JP4079415B2 - Submerged nozzle for continuous casting of thin slabs - Google Patents

Description

【００４４】
表１に示したように、逃げ孔を形成したノズル（実施例１）においては、スプラッシュによるブレークアウトの発生が見られなかったのに対して、従来の２方向のみの吐出孔が形成されたノズル（比較例１）においては、スプラッシュによるブレークアウトが２０本に１本発生した。
また、実施例１においては、溶鋼に浸漬される部分にシリカを含む場合（比較例１）に比べて、下部外周における地金の付着が抑制され、長時間安定して使用可能であることが認められた。
特に、実施例１においては、付着物の低減により、長時間使用の末期での湯面変動が少なく、モールド表面に存在するモールドパウダーの溶融層の均一化が図られ、スラグベアの生成が完全に抑制されることが認められた。
【００４５】
［比較例４］
溶融金属流路の下部３ｃの扁平直管状部分における断面積Ｓ_3cを、上部３ａの円筒状部分の断面おける断面積Ｓ_3aの９０％とし、それ以外については、実施例１と同様に構成された浸漬ノズルを用いて、実施例１と同様にして、連続鋳造試験を行った。
この試験においては、モールドにおける湯面変動および鋳片におけるモールドパウダーの巻き込み欠陥について評価を行った。
これらの結果を、実施例１と併せて、表２に示す。
【００４６】
［比較例５］
溶融金属流路の下部３ｃの扁平直管状部分における断面積Ｓ_3cを、上部３ａの円筒状部分の断面おける断面積Ｓ_3aの１１０％とし、それ以外については、実施例１と同様に構成された浸漬ノズルを用いて、実施例１と同様にして、連続鋳造試験を行った。
この試験においては、モールドにおける湯面変動および鋳片におけるモールドパウダーの巻き込み欠陥について評価を行った。
これらの結果を、表２に示す。
【００４７】
【表２】

【００４８】
表２に示したように、Ｓ_3cがＳ_3aの９５％未満である場合（比較例４）には、モールドパウダーの巻き込み欠陥は少ないものの、モールドでの湯面変動が大きく、一方、Ｓ_3cがＳ_3aの１０５％を超える場合（比較例５）には、モールドでの湯面変動は小さいものの、モールドパウダーの巻き込み欠陥が多く見られ、いずれのノズルにおいても、鋳片の品質上、好ましい結果は得られなかった。
これに対して、Ｓ_3cがＳ_3aの９５％以上１０５％以下である場合（実施例１）には、モールドでの湯面変動がなく、また、モールドパウダーの巻き込み欠陥も認められず、このような本発明に係るノズルは、高品質の鋳片を得る上で、有効であることが認められた。
【００４９】
【発明の効果】
以上のとおり、本発明に係る薄スラブ連続鋳造用浸漬ノズルは、長時間使用においても、ノズルおよびモールド内での溶融金属の偏流や湯面変動を防止し、かつ、ノズルの地金付着および損傷等を抑制することができる。
したがって、本発明に係る薄スラブ連続鋳造用浸漬ノズルを用いることにより、長時間連続して、高品質の薄スラブ鋳片を安定的に供給することができる。
【図面の簡単な説明】
【図１】本発明に係る薄スラブ連続鋳造用浸漬ノズルの概略縦断面図であり、（ａ）は短辺側、（ｂ）は長辺側を示す断面図である。
【図２】図１に示すノズルの溶融金属流方向に対する拡大断面図であり、（ａ）は上部３ａにおける断面を示したものであり、（ｂ）は下部３ｃにおける断面を示したである。
【図３】図１のＡ部分の拡大図である。
【図４】図１に示すノズルの使用態様および溶融金属の流動状態を表した模式図である。
【図５】従来の薄スラブ連続鋳造用浸漬ノズルの一例を示す概略縦断面図であり、（ａ）は短辺側、（ｂ）は長辺側を示したものである。
【符号の説明】
１ 浸漬ノズル
２ 溶融金属流入口
３、２３ 溶融金属流路
３ａ、２３ａ 上部
３ｂ、２３ｂ 中間部
３ｃ、２３ｃ 下部
４ 溶融金属吐出孔
５ 浸漬部分
６ 逃げ孔
Ｂ 長辺側のテーパの始点
Ｂ’ 短辺側のテーパの始点
Ｃ、 長辺側のテーパの終点
Ｃ’ 短辺側のテーパの終点
Ｔ 長辺方向の切欠き長さ
ｔ 短辺側の側壁の肉厚
１１ タンディッシュ
１２ ストッパーヘッド
１３ 溶融金属（溶鋼）
１４ モールド
Ｆ１ 側方流
Ｆ２ 下方流[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a thin slab continuous casting immersion nozzle, and more particularly to a flat thin slab continuous casting immersion nozzle suitable for continuous casting of thin slab cast pieces.
