JP3633573B2 - Continuous casting method - Google Patents

Description

【００６０】
試験番号１では、定常鋳込は、その圧下量δ_１が２０ｍｍとなるように段階的バルジング形式で行った。鋳込み終了後は、バルジングロールについては、開放速度α（ｔ）を０．１４ｍｍ／ｓｅｃとして、Ｎｏ．１セグメント、Ｎｏ．２セグメントおよびＮｏ．３セグメントを同時に、それぞれの開放量が６ｍｍ、４ｍｍおよび２ｍｍとなるまで開放し、その他のセグメントについては開放しなかった。一方、圧下ロールについては、開放速度を０．３ｍｍ／ｓｅｃとして、Ｎｏ．１〜４の全ての圧下ロールを同時に、それぞれの開放量が１１ｍｍとなるまで開放した。
【００６１】
試験番号２では、定常鋳込は、その圧下量δ_１が２０ｍｍとなるように段階的バルジング形式で行った。鋳込み終了後は、バルジングロールについては、開放速度α（ｔ）を０．１４ｍｍ／ｓｅｃとして、Ｎｏ．１〜９セグメントを下記の要領で開放した。
【００６２】
まず、Ｎｏ．１セグメントを２ｍｍ開放し、この開放が終了した後、Ｎｏ．２セグメントを２ｍｍ開放し、同じ要領で各セグメントをそれぞれ２ｍｍずつ開放して、Ｎｏ．９セグメントまで開放した。その後、同じ要領で、Ｎｏ．１セグメントからＮｏ．８セグメントまでを更に２ｍｍ開放し、さらに、Ｎｏ．１セグメントからＮｏ．７までを２ｍｍ開放した。このような作業を繰り返し、最終的には、Ｎｏ．１セグメントの開放量が１８ｍｍ、Ｎｏ．２セグメントの開放量が１６ｍｍ、…Ｎｏ．９セグメントの開放量が２ｍｍとなるように開放した。一方、圧下ロールについては開放しなかった。
【００６３】
試験番号３では、定常鋳込は、その圧下量δ_１が２０ｍｍとなるように段階的バルジング形式で行った。鋳込み終了後は、バルジングロールについては、開放しなかった。一方、圧下ロールについては、開放速度を０．３ｍｍ／ｓｅｃとして、全ての圧下ロールを同時に、それぞれの開放量が１１ｍｍとなるまで開放した。
【００６４】
試験番号４では、定常鋳込は、その圧下量δ_１が２０ｍｍとなるように段階的バルジング形式で行った。鋳込み終了後は、バルジングロールについては、開放速度α（ｔ）を０．１４ｍｍ／ｓｅｃとして、Ｎｏ．１〜１０の全てのセグメントを２セグメント毎に順次、各セグメントの開放量が１．５ｍｍとなるまで開放した。具体的には、まず、Ｎｏ．１および２セグメントをそれぞれ１．５ｍｍ開放し、これらの開放が終了した後、Ｎｏ．３および４セグメントをそれぞれ１．５ｍｍ開放し、その後、Ｎｏ．５および６セグメント、Ｎｏ．７および８セグメント、並びにＮｏ．９および１０セグメントについても同じ要領でそれぞれ１．５ｍｍとなるまで開放した。一方、圧下ロールについては、開放速度を０．３ｍｍ／ｓｅｃとして、Ｎｏ．１〜４の全ての圧下ロールを同時に、それぞれの開放量が１．５ｍｍとなるまで開放した。
【００６５】
試験番号５では、定常鋳込は、その圧下量δ_１が２０ｍｍとなるように一括バルジング形式で行った。鋳込み終了後は、バルジングロールについては、開放速度を０．１４ｍｍ／ｓｅｃとして、Ｎｏ．１〜１０の全ての圧下ロールを同時に、それぞれの開放量が２０ｍｍとなるまで開放した。一方、圧下ロールについては、開放速度を０．３ｍｍ／ｓｅｃとして、Ｎｏ．１〜４の全ての圧下ロールを同時に、それぞれの開放量が２０ｍｍとなるまで開放した。
【００６６】
試験番号６では、定常鋳込は、その圧下量δ_１が１０ｍｍとなるように段階的バルジング形式で行った。鋳込み終了後は、バルジングロールについては、開放しなかった。一方、圧下ロールについては、開放速度を０．１ｍｍ／ｓｅｃとして、Ｎｏ．１〜４の全ての圧下ロールを同時に、それぞれの開放量が３ｍｍとなるまで開放した。
【００６７】
試験番号７では、定常鋳込は、その圧下量δ_１が２０ｍｍとなるように段階的バルジング形式で行った。鋳込み終了後は、バルジングロールについては、開放速度を０．２ｍｍ／ｓｅｃとして、Ｎｏ．１〜１０の全ての圧下ロールを同時に、それぞれの開放量が２０ｍｍとなるまで開放した。一方、圧下ロールについては、開放速度を０．３ｍｍ／ｓｅｃとして、Ｎｏ．１〜４の全ての圧下ロールを同時に、それぞれの開放量が２０ｍｍとなるまで開放した。
【００６８】
以上の製造条件から、前記の▲５▼式および▲６▼式を用いて、鋳片引抜中において、単位時間当たりに吸い込まれる鋳片未凝固部の体積変化量Ｖ_１（ｍｍ^３／ｓｅｃ）および単位時間当たりに押し出される鋳片未凝固部の体積変化量Ｖ_２（ｍｍ^３／ｓｅｃ）を算出し、前記の▲３▼式および▲４▼式を用いて、鋳片引抜中の鋳片内の湯面の変化速度Ｖ（ｍｍ／ｓｅｃ）および鋳片内の未凝固部湯面の変化量Ｓ（ｍｍ）を算出した。これらの結果を表２に示す。
【００６９】
なお、鋳片の幅（鋳片の長辺長さ）は、鋳込みおよび引抜の過程においてほとんど変動することはないため、鋳型幅（鋳型長辺長さ）Ｗ_１（ｍｍ）と同一であるとみなすことができる。従って、表２には、「Ｖ_１／Ｗ_１」および「Ｖ_２／Ｗ_１」の値を記載した。
