of the ladle 1 that is a molten metal is poured into the continuous casting apparatus 100 and further cast into a slab-like stainless steel piece 3c as a metal piece by the mold 105 provided in the continuous casting apparatus 100, for example. The cast stainless steel piece 3c is hot-rolled or cold-rolled into a hot-rolled steel strip or a cold-rolled steel strip in the following rolling process (not shown).

Furthermore, the detail of a structure of the continuous casting apparatus (CC) 100 is demonstrated.
The continuous casting apparatus 100 has a tundish 101 which is a container for temporarily receiving the molten stainless steel 3 sent from the ladle 1 and sending it to the mold 105. The tundish 101 has a main body 101b whose upper part is open, an upper lid 101c that closes the upper part of the main body 101b and blocks it from the outside, and an immersion nozzle 101d that extends from the bottom of the main body 101b. And in the tundish 101, the interior space 101a closed by these inside with the main body 101b and the upper cover 101c is formed. The immersion nozzle 101d opens from the bottom of the main body 101b to the inside 101a at the inlet 101e.
Further, the ladle 1 is set above the tundish 101, and a long nozzle 2 that is an injection nozzle for tundish extending through the upper lid 101 c of the tundish 101 to the inside 101 a is connected to the bottom of the ladle 1. ing. And the spout 2a of the lower front-end | tip of the long nozzle 2 is opened by the inside 101a. Further, the space between the penetrating portion of the upper lid 101c and the upper lid 101c in the long nozzle 2 is sealed and airtightness is maintained.

  A plurality of gas supply nozzles 102 are provided on the upper lid 101 c of the tundish 101. The gas supply nozzle 102 is connected to a gas supply source (not shown), and sends a predetermined gas from the upper side to the lower side to the inside 101 a of the tundish 101. Further, the long nozzle 2 is configured so that the predetermined gas is also supplied into the long nozzle 2.

  Further, the upper lid 101 c of the tundish 101 is provided with a powder nozzle 103 for pouring tundish powder (hereinafter referred to as TD powder) 5 into the inside 101 a of the tundish 101. The powder nozzle 103 is connected to a TD powder supply source (not shown), and sends the TD powder 5 to the inside 101a of the tundish 101 from the top to the bottom. The TD powder 5 is made of a synthetic slag agent or the like and covers the surface of the molten stainless steel 3 to prevent the surface of the molten stainless steel 3 from being oxidized, keep the stainless molten steel 3 warm, and dissolve and absorb the inclusions in the molten stainless steel 3. The effect | action etc. which perform are show | played with respect to the stainless steel molten steel 3. FIG. In the first embodiment, the powder nozzle 103 and the TD powder 5 are not used.

Further, a bar-like stopper 104 that is movable in the vertical direction is provided above the immersion nozzle 101d, and the stopper 104 extends from the inside 101a of the tundish 101 to the outside through the upper lid 101c of the tundish 101. Exist.
The stopper 104 is capable of closing the inlet 101e of the immersion nozzle 101d at its tip by moving downward, and pulling the stainless steel 3 in the tundish 101 upward by pulling upward from the closed state of the inlet 101e. While flowing into the immersion nozzle 101d, the flow rate of the molten stainless steel 3 can be controlled by adjusting the opening area of the inlet 101e according to the amount of pulling up. In addition, a space between the penetrating portion of the upper lid 101c in the stopper 104 and the upper lid 101c is sealed and airtightness is maintained.

The tip 101f of the immersion nozzle 101d at the bottom of the tundish 101 extends into the through hole 105a of the lower mold 105 and opens laterally.
The through hole 105a of the mold 105 has a rectangular cross section and penetrates the mold 105 vertically. The through-hole 105a is configured such that the inner wall surface thereof is water-cooled by a primary cooling mechanism (not shown), and the molten stainless steel 3 inside is cooled and solidified to form a slab 3b having a predetermined cross section.
Further, below the through hole 105a of the mold 105, a plurality of rolls 106 are provided at intervals to draw and transfer the slab 3b formed by the mold 105 downward. Further, a secondary cooling mechanism (not shown) is provided between the rolls 106 to sprinkle and cool the slab 3b.