[0002]
[Prior art]
In recent years, slab slabs tend to be thinned in order to save labor in the subsequent process of continuous casting. For example, continuous casting of thin and wide slab cast pieces having a thickness of 100 mm or less and a width of 1000 mm or more has been generally performed. Accordingly, it is necessary to make the mold and the immersion nozzle flat.
[0003]
However, when a thin slab slab is continuously cast using a flat nozzle and mold, various problems that could not occur in the use of a conventional simple rectangular mold have occurred.
For example, when the distance between the mold and the nozzle is narrow and continuous casting is performed for a long time, deposits such as slag grown on the outer wall of the nozzle come into contact with and weld to the solidified shell. There was a risk that the tip of the tube was damaged, and that the solidified shell was torn and a breakout was induced.
[0004]
In addition, it is difficult to fill the flat flow path of the immersion nozzle with molten metal, especially when the cross-sectional area of the molten metal inlet is smaller than the cross-sectional area of the flow path of the flat portion, drift, turbulent flow, pulsating flow, etc. The unstable molten metal flow was likely to occur, and as a result, fluctuations in the molten metal surface and entanglement of mold powder into the slab were likely to occur.
Furthermore, when uneven flow occurs in a flat and narrow molten metal flow path, local melting of the inner wall of the nozzle occurs at a portion where the flow velocity of the molten metal is high, and nonmetallic inclusions such as alumina adhere to the portion where the flow velocity is low. There has also been a problem that clogging is likely to occur.
[0005]
On the other hand, in a flat immersion nozzle, when the cross-sectional area of the molten metal inlet is larger than the cross-sectional area of the flat flow path, the flow rate of the molten metal discharge flow increases, which causes fluctuations in the molten metal surface. In addition, there is an inconvenience that local melt damage at the lower part of the nozzle tends to occur.
[0006]
In order to eliminate the inconvenience associated with the occurrence of drift due to the flat nozzle as described above, various flat nozzles having improved shapes of the molten metal channel have been proposed so far.
For example, Japanese Patent Application Laid-Open No. 11-47897 discloses an immersion nozzle for continuous casting that is formed in a divergent shape at an appropriate angle in an intermediate portion of a molten metal flow path and has a flat bottom.
[0007]
However, in the above-mentioned divergent nozzle, it is difficult to obtain a full flow in the entire molten metal flow path in the nozzle, and it is easy to cause a drift, which causes deterioration of the quality of the slab due to entrainment of mold powder, and the inner wall surface of the nozzle There was a problem that local melting damage was likely to occur.
[0008]
As another conventional flat nozzle, for example, there is a nozzle as shown in FIG. FIG. 5A is a longitudinal sectional view seen from the short side direction, and FIG. 5B is a longitudinal sectional view seen from the long side direction. In the conventional flat nozzle shown in FIG. 5, the upper part 23a of the molten metal channel 23 is formed in a cylindrical shape, and the middle part 23b has a tapered shape with a long side and a tapered shape with a short side. The lower part 23c is formed in a flat shape, and a molten metal discharge hole 24 is formed on both side walls of the short side.
[0009]
As described above, the flat nozzle shown in FIG. 5 has a molten metal flow in two directions in order to suppress solidification and adhesion of the molten metal (metal) in the flat and narrow molten metal channel 23. Molten metal discharge holes 24 are formed so as to be discharged.
[0010]
[Problems to be solved by the invention]
However, for example, when the flow rate of the tundish to which the nozzle is connected is controlled by the stopper head, it is difficult to precisely control the flow rate at the start of casting. Therefore, the flat shape in which the two-direction molten metal discharge holes 24 are formed is formed. In the case of the nozzle, the molten metal flow rate from the molten metal discharge hole 24 at the start of casting tended to be relatively large.