【００７０】
本発明の効果を確認すべく、鋳片最終端部からの漏鋼の発生と、下記の要領で求めた鋳片ボトム部の中心偏析度の最大値、そして鋳片を圧延した後、超音波検査を行い内質の調査を実施した。また、鋳片最終端部の切り捨て長さについても評価した。これらの評価結果を表１に併記した。
【００７１】
中心偏析度は、りん（Ｐ）の最大偏析度で評価した。これは、得られた鋳片の最終端部から３ｍの位置で、鋳込み方向に垂直な断面で切断して、厚さ方向中心部から試験片を採取し、試験片の表面を２００μｍメッシュに区分し、各区分でＥＰＭＡ（エレクトリック・プローブ・マイクロ・アナライザー）を用いてＰ濃度を測定し、その中での最大Ｐ濃度［Ｐｍａｘ］と母溶鋼のＰの濃度［Ｐａｖｅ］との比（［Ｐｍａｘ］／［Ｐａｖｅ］）を算出して求めた。
【００７２】
【表２】

【００７３】
なお、鋳片最終端部の切り捨て長さは、その長さが５００ｍｍ未満であったものを「小」とし、５００ｍｍ以上１０００ｍｍ未満であったものを「中」とし、１０００ｍｍ以上であったものを「大」として表中に記載した。
【００７４】
本発明例の試験番号１〜５は、湯面変化速度Ｖと湯面変化量Ｓの値が本発明の範囲内となるように、バルジングロールおよび圧下ロールの開放方法を制御したものである。表２に示すように、本発明例１〜４では漏鋼は発生せず、圧延後の超音波検査でも不良は発生しなかった。ただし、試験番号１と３とでは圧下ロール群を開放させて、圧下ロール開放後の鋳片圧下量δ_２を定常部鋳片圧下量δ_１の４５％とした為に、Ｐ最大備析度は４．７とやや大きくなった。また、試験番号５では、湯面変化量Ｓの値が１１９３ｍｍと大きいため、漏鋼の発生はなかったが、鋳片最終端部の切り捨て量が増大し、歩留りが悪化するが、品質上の問題はない。
【００７５】
比較例の試験番号６〜８までは、湯面変化速度Ｖと湯面変化量Ｓのいずれかの値が本発明の範囲を外れるものである。試験番号６は、湯面変化量Ｓの値が−９．６ｍｍと小さいため、漏鋼が発生した。試験番号７および８は、Ｖの値が本発明で規定される範囲を超えるため、パウダー起因の超音波不良が発生した。特に、Ｓの値も本発明で規定される範囲を超える試験番号７では、切り捨て長さも５００ｍｍ以上となり、歩留りも悪化していた。
【００７６】
【発明の効果】
本発明の方法によれば、定常部鋳込みの際に鋳片の中心偏析をなくして鋳片の品質を改善できるだけでなく、鋳込末期の鋳片終端部におけるパウダー巻き込み等の品質不良を低減することができる。また、鋳片終端部の切り捨て量を最小限にして鋳造歩留まりを向上させることもできる。さらに、鋳込終了時に、未凝固溶鋼の鋳片最後端からの漏鋼等の操業時のトラブルを防止することができ、安定した操業が可能となる。また、本発明法の対象となる鋳片は、スラブでもブルーム（ビレツト）でもよいが、特に厚板鋼板の素材となるスラブの連続鋳造に好適である。
【００７７】
【図面の簡単な説明】
【図１】バルジング−圧下連続鋳造法を実施するための装置の一例を模式的に示す図である。
【図２】バルジング−圧下連続鋳造法を実施したときのロール位置と鋳片断面を示す模式図である。
【図３】本発明の連続鋳造方法におけるバルジングロールおよび圧下ロールの開放状況の一例を示す図であり、（ａ）は定常鋳込時の状態を示し、（ｂ）は鋳込終了後、鋳片引抜時の状態を示し、（ｃ）は各ロールの開放が終了した状態を示す。
【図４】上記の各記号を詳細に図示したものである。
【図５】バルジングロールを開放する際の制約条件を示す図である。
【図６】バルジングロールの開放方法の例を示す図である。
【図７】鋳込み中のバルジングロールの開放形式を示す図であり、（ａ）は段階的バルジングを示し、（ｂ）は一括バルジングを示す。
【符号の説明】
１．タンディシュ ２．溶鋼 ３．浸漬ノズル ４．鋳型 ５．鋳片
６．固相線クレータエンド ７ａ￣７ｎ．ガイドロール ８ａ￣８ｎ．圧下ロール
９．圧下装置 １０．ピンチロール[0001]
BACKGROUND OF THE INVENTION
The present invention provides a continuous casting machine that continuously reduces the center segregation of a steel slab by reducing the width of the slab in the short side direction (the thickness direction of the slab) of the guide roll and reducing the bulging. The present invention relates to a casting method, and more particularly to a slab drawing control method after completion of casting.