Next, operation | movement of the continuous casting apparatus 100 in this Embodiment 1 is demonstrated.
Referring to FIGS. 1 and 2, in the continuous casting apparatus 100, a ladle 1 including the stainless steel 3 after the secondary refining is installed above the tundish 101. Further, a long nozzle 2 is attached to the bottom of the ladle 1, and the tip of the long nozzle 2 having the spout 2 a extends to the inside 101 a of the tundish 101. At this time, the stopper 104 closes the inlet 101e of the immersion nozzle 101d.
In the following embodiment, a case will be described in which two ladles 1 are sequentially used, and the casting is continued without ending when the ladle 1 is replaced. That is, in the following embodiment, the stainless steel for 2 charges manufactured with the electric furnace in a melting process is continuously cast.

  Next, an argon (Ar) gas 4a, which is an inert gas, is injected as the seal gas 4 from the gas supply nozzle 102 to the inside 101a of the tundish 101, and the argon gas 4a is also supplied to the inside of the long nozzle 2. The As a result, the air containing impurities existing in the inside 101a and the long nozzle 2 of the tundish 101 is pushed out from the tundish 101, and the inside 101a and the long nozzle 2 are filled with the argon gas 4a. That is, the region from the ladle 1 to the inside 101a of the tundish 101 and the mold 105 is filled with the argon gas 4a.

Thereafter, a valve (not shown) provided in the long nozzle 2 is opened, and the molten stainless steel 3 in the ladle 1 flows down in the long nozzle 2 by the action of gravity and flows into the interior 101 a of the tundish 101. That is, the inside of the tundish 101 is in the state shown in step A of FIG.
At this time, the flowing stainless molten steel 3 is sealed by the argon gas 4a filled in the interior 101a and does not come into contact with air. Therefore, nitrogen (N ₂ ) having solubility in the molten stainless steel 3 contained in the air is stainless steel. It is suppressed that the nitrogen component dissolves into the molten steel 3 and increases. Further, when the molten stainless steel 3 flowing down from the spout 2a of the long nozzle 2 strikes the surface 3a of the molten stainless steel 3 in the tundish 101, a small amount of argon gas 4a is caught and mixed in the molten stainless steel 3. However, since the argon gas 4a is inactive, it does not react with or melt into the stainless molten steel 3.

  And the surface 3a of the molten stainless steel 3 of the inside 101a of the tundish 101 rises by the flowing molten stainless steel 3. When the rising surface 3a is in the vicinity of the spout 2a of the long nozzle 2, the stagnation of the surface 3a by the molten stainless steel 3 flowing down from the spout 2a is reduced and the amount of surrounding gas is reduced, so that the gas supply nozzle 102 Nitrogen gas 4b is injected into the interior 101a of the tundish 101 instead of the argon gas 4a. Thereby, in the inside 101a of the tundish 101, the argon gas 4a is pushed out, and the region between the stainless steel 3 and the upper lid 101c of the tundish 101 is filled with the nitrogen gas 4b.

  When the rising surface 3a immerses the spout 2a of the long nozzle 2 in the molten stainless steel 3, and the depth of the molten stainless steel 3 in the interior 101a of the tundish 101 reaches a predetermined depth D, the stopper 104 is raised, and the interior 101a The molten stainless steel 3 flows into the through hole 105a of the mold 105 through the immersion nozzle 101d, and casting starts. At the same time, the molten stainless steel 3 in the ladle 1 is continuously poured out into the inside 101 a of the tundish 101 through the long nozzle 2, and new molten stainless steel 3 is replenished. At this time, the inside of the tundish 101 is in a state as shown in step B of FIG.

  When the depth of the molten stainless steel 3 in the interior 101a is a predetermined depth D, the long nozzle 2 is formed in the molten stainless steel 3 so that the spout 2a has a depth of about 100 to 150 mm from the surface 3a of the molten stainless steel 3. Penetration is preferred. If the long nozzle 2 penetrates deeper than the above depth, it becomes difficult to pour out the molten stainless steel 3 from the spout 2a of the long nozzle 2 due to the resistance caused by the internal pressure of the molten stainless steel 3 accumulated in the interior 101a. On the other hand, when the long nozzle 2 penetrates shallower than the above-described depth, the spout 2a is exposed when the surface 3a of the molten stainless steel 3 controlled to be maintained near a predetermined position at the time of casting fluctuates as described later. Then, there is a possibility that the poured molten stainless steel 3 hits the surface 3a and involves the nitrogen gas 4b.