[0011]
Further, since the molten metal discharge holes 24 in the two directions are configured so that the molten metal flow strikes the mold side wall, a lot of splash is likely to occur at the initial stage of casting operation. When the splash solidifies above the mold, when the cast piece starts to be pulled out, the solidified piece remains as a foreign substance, and there is a risk that the solidified shell in the mold breaks from the location and induces breakout.
[0012]
The present invention has been made to solve the above technical problem, and prevents the molten metal from drifting in the nozzle and the mold and fluctuations in the molten metal surface even when used for a long period of time. Another object of the present invention is to provide an immersion nozzle for continuous casting of a thin slab capable of stably supplying a high-quality thin slab slab by suppressing damage and the like.
[0014]
[Means for Solving the Problems]
  According to the present inventionThe thin slab continuous casting immersion nozzle comprises a molten metal inlet at the upper end, a tubular molten metal channel extending downward from the molten metal inlet, a molten metal discharge hole at the lower end, and the molten metal flow A thin slab continuous casting immersion nozzle comprising a cylindrical upper portion, an intermediate portion deformed from a cylindrical shape into a flat shape, and a lower portion having a flat straight tube shape. A thick taper shape, a short side taper taper is formed, and the long side taper and the short side taper start point and end point height positions are different from each other. An escape hole is formed in the center of the bottom surface, and the opening area of the escape hole is 20% or more and 40% or less of the cross-sectional area of the straight tubular portion below the molten metal flow path.
  By forming the escape hole, it is possible to suppress the lateral flow at the initial stage of casting operation and prevent the occurrence of splash due to the initial molten metal flow having a high flow velocity hitting the mold side wall.
  In addition, with the above configuration, contact between the solidified shell in the mold and the lower end of the nozzle can be prevented, and an unstable molten metal flow such as a drift is suppressed, so that the high quality is stable for a long time. A thin slab slab can be obtained.
[0015]
  In the nozzleIsThe cross-sectional area of the flattened tubular portion at the bottom of the molten metal channel is preferably 95% or more and 105% or less of the cross-sectional area of the upper cylindrical portion.
  In this way, by making the cross-sectional area of the molten metal flow path near the inlet of the molten metal and the discharge hole nearly equal, the molten metal fluctuations in the mold are prevented, and the mold powder accompanying the uneven flow It is possible to prevent the deterioration of the quality of the slab due to the entrainment of.
[0016]
In the nozzle according to the present invention, at least a portion immersed in the molten metal is preferably made of a refractory material that does not contain vitreous silica.
As a result, adhesion of molten metal to the nozzle, prevention of melt damage of the nozzle, and improvement in strength near the escape hole can be achieved, so that the strength is maintained even if the escape hole is formed in the bottom wall of the nozzle. Can be used stably for a long time.
[0017]
Furthermore, it is preferable that the difference between the height positions of the end points of the long side taper and the short side taper of the intermediate portion of the molten metal flow path is 10 mm or more.
As described above, when the taper is shifted on the long side and the short side, the height position of the end point has a difference of 10 mm or more, which is due to the concentration of thermal stress on the taper end point. It is possible to effectively avoid cracks and breakage of the nozzle.
[0018]
The molten metal discharge hole is formed from the short side of the nozzle lower end side wall to the side of the planar bottom wall, and the angle α formed by the nozzle lower end side wall forming the molten metal discharge hole with respect to the horizontal plane, and The angle β formed by the side of the bottom wall forming the molten metal discharge hole and its horizontal plane is preferably 0 ° ≦ α ≦ 60 ° and 30 ° ≦ β ≦ 80 °.
In this way, by forming the molten metal discharge hole in an L shape at an angle in the above range from the short side of the nozzle lower end side wall to the bottom wall, the direction of the molten metal flow is appropriately controlled, and in the mold The drift of the molten metal can be prevented.
In addition, the molten metal discharge hole can avoid the fluctuation of the molten metal surface in the mold, the mixing of the mold powder on the molten metal surface into the thin slab slab, etc. It can be lifted and removed to improve the quality of the slab.
[0019]
Furthermore, it is preferable that the molten metal discharge hole has a notch length in the long side direction of the nozzle bottom wall of 75% or more and 200% or less of the wall thickness of the short side wall.