[0002]
[Prior art]
When steel slabs are manufactured by a continuous casting method, an internal defect called center segregation often occurs and becomes a problem. This center segregation is a phenomenon in which component elements such as C, Mn, S, and P in the molten steel are concentrated and positively segregated in the final solidified portion at the center in the thickness direction of the slab. It is known that this center segregation becomes a serious defect particularly in a thick steel plate and causes toughness reduction and hydrogen induced cracking in the segregated portion.
[0003]
The cause of the occurrence of such center segregation is that molten steel in which component elements such as C, Mn, S, and P are concentrated between dendrites at the end of solidification and solidifies as it is in the center of the slab thickness direction. In addition, the molten steel flows macroscopically toward the solidification completion point of the final solidified portion by the molten steel flow caused by expansion of the slab called shrinkage or bulging during solidification.
[0004]
Conventionally, bulging of a slab during casting has been considered to be avoided as much as possible because it causes a central segregation. However, in recent years, several casting methods have been proposed in which this bulging is actively caused and then the central segregation is reduced by reducing the bulging equivalent amount (for example, JP-A-60-21150, (See JP-A-1-178355, JP-A-9-57410, JP-A-9-206903, etc.). Hereinafter, this method is referred to as “bulging-reducing continuous casting method”.
[0005]
FIG. 1 is a diagram schematically showing an example of an apparatus for explaining the principle of the bulging-reducing continuous casting method.
[0006]
As shown in FIG. 1, the molten steel 2 stored in the tundish 1 is injected into the mold 4 through the immersion nozzle 3. The injected molten steel is cooled in the mold, forms a solidified shell 5a, becomes a slab 5, and is drawn out of the mold.
[0007]
In the continuous casting apparatus for carrying out the bulging-reducing continuous casting method, the rolls in the slab thickness direction of the rolls from the guide rolls 7a to 7n provided between the position immediately below the mold 4 and the solidus crater end 6 of the slab. Increase the interval step by step. And the reduction roll group 8a-8n is provided between the guide roll 7n and the solidus crater end 6. FIG. The range of the guide roll groups 7a to 7n expanded in stages is referred to as a bulging zone, and the range of the reduction roll groups 8a to 8n is referred to as a reduction zone. A reduction device 9 is provided for each reduction roll. It should be noted that at least a pair of reduction rolls may be provided in the reduction zone.
[0008]
The slab 5 is pulled out with the unsolidified molten steel 2 held therein, and actively causes bulging in the slab thickness direction in the bulging zone. The slab in which bulging has occurred is reduced by the reduction roll groups 8a to 8n in the reduction zone, and the solidification interface of the slab is pressed to complete the solidification. The solidified slab is pulled out by the pinch roll group 10.
[0009]
In the bulging-reducing continuous casting method, after the slab is bulged, the molten steel is squeezed out in the indented portion in order to reduce the equivalent amount of bulging. However, since the bulging amount and the reduction amount are set to be balanced during steady casting, the molten metal surface in the mold is kept substantially constant, and a stable slab is obtained. Also, even when the guide roll interval in the bulging zone and the reduction amount in the reduction zone change, while the molten steel is being supplied into the mold, there is a possibility that a problem will occur in terms of operation, although the molten metal level will vary. small.
[0010]
However, at the end of casting, when the molten steel is no longer supplied into the mold, the slab is pulled out and when the reduction is continued, the rear end (bottom) of the slab is removed from the mold. When it comes off, so-called “leakage” may occur in which the molten steel squeezed out from the slab overflows from the rear end of the slab.