  The molten stainless steel 3 flowing into the through hole 105a of the mold 105 is cooled by a primary cooling mechanism (not shown) in the process of flowing through the through hole 105a, and the inner wall surface side of the through hole 105a is solidified to form a solidified shell 3ba. To do. The formed solidified shell 3ba is pushed out of the mold 105 downward by the solidified shell 3ba newly formed above in the through hole 105a. The mold powder is supplied to the inner wall surface of the through hole 105a from the tip 101f side of the immersion nozzle 101d. The mold powder melts in the slag on the surface of the molten stainless steel 3, prevents oxidation of the surface of the molten stainless steel 3 in the through hole 105a, lubricates between the mold 105 and the solidified shell 3ba, in the through hole 105a. It plays a role of keeping the surface of the molten stainless steel 3 warm.

  A cast slab 3b is formed by the extruded solidified shell 3ba and the unsolidified molten stainless steel 3 inside, and the slab 3b is sandwiched from both sides by the roll 106 and further drawn downward. The drawn slab 3b is sprinkled and cooled by a secondary cooling mechanism (not shown) in the process of passing through between the rolls 106 to completely solidify the molten stainless steel 3 inside. Thus, the slab 3b is drawn from the mold 105 by the roll 106, and a new slab 3b is formed in the mold 105, whereby the slab 3b continuous from the mold 105 in the extending direction of the roll 106 is formed. Is formed. Further, the slab-like stainless steel piece 3c is formed by feeding the cast piece 3b from the end of the roll 106 to the outside of the roll 106 and cutting the fed cast piece 3b.

The casting speed at which the slab 3b is cast is controlled by adjusting the open area of the inlet 101e of the immersion nozzle 101d by the stopper 104. Furthermore, the inflow amount of the molten stainless steel 3 from the ladle 1 through the long nozzle 2 is adjusted so as to be equal to the outflow amount of the molten stainless steel 3 from the inlet 101e. Accordingly, the surface 3a of the molten stainless steel 3 in the inside 101a of the tundish 101 is controlled so as to maintain a substantially constant position in the vertical direction in a state where the depth of the molten stainless steel 3 is maintained in the vicinity of the predetermined depth D. Is done. At this time, in the long nozzle 2, the spout 2 a at the tip is immersed in the molten stainless steel 3. Then, as described above, the vertical position of the surface 3a of the stainless steel 3 in the inner 101a was maintained substantially constant while the spout 2a of the long nozzle 2 was immersed in the stainless steel 3 in the inner 101a of the tundish 101. The cast state is called a steady state.
Therefore, since the surface 3a is not sunk by the molten stainless steel 3 flowing in from the long nozzle 2 while casting is performed in a steady state, the nitrogen gas 4b does not get caught in the molten stainless steel 3 and flows into the molten stainless steel 3. Maintaining contact with the gentle surface 3a. Thereby, even if it is the nitrogen gas 4b which has the solubility to the stainless steel molten steel 3, the penetration to the stainless steel molten steel 3 is suppressed low in a steady state.

  When the molten stainless steel 3 in the ladle 1 is lost, the long nozzle 2 is removed and replaced with another ladle 1 containing the molten stainless steel 3. The ladle 1 to be replaced is installed on the tundish 101 and the long nozzle 2 is connected thereto. Further, the casting operation is continuously performed even during the replacement operation of the ladle 1, whereby the surface 3 a of the molten stainless steel 3 in the inside 101 a of the tundish 101 is lowered. The supply of nitrogen gas 4b to the inside 101a of the tundish 101 is continued during the ladle replacement operation. Then, the inside of the tundish 101 is in a state as shown in Step C of FIG.

  During the operation of replacing the ladle 1, the stopper 104 opens the inlet 101e of the immersion nozzle 101d so that the surface 3a of the stainless steel 3 in the interior 101a of the tundish 101 does not fall below the spout 2a of the long nozzle 2. The flow rate of the molten stainless steel 3, that is, the casting speed is controlled by adjusting the area. By continuously casting the molten stainless steel 3 of the two ladles 1 as described above, the quality of the seam in the continuous slab 3b formed by the molten stainless steel 3 of the two ladles 1 cast is set to a steady state. It can hold | maintain equivalent to the slab 3b cast by (3). In other words, as will be described later, the quality of the slab 3b is reduced at the initial stage of casting every time the ladle 1 changes, thereby eliminating the need for disposal or processing of the part where the quality has changed, thereby reducing costs. Is possible. Further, by continuously casting the molten stainless steel 3 of the two ladles 1, compared to the case where the casting is finished for each ladle 1, the molten stainless steel 3 is accumulated in the tundish 101 and the casting is started. The steps up to can be omitted once, and the work efficiency is improved, so that the cost can be reduced.