By configuring the molten metal discharge hole in this manner, it is possible to adjust the lateral flow and the downward flow of the molten metal in the mold to an appropriate state, to suppress the drift, and a sufficient molten metal flow rate and A flow rate can be obtained.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.
FIG. 1 is a schematic longitudinal sectional view showing an example of an immersion nozzle for continuous casting of a thin slab according to the present invention, wherein (a) shows a short side and (b) shows a long side.
As shown in FIGS. 1A and 1B, a nozzle 1 according to the present invention includes an upper end molten metal inlet 2, and a tubular molten metal passage 3 extending downward from the molten metal inlet 2. The molten metal discharge hole 4 is provided at the lower end, and the upper part 3a of the molten metal flow path 3 is formed in a cylindrical shape and the lower part 3c is formed in a flat straight tube shape. Further, the intermediate part 3b of the molten metal flow path 3 is formed in a taper shape having a tapered side on the long side and a taper shape having a tapered side on the short side.
Here, the flat straight tube means a flat cross-sectional shape in which the widths of the long side and the short side are not substantially changed in the fragment shape of each height nozzle. And in the cross section of the said flat tube part, it is preferable that ratio of the internal diameter of a short side side and a long side is short side side: long side side = 1: 2-1:10.
Moreover, in the flat straight tubular portion, the corner portion is preferably chamfered in a curved shape on both the inner wall and the outer wall, and more preferably, the short side is formed in a semicircular shape.
[0021]
As described above, the lower portion 3c has a flat shape, but is not formed in a divergent shape, but is formed in a straight tubular shape, so that it is difficult to receive a biased thermal stress during use, and cracks, breakage, and the like can be prevented. .
In addition, the fact that the lower portion 3c is a straight tube also suppresses unstable molten metal flow such as turbulent flow, pulsating flow, and drift, and also prevents breakout due to contact between the solidified shell in the mold and the lower end of the nozzle. It is valid.
[0022]
2 is an enlarged cross-sectional view of the nozzle shown in FIG. 1 in the molten metal flow direction, where (a) shows a cross section of the cylindrical portion of the upper portion 3a, and (b) shows a cross section of the flat straight tubular portion of the lower portion 3c. Is.
As shown in FIGS. 2 (a) and 2 (b), the cross section of the molten metal flow path of the nozzle according to the present invention has a circular shape in the upper part 3a and a flat and substantially rectangular shape in the lower part 3c. The short side is formed in a curved surface.
And in this invention, the cross-sectional area S in the flat straight tubular part of the lower part 3c of this molten metal flow path_3cIs the cross-sectional area S in the cross-section of the cylindrical portion of the upper part 3a._3a95% or more and 105% or less, more preferably S_3aAnd S_3cAre formed to be equal.
[0023]
Cross-sectional area S in the flat straight tubular portion of the lower part 3c of the molten metal channel_3cIs the cross-sectional area S in the cross-section of the cylindrical portion of the upper part 3a._3aWhen the ratio is less than 95%, the flow rate of the molten metal discharge flow from the nozzle discharge hole increases, so that the molten metal level in the mold is likely to change.
On the other hand, the cross-sectional area S in the flat straight tubular portion of the lower part 3c of the molten metal channel_3cIs the cross-sectional area S in the cross-section of the cylindrical portion of the upper part 3a._3aIf it exceeds 105%, it is difficult to obtain a full flow in the entire molten metal flow path in the nozzle, and uneven flow is likely to occur, and the quality of the resulting slab is likely to deteriorate due to the entrainment of mold powder.
Therefore, S_3a= S_3cIt is most preferable to make the cross-sectional area of the molten metal flow path near the molten metal inlet and the discharge hole equal, thereby preventing the molten metal from fluctuating in the mold. It is possible to prevent deterioration of the quality of the slab due to the entrainment of powder.
[0024]
Moreover, in the nozzle shown in FIG. 1, the escape hole 6 is formed in the center part of the bottom face of the nozzle bottom wall.
For example, when the flow rate of the tundish to which the nozzle is connected is controlled by the stopper head, the molten metal flow rate 3c at the start of casting tends to be relatively large because the flat molten metal flow channel 3c of the nozzle is straight. .