[0011]
When steel leakage occurs, it not only poses a danger to workers near the mold, but also causes molten steel to adhere to and damage the guide rolls and spray nozzles. In addition, efforts are made to recover the solidified material adhering to the equipment and the replacement of damaged equipment, thereby hindering productivity.
[0012]
In order to prevent leakage of steel from the end of the slab at the end of casting, the reduction of the slab is stopped, the reduction zone is opened, and the slab reduction amount is set to zero. However, this increases the thickness of the slab, and the center segregation cannot be reduced, leaving a portion to be cut off, resulting in a deterioration in yield.
[0013]
Thus, several methods as described below have been proposed for the drawing control method at the end of casting.
[0014]
(1) The casting is finished and the slab is pulled out while maintaining the normal casting speed without reducing the casting speed or stopping the casting and processing the bottom part which is the rear end of the slab. The roll interval of the unsolidified part in the end slab is expanded to intentionally bulge the slab outer shell part, and then the widened part is crushed by a subsequent roll to obtain a predetermined slab thickness at the fully solidified part. (See JP-A-10-244347).
[0015]
(2) Method of making the volume of the bulging larger than the bulging volume at the time of steady casting while pulling out the slab while maintaining the steady drawing speed at the end of casting in the bulging-reducing continuous casting method (Japanese Patent Laid-Open No. 11-156508) ,reference).
[0016]
(3) In the bulging-continuous reduction casting method, the guide roll group and reduction amount are made smaller than those during steady casting and the reduction position is moved to the mold side as the casting speed is reduced at the end of casting. 156509).
[0017]
(4) In the bulging-reducing continuous casting method, the slab is squeezed with at least one pair of squeezing rolls provided in the downstream part of the mold while maintaining the steady casting speed, and the molten steel in the unsolidified part is pushed inward in the mold. Thus, a new solidified shell is formed while the end of the slab is in the mold, then the reduction is released, and the slab thickness of the indented portion is restored to the original thickness, and the molten steel in the unsolidified portion is By sucking in the casting direction and lowering the molten steel surface at the end of the slab, a recess is formed and the end of the slab is drawn from the mold at a drawing speed corresponding to the steady casting speed (Japanese Patent Laid-Open No. 9-314289). Issue gazette).
[0018]
In the above methods (1) and (2), it is possible to prevent leakage of steel at the initial stage of slab drawing by widening the roll interval of the guide roll group corresponding to the unsolidified portion of the slab and bulging the slab. However, there is a state where the slab is being squeezed downstream from the slab position where the roll interval is maximum. Thereby, as slab drawing progresses, the molten steel in the unsolidified portion may be squeezed out and leakage steel may be generated.
[0019]
In the invention of (3) above, since the casting speed is reduced at the end of casting, the slab final end is an unsteady part that is not stable at both the casting speed and secondary cooling, and compared with the slab steady part. The quality of the piece is not stable, and it is actually difficult to change the ideal guide roll group and the reduction amount corresponding to the reduction of the casting speed, which is problematic in operation.
[0020]
In the method of (4) above, while the final end of the slab is in the mold, the slab is once reduced to form a solidified shell with the unsolidified molten steel, and then the reduction is released to obtain the unsolidified molten steel. Is effective in preventing steel leakage, but the opening and closing work of the guide roll is complicated, so that the operability is inferior.
[0021]
In any of the above methods (1) to (4), since the roll interval of the guide roll group is increased and bulging is caused after the completion of casting, powder or the like is caught in the molten steel at the final end of the slab. The quality of the slab bottom portion may be deteriorated. Thus, none of the methods considers the suction phenomenon of the molten steel in the unsolidified part.
[0022]
[Problems to be solved by the invention]
The object of the present invention is to perform a gap control in the thickness direction of the slab thickness of the guide roll and the reduction roll in consideration of the suction phenomenon of the molten steel in the unsolidified portion at the end of casting in the bulging-reduction continuous casting method. It is an object of the present invention to provide a continuous casting method for producing a slab without causing leakage steel from the rearmost end and free from center segregation and howder entrainment defects.
[0023]
[Means for Solving the Problems]
The gist of the present invention is the continuous casting method shown in the following (1) to (3).
[0024]
(1) Widen the gap in the slab thickness direction of the guide roll in a predetermined range from the position corresponding to the liquid phase crater end to the position corresponding to the solid phase crater end of the slab, and after bulging the slab, It is a continuous casting method that uses a bulging equivalent amount or less, and the rate of change V (mm / sec) of the unsolidified molten metal surface in the slab during slab drawing after casting is as follows: The guide roll or rolling roll interval is opened under the condition that satisfies the formula (2) and the amount of change S (mm) of the unsolidified molten metal surface in the slab during slab drawing satisfies the formula (2) below. Continuous casting method.
[0025]
V ≦ 10… ▲ 1 ▼
S> 0… ▲ 2 ▼
However, V in the above formula (1) is a value obtained from the following formulas (3), (5) and (6), and S in formula (2) is the following formula (4), This is a value obtained from the equations (5) and (6).