  Furthermore, when the molten stainless steel 3 in the ladle 1 that has been replaced is lost as the casting progresses, the surface 3a of the molten stainless steel 3 in the interior 101a of the tundish 101 descends below the spout 2a of the long nozzle 2. Since there is no new flow of the molten steel 3, the molten steel 3 is in contact with the nitrogen gas 4 b without causing turbulence due to knocking or the like. Therefore, the mixing by the penetration of the nitrogen gas 4b into the molten stainless steel 3 can be kept low until the end of casting where the molten stainless steel 3 in the tundish 101 disappears. At this time, the inside of the tundish 101 is in a state as shown in step D of FIG.

  Further, even before the spout 2a of the long nozzle 2 is immersed in the molten stainless steel 3 in the interior 101a of the tundish 101, the spout 2a, the bottom of the body 101b of the tundish 101, and the surface 3a of the stainless molten steel 3 in the interior 101a , And the stagnation of the surface 3a by the molten stainless steel 3 is limited to the short time until the spout 2a is immersed, thereby reducing the contamination of the molten stainless steel 3 by the entrainment of air or argon gas 4a. ing.

  If nitrogen gas 4b is used as the sealing gas when the surface 3a is struck by the molten stainless steel 3, the nitrogen gas 4b may be excessively dissolved in the molten stainless steel 3 to make the components incompatible with the product. That is, there is a possibility that all of the stainless steel pieces 3c cast from the molten stainless steel 3 stored in the inside 101a of the tundish 101 need to be discarded before the spout 2a of the long nozzle 2 is immersed. is there. However, by using the argon gas 4a, the components of the molten stainless steel 3 can be kept within a required range without largely changing.

  Therefore, the stainless steel in the early casting stage is affected by slight air or argon gas 4a mixed in the molten stainless steel 3 in a short time until the spout 2a of the long nozzle 2 is immersed in the molten stainless steel 3 in the interior 101a of the tundish 101. The piece 3c can obtain a required component structure. Thus, the stainless steel piece 3c can be used as a product if the surface is cut in order to remove bubbles generated by the mixing of the argon gas 4a. In addition, the stainless steel piece 3c cast at a time other than the initial stage of casting, which occupies most of the casting time from the start to the end of casting, is mixed with the air and argon gas 4a mixed before the spout 2a of the long nozzle 2 is immersed. In addition, mixing of nitrogen gas 4b during casting can be kept low. For this reason, the stainless steel piece 3c occupying most of the above casting time can suppress an increase in nitrogen content from the state after the secondary refining, and a small amount of mixed nitrogen gas 4b enters the molten stainless steel 3. Since the generation of surface defects due to bubbles is greatly suppressed by dissolution, the product can be used as it is.

  Therefore, by using the argon gas 4a as the sealing gas before the start of casting, the change in the components of the molten stainless steel 3 before casting is suppressed, and during the casting, the molten stainless steel in the tundish 101 is used with the nitrogen gas 4b as the sealing gas. By injecting the molten stainless steel 3 of the ladle 1 through the long nozzle 2 in which the spout 2a is immersed in 3, the generation of bubbles in the stainless steel piece 3c after casting is suppressed, and after the secondary refining The increase in nitrogen content from the state is suppressed.

Embodiment 2. FIG.
The continuous casting method according to Embodiment 2 of the present invention is such that the TD powder 5 is sprayed and coated on the surface 3a of the molten stainless steel 3 in the tundish 101 in the continuous casting method according to Embodiment 1. is there.
In the continuous casting method according to the second embodiment, since the continuous casting apparatus 100 is used as in the first embodiment, the description of the configuration of the continuous casting apparatus 100 is omitted.

With reference to FIG.1 and FIG.3, operation | movement of the continuous casting apparatus 100 in Embodiment 2 is demonstrated.
In the tundish 101 in which the ladle 1 is set and the long nozzle 2 is attached to the ladle 1 in the continuous casting apparatus 100, the inlet 101e of the immersion nozzle 101d is closed by the stopper 104, as in the first embodiment. Then, the argon gas 4a is supplied from the gas supply nozzle 102 or the like into the interior 101a and the long nozzle 2, and is filled with the argon gas 4a. Next, the molten stainless steel 3 is poured from the ladle 1 into the inside 101 a of the tundish 101 through the long nozzle 2. That is, the inside of the tundish 101 is in the state shown in step A of FIG.