Further, since the molten metal discharge hole 4 is configured so that the molten metal flow strikes the mold side wall, a lot of splash is likely to occur at the initial stage of casting operation. When the splash solidifies above the mold, when the slab starts to be pulled out, the solidified piece remains as a foreign substance, and the solidified shell in the mold may be broken from the location, which may induce breakout.
Accordingly, a flat straight tubular molten metal flow path as described above is formed in the lower portion 3c, and the escape hole 6 is provided, so that a part of the molten metal flow to be discharged is escaped at the initial stage of casting operation. It can be guided to the hole 6 to suppress the lateral flow, and the occurrence of splash due to the initial molten metal flow having a high flow velocity hitting the mold side wall can be prevented.
[0025]
The opening area of the escape hole 6 is not less than 20% and not more than 40% of the cross-sectional area of the straight tubular portion of the lower part 3c of the molten metal flow channel from the viewpoint of preventing generation of unstable molten metal flow. It is preferable. More preferably, it is 25% or more and 35% or less.
When the ratio of the opening area of the escape hole 6 is less than 20%, the molten metal hardly flows out from the escape hole 6 and it is difficult to serve as the escape hole as described above.
On the other hand, when the opening area exceeds 40%, the strength of the nozzle bottom wall is lowered.
In addition, it is preferable that the cross-sectional shape of the said escape hole 6 is a shape which does not have an angle | corner from a viewpoint of intensity | strength, for example, circular, an ellipse, etc.
[0026]
In the intermediate part 3b of the molten metal flow path 3, the taper start point B on the long side and the taper start point B ′ on the short side and the taper end point C on the long side and the taper end point on the short side are provided. The height positions of C ′ are different from each other.
In the nozzle according to the present invention, the taper start point B on the long side and the taper start point B ′ on the short side, and the taper end point C on the long side and the taper end point C ′ on the short side are respectively By being located at different heights, the concentration of thermal stress on these portions during use is suppressed, and damage to the nozzles such as cracks and breakage due to the concentration can be avoided.
[0027]
The height position of the end point C of the long side taper and the end point C ′ of the short side taper is preferably 10 mm or more from the viewpoint of effectively avoiding the concentration of the thermal stress.
It should be noted that the vertical position of the height position of the taper end point C ′ on the long side and the taper end point C ′ on the short side does not matter.
[0028]
Moreover, in the said nozzle, it is preferable that the part 5 immersed in a molten metal is comprised with the refractory material which does not contain glassy silica.
Conventionally, a refractory material containing glassy silica has been used for the portion 5 immersed in the molten metal of the nozzle for the purpose of improving the spalling resistance.
However, it is known that the vitreous silica disappears at about 1400 ° C. in a reducing atmosphere, and disappeared during use of the nozzle at a high temperature of 1500 ° C. or more, and contained vitreous silica. Refractory material is easily made porous. For this reason, when the molten metal infiltrated into the generated pores, the base metal is likely to adhere, and the strength is lowered due to melt damage of the nozzle.
Also, when a relief hole is formed in the bottom wall of a nozzle using a refractory material containing glassy silica and used for a long time, the escape hole is blocked due to adhesion of molten metal, or the strength is reduced due to melting damage. The vicinity of the escape hole was easily damaged.
Therefore, from the viewpoint of preventing adhesion of the molten metal due to the porous silica component, it is preferable to use a material that does not contain glassy silica as the refractory material constituting the portion 5 immersed in the molten metal.
[0029]
Examples of the refractory material that does not contain the vitreous silica and can be suitably used for the nozzle according to the present invention include alumina-graphite material, zirconia-graphite material, magnesia-graphite material, and the like. it can.
[0030]
In addition, the refractory material does not contain glassy silica, but even if the crystalline silica compound is contained in an amount of about 5% or less, it does not cause a blockage of the escape hole or damage near the escape hole. There is no problem. Specifically, for example, pyrophyllite (Al₂O_Three・ 4SiO₂・ H₂Olite, the main component of kaolinite (Al)₂O_Three・ 2SiO₂・ 2H₂Sasame clay or the like mainly composed of O) can be used as a refractory material raw material constituting the portion 5 immersed in the molten metal.
[0031]
By using a refractory material that does not contain glassy silica as described above, it is possible to prevent adhesion of molten metal to the nozzle, prevent melt damage of the nozzle, and improve strength near the escape hole. Even in this case, there is no blockage of the escape hole or breakage in the vicinity of the escape hole, and it can be used stably.