[0026]
V = (V ₁ -V ₂ ) / (T ₁ ・ W ₁ )… ▲ 3 ▼
S = ∫ (V ₁ -V ₂ ) Dt / (t ₁ ・ W ₁ )… ▲ 4 ▼
V ₁ = W ₁ ・ Σ {Ln · α (t)} + W ₁ ・ Σ {Lm · β (t)} (5)
V ₂ = Vc (t) · δ (t) · W ₁ … ▲ 6 ▼
In addition, V in the above formulas (3) to (6) ₁ Is the volume change (mm) of the unsolidified part of the slab sucked per unit time during slab drawing ³ / Sec) and V ₂ Is the volume change (mm) of the unsolidified part of the slab extruded per unit time during slab drawing ³ / Sec), t ₁ Indicates the mold thickness (mold short side length) (mm), W ₁ Is the mold width (length of the mold long side) (mm), and Ln is the slab direction length (mm) of the guide roll segment of the bulging zone that is open during slab drawing. N indicates the number assigned to the guide roll segment in the bulging zone in order from the upstream side, and Lm indicates the slab direction of the reduction roll segment in the range of the reduction roll segment in the reduction zone that is opened during slab drawing. The length (mm) is indicated, m is the number assigned to the reduction roll segment in the reduction zone in order from the upstream side, α (t) is the guide roll segment opening speed (mm / sec), β (t ) Indicates the release speed (mm / sec) of the rolling roll segment, Vc (t) indicates the drawing speed (mm / sec) of the slab, and δ (t) is The slab reduction amount (mm) by the reduction roll is shown.
[0027]
(2) The continuous roll according to (1) above, wherein the guide roll or the rolling roll is opened under a condition that the amount of change S (mm) of the unsolidified molten metal surface satisfies the following expression (7): Casting method.
[0028]
0 <S ≦ 500… ▲ 7 ▼
(3) The above-mentioned (1) or (2), wherein after the slab is drawn, the final end of the slab is cut off so that the length L (mm) satisfies the following formula (8): The continuous casting method described in 1.
[0029]
S ≦ L… ▲ 8 ▼
[0030]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, “bulging roll” means a guide roll in the bulging zone, and “reduction roll” means a reduction roll in the reduction zone. Unless specifically limited, when “roll” is simply described, both a bulging roll and a rolling roll are shown.
[0031]
(1) Operation during steady casting
FIG. 2 is a diagram schematically showing a roll position and a slab cross section when the bulging-reducing continuous casting method is performed. As shown in FIG. 2, the slab is, for example, the maximum thickness of the slab (t _max ) Is the mold short side length (t ₁ 1.1 times to 1.5 times (in the figure, the bulging amount is the reduction amount δ ₁ Bulging so as to be equal to 2), and then a reduction equivalent to or less than the bulging amount is applied in the reduction zone. The amount of reduction (δ ₁ ), As shown in the figure, it is usually equivalent to the bulging amount and is cast with the same thickness as the short side of the mold, but the reduction amount is smaller than the bulging amount and the casting is slightly thicker than the short side of the mold. It is good also as a piece.
[0032]
(2) Operation after casting
FIG. 3 is a diagram showing an example of the operation status of the bulging roll and the reduction roll in the continuous casting method of the present invention, (a) shows the state at the time of steady casting, and (b) shows the state after casting is finished. The state at the time of one drawing is shown, (c) shows the state where the release of each roll is completed. Here, “at the time of slab drawing after the end of casting” refers to the time after the time when the supply of molten steel into the mold is stopped. In addition, the dashed-dotted line in FIG.3 (b) and (c) shows the state at the time of steady casting (state of figure (a)).
[0033]
As shown in FIG. 3, in the method of the present invention, from the open state of the roll at the time of steady casting (see FIG. Each is opened at a constant speed (see FIG. (B)), and each roll is opened to a predetermined position during drawing of the slab (see FIG. (C)). Therefore, when the slab is drawn, the unsolidified part of the slab is sucked into the slab by the volume which increases with the opening of the bulging roll and the reduction roll. Since it is narrower than that of the roll, only the volume which decreases with the difference between these gaps is pushed out to the upstream side of the slab. The method of the present invention adjusts the balance between the suction amount of the slab unsolidified portion and the extrusion amount, and specifically, it is controlled in the following manner.
[0034]
(A) About change rate V (mm / sec) of unsolidified molten metal surface
The change rate V (mm / sec) of the unsolidified molten metal surface in the slab during slab drawing after the end of casting is per unit time by further opening the bulging roll and the reduction roll during slab drawing. Volume change V of the slab unsolidified part ₁ (Mm ³ / Sec) and the volume change V of the unsolidified portion of the slab extruded per unit time due to the reduction amount of the reduction roll V ₂ (Mm ³ The volume change, which is the difference from / sec), is the cross-sectional area of the slab (mm ² ). The cross-sectional area of the slab (mm ² ) Is the mold thickness (mold short side length) t ₁ (Mm) and mold width (mold long side length) W ₁ It is expressed as a product of (mm).