  When the surface 3a of the stainless molten steel 3 rising by the flowing stainless molten steel 3 in the interior 101a of the tundish 101 is in the vicinity of the spout 2a of the long nozzle 2, the surface 3a of the stainless molten steel 3 flowing down from the spout 2a Since the entrapping due to the squeezing becomes smaller, the TD powder 5 is sprayed from the powder nozzle 103 toward the surface 3a of the molten stainless steel 3 in the interior 101a. The TD powder 5 is sprayed so as to cover the entire surface 3 a of the molten stainless steel 3.

After the TD powder 5 is sprayed, nitrogen gas 4b is injected from the gas supply nozzle 102 in place of the argon gas 4a. Thereby, in the inside 101a of the tundish 101, the argon gas 4a is pushed out, and the region between the TD powder 5 and the upper lid 101c of the tundish 101 is filled with the nitrogen gas 4b.
The TD powder 5 deposited in layers on the surface 3a of the molten stainless steel 3 blocks contact between the surface 3a of the molten stainless steel 3 and the nitrogen gas 4b, and suppresses the penetration of the nitrogen gas 4b into the molten stainless steel 3.

Furthermore, in the inside 101a of the tundish 101 into which the molten stainless steel 3 is poured, when the surface 3a of the molten stainless steel 3 rises and the depth reaches a predetermined depth D, the stopper 104 is raised, thereby the stainless molten steel in the inner 101a. 3 flows into the mold 105 and casting starts.
During casting, in the tundish 101, the spout 2a of the long nozzle 2 is immersed in the molten stainless steel 3 in the inner 101a of the tundish 101, while the molten stainless steel 3 in the inner 101a has a depth in the vicinity of the predetermined depth D. The amount of outflow of the molten stainless steel 3 from the immersion nozzle 101d and the amount of inflow of the molten stainless steel 3 through the long nozzle 2 are adjusted so that the surface 3a is in a substantially constant position.

Therefore, on the surface 3a of the molten stainless steel 3 covered with the TD powder 5, the TD powder 5 deposited by the injected molten stainless steel 3 is prevented from being disturbed, whereby the surface 3a is exposed to the nitrogen gas 4b. Direct contact is prevented. Therefore, while casting is performed in a steady state, the TD powder 5 keeps blocking between the surface 3a of the molten stainless steel 3 and the nitrogen gas 4b.
At this time, the inside of the tundish 101 is in a state shown in step B of FIG.

  Further, when the molten stainless steel 3 in the ladle 1 is lost, the casting is continued and the surface 3a of the molten stainless steel 3 in the interior 101a of the tundish 101 is removed from the spout 2a of the long nozzle 2 as in the first embodiment. The long nozzle 2 is removed, replaced with another ladle 1 containing the molten stainless steel 3, and the long nozzle 2 is connected to the replaced ladle 1 in sequence. At this time, the inside of the tundish 101 is in a state as shown in Step C of FIG.

Further, when the molten stainless steel 3 in the ladle 1 that has been replaced is lost as the casting progresses, the surface 3a of the molten stainless steel 3 in the interior 101a of the tundish 101 descends below the spout 2a of the long nozzle 2. At this time, the TD powder 5 on the surface 3a of the molten stainless steel 3 fills the portion where the long nozzle 2 has penetrated and covers the entire surface 3a, and the surface 3a of the molten stainless steel 3 and the nitrogen gas 4b Continue to block direct contact. At this time, the inside of the tundish 101 is in a state as shown in step D of FIG.
The molten stainless steel 3 in the interior 101a of the tundish 101 flows into the mold 105 in a state where the entire surface 3a is covered with the TD powder 5 until the end of casting, and the TD powder 5 is in contact with the surface 3a of the molten stainless steel 3 and nitrogen gas. Continue to block contact with 4b.

  Therefore, in the tundish 101, the molten stainless steel 3 in the inner portion 101 a is covered with the TD powder 5 during the steady state of casting after the dispersion of the TD powder 5 and until the end of the subsequent casting, and the molten stainless steel in the ladle 1 is further covered. 3 is poured into the molten stainless steel 3 in the inner 101a through the long nozzle 2 in which the spout 2a is immersed in the molten stainless steel 3 in the inner 101a. Thereby, the molten stainless steel 3 is not in direct contact with the nitrogen gas 4b, and the mixing of the nitrogen gas 4b into the molten stainless steel 3 hardly occurs.