Furthermore, it is possible to increase the opening area of the escape hole as compared with the conventional case.
In addition, you may apply the said material also to the refractory material which comprises parts other than the part 5 immersed in molten metal.
[0032]
The molten metal discharge hole 4 is formed from the short side of the nozzle lower end side wall to the side of the flat bottom wall, and the angle α formed by the nozzle lower end side wall forming the molten metal discharge hole with respect to the horizontal plane, In addition, it is preferable that the angle β formed by the side portion of the bottom wall forming the molten metal discharge hole and the horizontal plane is 0 ° ≦ α ≦ 60 ° and 30 ° ≦ β ≦ 80 °.
As described above, the molten metal discharge hole 4 is not straight but is formed in an L shape from the short side of the nozzle lower end side wall to the bottom wall, whereby a substantially horizontal molten metal discharge flow can be obtained. Then, by applying the molten metal flow to the mold side wall to generate an upward flow, non-metallic inclusions in the molten metal can be lifted and removed, and the quality of the slab can be improved.
Moreover, the drift of the molten metal in the mold can be prevented, and fluctuations in the molten metal surface that cause deterioration in the quality of the slab, and mixing of mold powder on the molten metal surface into the thin slab slab are avoided. be able to.
[0033]
Further, the L-shaped discharge hole 4 has a tapered lower end side wall to be formed, an angle α with respect to the horizontal plane is 0 ° ≦ α ≦ 60 °, and the bottom wall forming the discharge hole is The direction of the molten metal flow can be appropriately controlled by forming a divergent gradient so that the angle β with respect to the horizontal plane is 30 ° ≦ β ≦ 80 °.
[0034]
FIG. 3 shows an enlarged view of a portion A of the nozzle shown in FIG. As shown in FIG. 3, in the molten metal discharge hole 4, the notch T in the long side direction of the nozzle bottom wall has a length of 75% or more and 200% or less of the wall thickness t of the side wall on the short side, that is, And 75% ≦ T / t ≦ 200%.
When the angle β is less than 30 °, if T / t is less than 75%, there is little downward flow of molten metal, and there is much lateral flow. It tends to occur.
On the other hand, when the angle β is 80 ° or more, if T / t exceeds 200%, the lateral flow of the molten metal is small, and the molten metal is easily solidified in the vicinity of the nozzle on the molten metal surface.
[0035]
FIG. 4 shows the usage pattern of the nozzle as shown in FIG. 1 and the pattern of the molten metal flow. As shown in FIG. 4, the thin slab continuous casting immersion nozzle 1 according to the present invention is attached to the bottom of a tundish 11, and the molten metal inlet 2 at the upper end of the nozzle 1 is melted from the tundish 11. A stopper head 12 for controlling the metal flow rate is provided. The lower portion of the nozzle is disposed in the thin slab mold 14.
By raising the stopper head 12 with the above apparatus configuration, the molten metal 19 is injected from the tundish 11 through the molten metal flow path 3 in the nozzle 1 into the mold 14.
The thin slab mold 14 is generally flat with a long side of 9000 mm or more and a short side of 150 mm or less. The portion immersed in the mold 14 of the nozzle 1 is formed in a shape corresponding to the size of the flat mold 14.
[0036]
As shown in FIG. 4, the molten metal discharged from the molten metal discharge hole of the nozzle generates a side flow F1 and a downward flow F2 in a balanced manner in the mold.
Further, the escape hole 6 in the bottom wall of the nozzle 1 prevents the occurrence of splash due to the side flow F1 in the initial casting operation.
[0037]
The lateral flow F1 flows in a substantially horizontal direction toward the side wall of the mold 14 and becomes an upward flow after contacting the side wall of the mold 14. Due to this upward flow, inclusions in the molten metal can be floated and melted in the mold powder to be removed, so that defects in the cast metal can be reduced.
[0038]
On the other hand, the downward flow F <b> 2 flows obliquely downward and becomes a gentle downward flow along the side wall of the mold 14 after contacting the side wall of the mold 14.
As described above, by using the nozzle, it is possible to prevent the molten metal discharged from the molten metal discharge hole 4 from generating an unstable molten metal flow such as a drift in the mold 14.