[0035]
This relationship can be expressed by the following equation (3).
[0036]
V = (V ₁ -V ₂ ) / (T ₁ ・ W ₁ )… ▲ 3 ▼
Here, “change rate of unsolidified molten metal surface in the slab” is the rate at which the molten metal surface in the solidified shell during slab drawing in the slab fluctuates, taking into account the slab drawing speed. It is the fluctuation speed of the hot water surface. Further, during the slab drawing, the volume change amount V of the slab unsolidified portion sucked per unit time. ₁ (Mm ³ / Sec) and the volume change V of the slab unsolidified portion extruded per unit time ₂ (Mm ³ / Sec) is obtained by the following equations (5) and (6).
[0037]
V ₁ = W ₁ ・ Σ {Ln · α (t)} + W ₁ ・ Σ {Lm · β (t)} (5)
V ₂ = Vc (t) · δ (t) · W ₁ … ▲ 6 ▼
However, the meanings of the symbols in the above formulas (5) and (6) are as follows. That is, Ln indicates the slab direction length (mm) of the guide roll segment in the range of the guide roll segment in the bulging zone that is opened during slab drawing, and n indicates the upstream side of the guide roll segment in the bulging zone. The numbers given in order are shown, Lm indicates the slab direction length (mm) of the rolling roll segment in the range of the rolling roll segment in the rolling zone that is opened during slab drawing, and m is the rolling in the rolling zone. For the roll segment, the number assigned in order from the upstream side is shown, α (t) indicates the release speed (mm / sec) of the guide roll segment, and β (t) indicates the release speed (mm / sec) of the rolling roll segment. Vc (t) indicates the drawing speed (mm / sec) of the slab, and δ (t) indicates the slab reduction amount (mm) by the reduction roll. Show.
[0038]
FIG. 4 shows the above symbols in detail. In addition, the state shown with the dashed-dotted line (line AB, CD) in a figure shows the roll open | release state (refer also FIG. 3 (a) at the time of steady casting), and the solid line ( The state indicated by lines EB and FG) indicates a state in which the opening of each roll is completed (see also FIG. 3C).
[0039]
As shown in FIG. 4, each roll moves from the state of line ABCD to the state of line EBFG when the slab is drawn. Specifically, the bulging roll has a predetermined opening speed α (t) (mm / sec) and within the range surrounded by A-B-E, the initial state of the line A-B to the state of the line E-B. The rolling roll moves at a predetermined opening speed β (t) (mm / sec), and within the range surrounded by CD-G-F, from the initial state of the line CD, the roll F -Move to the state of G. In addition, line HI in a figure shows the arbitrary states (state of FIG.3 (b)) in releasing the reduction roll.
[0040]
Therefore, “W” in the above formula (5) ₁ ・ Σ {Ln · α (t)} ”is the volume change (mm) that increases per unit time when the bulging roll is released within the range surrounded by A-B-E. ³ / Sec), meaning “W ₁ Σ {Lm · β (t)} ”is a volume change amount (mm) that increases per unit time when the rolling roll is released within a range surrounded by CDFG. ³ / Sec). On the other hand, “Vc (t) · δ (t) · W in the above formula (6)” ₁ "Is the plane indicated by line B-H (i.e., δ (t) x W ₁ The volume that extrudes the unsolidified part of the slab per unit time (mm) ³ / Sec).
[0041]
In practice, the slab width (the slab long side length) does not change during steady casting and slab drawing, so there is no need to consider this. Therefore, the above V ₁ And V ₂ W ₁ Is calculated as 1 mm.
[0042]
The rate of change V of the molten metal surface at the end portion (bottom portion) of the slab is desirably small, and when V exceeds 10 mm / sec, mold powder or the like is involved and the quality of the bottom portion of the slab is deteriorated. Therefore, the change rate V of the molten metal surface was set to 10 mm / sec or less, and the following formula (1) was defined.
[0043]
V ≦ 10… ▲ 1 ▼
(B) About the amount of change S (mm) of the unsolidified molten metal surface
After the completion of casting, the amount of change S (mm) of the surface of the unsolidified portion in the slab during drawing of the slab is V ₁ And V ₂ Is expressed by the following equation (4).
[0044]
S = ∫ (V ₁ -V ₂ ) Dt / (t ₁ ・ W ₁ )… ▲ 4 ▼
The amount of change S of the molten metal surface is the so-called “shrinkage length” at the end of the slab, and 0 mm is ideal. However, when S is less than 0 mm, steel leakage occurs. Therefore, the amount of change S of the molten metal surface was set to 0 mm or more, and the following formula (2) was defined.