  And the stainless steel piece 3c cast at the initial stage of casting in which the influence of the slight amount of air mixed in the molten stainless steel 3 or the argon gas 4a in the short time until the TD powder 5 is sprayed is the same as in the first embodiment. The required components can be obtained, and the product can be used as a product by surface cutting. Further, the stainless steel piece 3c cast at a time other than the initial stage of casting, which occupies most of the casting time from the start to the end of casting, is affected by the air and the argon gas 4a mixed before the TD powder 5 is sprayed. Furthermore, there is little mixing of nitrogen gas 4b during casting. For this reason, the stainless steel piece 3c cast in most of the casting time described above has a surface defect due to the bubbling of the mixed nitrogen gas 4b or the like with little increase in nitrogen content from the state after secondary refining. Therefore, even a low-nitrogen steel type stainless steel can be used as it is as a product.

Therefore, by using the argon gas 4a as the seal gas before the start of casting, changes in the components of the molten stainless steel 3 before casting can be suppressed. Further, during casting, the molten stainless steel 3 is injected through the long nozzle 2 in which the spout 2a is immersed in the molten stainless steel 3 in the tundish 101, using the nitrogen gas 4b as a seal gas. By covering the surface 3a of the molten stainless steel 3 with the TD powder 5 and preventing direct contact between the molten stainless steel 3 and the nitrogen gas 4b, generation of bubbles in the cast stainless steel piece 3c is suppressed and secondary refining is performed. The increase in the nitrogen content from the later state is greatly suppressed as compared with the first embodiment.
Moreover, since the other structure and operation | movement regarding the continuous casting apparatus 100 using the continuous casting method which concerns on Embodiment 2 of this invention are the same as that of Embodiment 1, description is abbreviate | omitted.

(Example)
Hereinafter, examples in which stainless steel pieces are cast using the continuous casting method according to the first and second embodiments will be described.
Using SUS430, ferritic single-phase stainless steel (chemical component: 19Cr-0.5Cu-Nb-LCN) and SUS316L stainless steel, a slab, which is a stainless steel piece, was cast using the continuous casting method of Embodiments 1 and 2. The characteristics were evaluated for Examples 1 to 4 and Comparative Examples 1 to 2 in which a short nozzle was used as an injection nozzle for SUS430 stainless steel and a slab was cast using argon gas or nitrogen gas as a seal gas. The following detection results were sampled from a slab cast in a steady state excluding the initial stage of casting in the example, and in the comparative example, the sample was cast at the same time as the sampling time of the example from the start of casting. Sampled from slab.

  Table 1 shows the steel type, the type and supply flow rate of the sealing gas, the type of injection nozzle, and the presence or absence of use of TD powder for each of the examples and comparative examples. In addition, the short nozzle in Table 1 means that the lower end of the short nozzle in FIG. 1 is substantially the same as the lower surface of the upper lid 101c of the tundish 101 when it is attached to the ladle 1 instead of the long nozzle 2. The length is short.

Example 1 is an example in which a SUS430 stainless steel slab was cast using the continuous casting method of the first embodiment.
Example 2 is an example in which a stainless steel slab of SUS430 was cast using the continuous casting method of the second embodiment.
Example 3 is an example in which a stainless steel slab of ferritic single phase stainless steel (chemical component: 19Cr-0.5Cu-Nb-LCN), which is a low nitrogen steel type, was cast using the continuous casting method of the second embodiment. is there.
Example 4 is an example in which a stainless steel slab of SUS316L (austenite low nitrogen steel type), which is a low nitrogen steel type, was cast using the continuous casting method of the second embodiment.
Comparative Example 1 uses a short nozzle instead of the long nozzle 2 in the continuous casting method of the first embodiment, and uses argon (Ar) gas instead of nitrogen gas as a sealing gas, and SUS430 stainless steel slab This is an example of casting.
Comparative Example 2 is an example in which a SUS430 stainless steel slab was cast using a short nozzle instead of the long nozzle 2 in the continuous casting method of the first embodiment.

  Furthermore, Table 2 shows the results of N pickup, which is the amount of nitrogen (N) pickup in the slabs cast in Examples 1 to 4 and Comparative Examples 1 and 2. In Table 2, N pickups measured with a plurality of slabs cast for each of Examples 1 to 4 and Comparative Examples 1 to 2 are summarized. Moreover, N pick-up is the increase amount of the nitrogen component contained in the slab after casting with respect to the nitrogen component of the molten stainless steel 3 in the ladle 1 after final component adjustment in the secondary refining process, This is the mass of nitrogen component newly contained in the molten stainless steel in the casting process. N pickup is indicated by mass concentration, and its unit is ppm.