[0039]
【Example】
EXAMPLES Hereinafter, although this invention is demonstrated further more concretely based on an Example, this invention is not restrict | limited by the following Example.
[Example 1]
A continuous casting test of 2100 t of molten steel was performed using an immersion nozzle for continuous casting of thin slab as shown in FIG. 1 and a mold for thin slab of 900 mm × 80 mm.
In this immersion nozzle, the portion 5 immersed in the molten steel is made of an alumina-graphite material, and the end C of the long side taper in the intermediate portion 3b is 50 mm lower than the end C 'of the short side taper. In addition, α = 45 °, β = 60 °, T / t = 150%, and the opening area of the escape hole was formed to be 30% of the cross-sectional area of the straight tubular portion of the nozzle lower portion 3c.
Moreover, in this immersion nozzle, the cross-sectional area S in the flat straight tubular part of the lower part 3c of the molten metal flow path._3cIs the cross-sectional area S in the cross section of the cylindrical part of the upper part 3a._3aIs equal to, that is, S_3a= S_3cIt is.
The test results are shown in Table 1.
[0040]
[Comparative Example 1]
A continuous casting test was performed in the same manner as in Example 1 except that a conventional thin slab continuous casting immersion nozzle having no relief hole formed in the nozzle bottom wall as shown in FIG. 5 was used.
The test results are shown in Table 1.
[0041]
[Comparative Example 2]
A continuous casting test is performed in the same manner as in Example 1 except that the portion immersed in the molten steel is alumina-graphite containing 22% by weight of silica, and the immersion nozzle configured in the same manner as in Example 1 is used. It was.
The test results are shown in Table 1.
[0042]
[Comparative Example 3]
In the intermediate part 3b, the end point C of the long side taper and the end point C ′ of the short side taper are set to the same height position, and other than that, using an immersion nozzle configured in the same manner as in Example 1, When a continuous casting test was performed in the same manner as in Example 1, since the cracks occurred at the taper end points C and C ′ in 100 minutes from the start of casting, the casting was stopped.
[0043]
[Table 1]

[0044]
As shown in Table 1, in the nozzle (Example 1) in which the escape holes were formed, the occurrence of breakout due to splash was not observed, but the conventional discharge holes only in two directions were formed. In the nozzle (Comparative Example 1), one breakout occurred due to splash.
Moreover, in Example 1, compared with the case where the part immersed in molten steel contains silica (Comparative Example 1), the adhesion of the metal on the lower outer periphery is suppressed, and it can be used stably for a long time. Admitted.
In particular, in Example 1, by reducing the deposits, there is little fluctuation of the molten metal surface at the end of long-term use, the molten layer of the mold powder existing on the mold surface is made uniform, and the generation of slag bear is completely achieved. It was found to be suppressed.
[0045]
[Comparative Example 4]
Cross-sectional area S in the flat straight tubular portion of the lower part 3c of the molten metal channel_3cIs the cross-sectional area S in the cross section of the cylindrical portion of the upper part 3a._3aFor the other cases, a continuous casting test was performed in the same manner as in Example 1 using an immersion nozzle configured in the same manner as in Example 1.
In this test, the molten metal surface level in the mold and the mold powder entrainment defect in the slab were evaluated.
These results are shown in Table 2 together with Example 1.
[0046]
[Comparative Example 5]
Cross-sectional area S in the flat straight tubular portion of the lower part 3c of the molten metal channel_3cIs the cross-sectional area S in the cross section of the cylindrical portion of the upper part 3a._3aFor the other cases, a continuous casting test was conducted in the same manner as in Example 1 using an immersion nozzle configured in the same manner as in Example 1.
In this test, the molten metal surface level in the mold and the mold powder entrainment defect in the slab were evaluated.
These results are shown in Table 2.
[0047]
[Table 2]

[0048]
As shown in Table 2, S_3cIs S_3aWhen the ratio is less than 95% (Comparative Example 4), although there are few mold powder entrainment defects, the molten metal surface fluctuation in the mold is large._3cIs S_3aWhen the ratio exceeds 105% (Comparative Example 5), the mold surface fluctuation in the mold is small, but many mold powder entrainment defects are observed, and favorable results are obtained with any nozzle in terms of the quality of the slab. I couldn't.