[0045]
S> 0… ▲ 2 ▼
However, there is no problem if S is 0 mm or more from the viewpoint of steel leakage, but if this value becomes too large, the shrinkage nest length increases and the yield decreases. Therefore, it is desirable that the value S of the hot water level change is 500 mm or less and is as close to 0 mm as possible. That is, it is desirable that the range satisfies the following formula (7).
[0046]
0 <S ≦ 500… ▲ 7 ▼
(C) About the cut-off length L (mm) of the slab end (bottom)
The cut-off length L (mm) of the slab end portion (bottom portion) is not less than the value of S calculated by the above formula (2) or formula (7), that is, within the range of formula (8) below. I just need it. As a result, the bottom portion where the shrinkage nest is generated is cut off.
[0047]
S ≦ L… ▲ 8 ▼
(D) About the opening method of the bulging roll during slab drawing after completion of casting FIG. 5 is a diagram showing the constraint conditions when opening the bulging roll, and (a) shows the interval in the thickness direction of the upstream roll. The case where it becomes smaller than the space | interval of the thickness direction of a downstream roll is shown, (b) shows the case where the space | interval of the thickness direction of an upstream roll becomes equal to the space | interval of the thickness direction of a downstream roll, (a) shows an upstream roll. The case where the space | interval of the thickness direction of this becomes larger than the space | interval of the thickness direction of a downstream roll is shown.
[0048]
It is assumed that the bulging zone is composed of n rolls, and the suffix ξ in the figure is numbered sequentially from the upstream side. That is, FIG. ₁ ≦ ξ ₂ ≦… ξ _i-1 ≦ ξ _i … ≦ ξ _n-1 ≦ ξ _n FIG. (B) shows the state of ₁ = Ξ ₂ = ... ξ _i-1 = Ξ _i … ＝ ξ _n-1 = Ξ _n FIG. (C) shows the state of ₁ ≧ ξ ₂ ≧… ξ _i-1 ≧ ξ _i … ≧ ξ _n-1 ≧ ξ _n The state of is illustrated.
[0049]
When the gap between the rolls in the thickness direction when the bulging roll is released is in the state of (c), the slab is squeezed in the bulging zone. May occur. For this reason, the state of (a) or (b), that is, the state where the downstream roll is longer in the thickness direction than the upstream roll among the adjacent rolls or the thickness between the upstream roll and the downstream roll. It is necessary to release the bulging rolls with the same roll interval in the direction.
[0050]
Therefore, the release of the bulging rolls means that the roll interval in the thickness direction is ξ _i-1 ≦ ξ _i It must be controlled so that For example, the bulging roll may be opened based on the opening method shown in FIG.
[0051]
6A to 6D are diagrams illustrating an example of a method for opening a bulging roll. The method for opening the bulging roll may be to open the bulging roll in order from the upstream side to the downstream side, as shown in (a) to (b), for example, from the state of steady casting. ) To (d), all the rolls from the upstream side to the downstream side may be opened simultaneously.
[0052]
The timing for opening the bulging roll is preferably as early as possible from the end of casting until the end of the slab is in the mold. Moreover, opening the rolling roll means reducing the amount of slab reduction and leads to residual center segregation. Therefore, it is desirable that the opening start time be delayed as close as possible to the slab end portion.
[0053]
【Example】
Using a vertical bend type continuous casting equipment as shown in FIG. 1, aluminum killed carbon steel (C: 0.16-0.18%, Si: 0.3-0.4%, Mn: 1.3-1.45) %, P ≦ 0.020%, S ≦ 0.004%, Fe: balance). The internal cross-sectional dimension of the mold used is the thickness (t ₁ ) Is 235 mm and the width is 2260 mm. The steady casting speed was 20.83 mm / sec (1.25 m / min), and this casting speed was maintained during drawing after casting. The amount of cooling water in the guide roll portion was 2 liters / (molten steel kg) in terms of specific water.
[0054]
The upstream position of the bulging zone was 5.3 m from the meniscus, and the upstream position of the reduction zone was 20.3 m from the meniscus. The number of guide roll segments in the bulging zone was 10, the number of reduction roll segments in the reduction zone was 4, and the length of one roll group was 1.5 m in both the bulging zone and the reduction zone.
[0055]
Slab reduction amount δ during steady casting ₁ Slab bulging type in bulging zone during steady casting, slab reduction amount δ after release of reduction roll ₂ Were the values shown in Table 1. Here, the “bulging form” is an opening form of the bulging roll being cast, and means an opening form of each bulging roll shown in FIG.
[0056]
FIGS. 7A and 7B are diagrams showing an opening form of a bulging roll during casting, in which FIG. 7A shows stepped bulging and FIG. 7B shows collective bulging. As shown in FIG. 1 (a), a type in which roll segments involved in bulging are gradually opened from the upstream side to the downstream side to bulge the slab is referred to as a gradual bulging format (in Table 1, “graded”). ).