In Comparative Example 1, since the argon gas is used as the seal gas without using the nitrogen gas, the N pickup is between 0 and 20 ppm, and the average is as low as 8 ppm.
In Comparative Example 2, since the short nozzle is used, the molten stainless steel poured into the tundish 101 knocks on the surface of the molten stainless steel in the tundish 101 and entrains a lot of surrounding nitrogen gas, so that the N pickup is 50 ppm. The average is as high as 50 ppm.

  In the first embodiment, when the casting nozzle 2a of the long nozzle 2 is immersed in stainless steel in a steady state of casting, the surface of the molten stainless steel in the tundish 101 due to the poured molten stainless steel is prevented. Since the nitrogen gas is only in contact with the mild surface of the molten stainless steel, the N pickup is as low as in Comparative Example 1. Specifically, the N pickup in Example 1 is between 0 and 20 ppm, and the average is as low as 10 ppm.

  In Examples 2 to 4, in the steady state of casting, in addition to the use of the long nozzle 2, the stainless steel in the tundish 101 and nitrogen gas are blocked by TD powder, so that the N pickup is used for Comparative Example 1 and Example. It is considerably smaller than 1. Specifically, the N pickup in Example 2 is between -10 and 0 ppm, and its average is as low as -4 ppm. That is, the nitrogen content in the slab is less than that in the stainless steel after secondary refining, which is considered that the TD powder absorbs the nitrogen component in the stainless steel. Further, the N pickup in Example 3 is also between −10 and 0 ppm, and the average is as low as −9 ppm. Furthermore, the N pickup in Example 4 is also between -10 and 0 ppm, and the average is very low at -7 ppm.

  In addition, when argon gas, which is an inert gas, is contained in molten stainless steel, most of it does not dissolve in the molten stainless steel and remains in the slab after being cast as bubbles, but most of the nitrogen that is soluble in molten stainless steel is nitrogen. In the example in which nitrogen gas was used as the seal gas to dissolve in the molten stainless steel, it was hardly detected as bubbles from the slab. That is, in Examples 1 to 4 and Comparative Example 2, almost no bubbles were confirmed in the slab, while in Comparative Example 1, many bubbles that were surface defects were confirmed in the slab.

For example, FIG. 4 shows Example 3 and further comparative example 3 (steel type: ferritic single phase stainless steel (chemical component: 19Cr-0.5Cu-Nb-LCN), seal gas: Ar, seal gas supply flow rate: 60 Nm. ³ / h, injection nozzle: short nozzle), a diagram comparing the number of bubbles of Φ0.4 mm or more generated in the slab is shown. In FIG. 4, the number of bubbles per 10000 mm ² (100 mm × 100 mm region) at six measurement points equally divided from the center to the end in the half region from the center to the end in the width direction of the slab surface. It is shown.
As shown in FIG. 4, in Example 3, the number of bubbles was 0 over the entire region, and in Comparative Example 3, bubbles were confirmed over almost the entire region, and 0-14 bubbles were confirmed at each measurement point. .

FIG. 5 also shows a comparison between Example 4 and further comparative example 4 (steel type: SUS316L (austenite low nitrogen steel type), seal gas: Ar, seal gas supply flow rate: 60 Nm ³ / h, injection nozzle: short nozzle). The figure which compared the number of air bubbles more than (phi) 0.4mm produced in a slab between is shown. In FIG. 5, in the half area from the center to the end of the slab surface in the width direction, the number of bubbles per 10,000 mm ² (100 mm × 100 mm area) at five measurement points equally divided from the center to the end. It is shown.
As shown in FIG. 5, in Example 4, the number of bubbles was 0 over the entire region, and in Comparative Example 4, bubbles were confirmed over almost the entire region, and 5 to 35 bubbles were confirmed at each measurement point. .