In contrast, S_3cIs S_3aNo. 95% or more and 105% or less (Example 1), there is no mold surface fluctuation in the mold, and no mold powder entrainment defects are observed. It has been found effective in obtaining quality slabs.
[0049]
【The invention's effect】
As described above, the immersion nozzle for continuous casting of a thin slab according to the present invention prevents the molten metal from drifting in the nozzle and the mold and fluctuations in the molten metal surface even when used for a long time, and adheres to and damages the nozzle metal. Etc. can be suppressed.
Therefore, by using the immersion nozzle for continuous casting of thin slab according to the present invention, a high quality thin slab cast can be stably supplied continuously for a long time.
[Brief description of the drawings]
FIG. 1 is a schematic longitudinal sectional view of an immersion nozzle for continuous casting of a thin slab according to the present invention, wherein (a) is a short side and (b) is a cross sectional view showing a long side.
2 is an enlarged cross-sectional view of the nozzle shown in FIG. 1 with respect to the molten metal flow direction, in which (a) shows a cross-section at the upper part 3a and (b) shows a cross-section at the lower part 3c.
FIG. 3 is an enlarged view of a portion A in FIG.
FIG. 4 is a schematic view showing the usage mode of the nozzle shown in FIG. 1 and the flow state of the molten metal.
FIGS. 5A and 5B are schematic longitudinal sectional views showing an example of a conventional immersion nozzle for thin slab continuous casting, in which FIG. 5A shows a short side and FIG. 5B shows a long side.
[Explanation of symbols]
1 Immersion nozzle
2 Molten metal inlet
3, 23 Molten metal flow path
3a, 23a upper part
3b, 23b middle part
3c, 23c Bottom
4 Molten metal discharge hole
5 Immersion part
6 escape hole
B Starting point of taper on long side
B 'Start point of short side taper
C, end point of long side taper
C 'End of taper on short side
T Notch length in the long side direction
t Wall thickness on the short side
11 Tundish
12 Stopper head
13 Molten metal (molten steel)
14 Mold
F1 lateral flow
F2 downward flow

Claims (6)

A molten metal inflow port at the upper end, a tubular molten metal channel extending downward from the molten metal inflow port, a molten metal discharge hole at the lower end, and the molten metal channel has a cylindrical upper portion, a cylindrical shape In the submerged nozzle for thin slab continuous casting composed of an intermediate part deformed into a flat shape, a flat straight tubular lower part,
The intermediate part of the molten metal flow path is formed with a tapered shape with a long side and a tapered shape with a short side, and the height of the start and end points of the long side taper and the short side taper. Configured to have different positions,
An escape hole is formed in the bottom center of the nozzle bottom wall, and the opening area of the escape hole is not less than 20% and not more than 40% of the cross-sectional area of the straight tubular portion below the molten metal flow path. An immersion nozzle for continuous casting of thin slabs. The cross-sectional area of the lower portion of the flat straight tube portion of the molten metal passage, dipping thin slab continuous casting according to claim 1, wherein a is not more than 105% 95% of the cross-sectional area of the cylindrical portion of the upper nozzle. The immersion nozzle for thin slab continuous casting according to claim 1 or 2, wherein at least a portion immersed in the molten metal is made of a refractory material containing no vitreous silica. An intermediate portion of the molten metal passage, according to claim 1, the difference between the height position of the end point of the long side of the taper and the short side taper is characterized in that at 10mm or more to 3 Immersion nozzle for continuous casting of thin slabs. The molten metal discharge hole is formed from the short side of the lower end side wall of the nozzle to the side of the flat bottom wall,
The angle α formed by the nozzle lower end side wall forming the molten metal discharge hole with respect to the horizontal plane, and the angle β formed by the side portion of the bottom wall forming the molten metal discharge hole formed by the horizontal plane are:
0 ° ≦ α ≦ 60 °
30 ° ≦ β ≦ 80 °
The immersion nozzle for continuous casting of a thin slab according to any one of claims 1 to 4 , wherein the nozzle is for continuous casting. 6. The thin slab according to claim 5, wherein the molten metal discharge hole has a notch length in a long side direction of a nozzle bottom wall of 75% or more and 200% or less of a wall thickness of a short side wall. Immersion nozzle for continuous casting.

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