Incidentally, FIG. 6 shows the number of bubbles of Φ0.4 mm or more generated in the slab in Comparative Example 3 described above and the steady state excluding the initial stage when the long nozzle 2 is used instead of the short nozzle in Comparative Example 3. The figure which compared the bubble number of (phi) 0.4 mm or more which arises in another slab is shown. In FIG. 6, the number of bubbles per 10000 mm ² (100 mm × 100 mm region) at six measurement points equally divided from the center to the end in the half region from the center to the end in the width direction of the slab surface. It is shown.
As shown in FIG. 6, even when the long nozzle 2 was used, the number of bubbles was reduced as compared with Comparative Example 3, but 3 to 7 bubbles were confirmed over the entire region. Such a bubble reduction effect cannot be confirmed.

Therefore, in Example 1 using the continuous casting method of the first embodiment, while suppressing bubble defects in the slab to be substantially zero, N pickup in the casting process is compared with Comparative Example 1 in which nitrogen gas is not used as a seal gas. It can be kept down to the same extent. Therefore, the continuous casting method of Embodiment 1 is applied to the production of stainless steel having a low nitrogen content with a nitrogen component content of 400 ppm or less, instead of the conventional casting method using argon gas as a sealing gas. Is sufficiently possible, and further has an effect of reducing bubble defects.
Further, in Examples 2 to 4 using the continuous casting method of the second embodiment, the N pick-up in the casting process is performed while the bubble defect in the slab is suppressed to almost zero, and the comparative example in which nitrogen gas is not used as the seal gas. It can be kept below 1 and almost zero. Therefore, the continuous casting method of Embodiment 2 can be sufficiently applied to the production of stainless steel of a low nitrogen steel type, and has the effect of suppressing bubble defects.

  Therefore, by using nitrogen gas as the seal gas during the steady state of casting, the generation of bubbles in the stainless steel piece after casting can be suppressed. Furthermore, the N pickup can be reduced by pouring the molten stainless steel using the long nozzle 2 in which the spout 2a is immersed in the molten stainless steel in the tundish 101 during the steady state of casting. Furthermore, the N pickup can be reduced to nearly zero by covering the surface of the molten stainless steel in the tundish 101 with TD powder during the steady state of casting.

In addition to the above steel types, the present invention was applied to SUS409L, SUS444, SUS445J1, SUS304L, etc., and it was confirmed that the N pickup reduction effect and the bubble reduction effect as shown in Examples 1 to 4 were obtained.
Moreover, although the continuous casting method which concerns on Embodiment 1 and 2 was applied to manufacture of stainless steel, you may apply to manufacture of another metal.
Further, the control in the tundish 101 in the continuous casting method according to the first and second embodiments has been applied to continuous casting, but may be applied to other casting methods.

  1 ladle, 2 long nozzle, 2a spout, 3 stainless molten steel (molten metal), 3c stainless steel piece (metal piece), 4 seal gas, 4a argon gas (inert gas), 4b nitrogen gas, 5 tundish powder , 100 continuous casting equipment, 101 tundish, 105 mold.

Claims (5)

In a continuous casting method in which molten metal in a ladle is poured into a lower tundish, and the molten metal in the tundish is continuously poured into a mold to cast a metal piece.
A long nozzle installation step in which a long nozzle extending into the tundish is provided in the ladle as an injection nozzle for injecting the molten metal in the ladle into the tundish;
Injecting the molten metal into the tundish through the long nozzle and immersing the spout of the long nozzle in the molten metal in the tundish;
A first seal gas supply step of supplying an inert gas as a seal gas around the molten metal in the tundish in the injection step;
While immersing the spout of the long nozzle in the molten metal in the tundish, the molten metal is injected into the tundish through the long nozzle, and the molten metal in the tundish is used as the mold. A casting step of injecting,
A second sealing gas supply step of supplying nitrogen gas around the molten metal in the tundish instead of the inert gas as a sealing gas in the casting step ;
A spraying step of spraying tundish powder so as to cover the surface of the molten metal in the tundish between the injection step and the casting step and before the second sealing gas supply step; A continuous casting method comprising:   The continuous casting method according to claim 1, wherein the inert gas in the first seal gas supply step is argon. In the casting step, the molten metal of the plurality of ladles is continuously cast while sequentially replacing the plurality of ladles, and the spout of the long nozzle is immersed in the molten metal in the tundish. The continuous casting method according to claim 1 or 2 , wherein the ladle is replaced. The continuous casting method according to any one of claims 1 to 3 , wherein in the casting step, the spout of the long nozzle is penetrated into the molten metal in the tundish at a depth of 100 to 150 mm. The continuous casting method according to any one of claims 1 to 4 , wherein the metal piece to be cast is stainless steel having a nitrogen concentration of 400 ppm or less.

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