[0057]
Specifically, the amount of reduction δ during steady casting ₁ Is 20 mm, the opening amount of each segment is No. One segment is 2 mm, no. In 2 segments, 4 mm, no. 6 mm for 3 segments,. For 10 segments, such as 20 mm, the difference in the opening amount between adjacent segments is set to 2 mm, and the amount of reduction δ during steady casting ₁ Is 10 mm, the opening amount of each segment is No. One segment is 1 mm, no. 2 mm for 2 segments, no. 3 segments for 3 segments, ... No. For 10 segments, the difference in the opening amount between adjacent segments was set to 1 mm, such as 10 mm. On the other hand, as shown in FIG. 5B, a form in which all the roll segments involved in bulging are bulged with the same opening amount is referred to as a collective bulging form (referred to as “collective” in Table 1).
[0058]
In the case of adopting the “stepped bulging format” in actual operation, the difference in the opening amount between adjacent segments as described above may be a fixed amount or may not be a fixed amount.
[0059]
[Table 1]

[0060]
In test number 1, the steady casting is the reduction amount δ ₁ Was carried out in a stepwise bulging format to give a 20 mm. After the end of casting, the bulging roll is set to No. 1 with an opening speed α (t) of 0.14 mm / sec. 1 segment, no. 2 segments and no. Three segments were simultaneously opened until the respective opening amounts were 6 mm, 4 mm, and 2 mm, and the other segments were not opened. On the other hand, for the reduction roll, the release speed was set to 0.3 mm / sec. All the rolling rolls 1 to 4 were simultaneously opened until the respective opening amounts were 11 mm.
[0061]
In test No. 2, the steady casting is the reduction amount δ ₁ Was carried out in a stepwise bulging format to give a 20 mm. After the end of casting, the bulging roll is set to No. 1 with an opening speed α (t) of 0.14 mm / sec. 1 to 9 segments were opened as follows.
[0062]
First, no. One segment is opened by 2 mm, and after this opening is finished, 2 segments are released by 2 mm, and each segment is opened by 2 mm in the same manner. Opened up to 9 segments. Then, in the same way, No. No. 1 segment Open up to 2 segments up to 8 segments. No. 1 segment Up to 7 was opened by 2 mm. Such work is repeated, and finally, No. The opening amount of one segment is 18 mm. The opening amount of the two segments is 16 mm. The 9 segments were opened so that the opening amount was 2 mm. On the other hand, the reduction roll was not opened.
[0063]
In test No. 3, the steady casting is the reduction amount δ ₁ Was carried out in a stepwise bulging format to give a 20 mm. After the casting, the bulging roll was not opened. On the other hand, for the reduction rolls, the release speed was set to 0.3 mm / sec, and all the reduction rolls were simultaneously released until the respective release amounts were 11 mm.
[0064]
In test No. 4, the steady casting is the reduction amount δ ₁ Was carried out in a stepwise bulging format to give a 20 mm. After the end of casting, the bulging roll is set to No. 1 with an opening speed α (t) of 0.14 mm / sec. All the segments 1 to 10 were opened sequentially every two segments until the opening amount of each segment was 1.5 mm. Specifically, first, no. After each of the 1 and 2 segments was opened by 1.5 mm and the opening was completed, The 3 and 4 segments were each opened by 1.5 mm. 5 and 6 segments, no. 7 and 8 segments and The 9 and 10 segments were also opened in the same manner until each became 1.5 mm. On the other hand, for the reduction roll, the release speed was set to 0.3 mm / sec. All the rolling rolls 1 to 4 were simultaneously opened until the respective opening amounts were 1.5 mm.
[0065]
In test No. 5, the steady casting is the reduction amount δ ₁ Was carried out in a batch bulging format so that the thickness of the film was 20 mm. After completion of casting, the bulging roll was set to No. 1 with an opening speed of 0.14 mm / sec. All the rolling rolls 1 to 10 were simultaneously opened until the respective opening amounts were 20 mm. On the other hand, for the reduction roll, the release speed was set to 0.3 mm / sec. All the rolling rolls 1 to 4 were simultaneously opened until the respective opening amounts were 20 mm.
[0066]
In test No. 6, the steady casting is the reduction amount δ ₁ Was carried out in a stepwise bulging format so as to be 10 mm. After the casting, the bulging roll was not opened. On the other hand, for the reduction roll, the release speed was set to 0.1 mm / sec and No. All the rolling rolls 1 to 4 were simultaneously opened until the respective opening amounts were 3 mm.
[0067]
In Test No. 7, the steady casting is the reduction amount δ ₁ Was carried out in a stepwise bulging format to give a 20 mm. After the end of casting, the bulging roll is set to No. 2 with an opening speed of 0.2 mm / sec. All the rolling rolls 1 to 10 were simultaneously opened until the respective opening amounts were 20 mm. On the other hand, for the reduction roll, the release speed was set to 0.3 mm / sec. All the rolling rolls 1 to 4 were simultaneously opened until the respective opening amounts were 20 mm.
[0068]
From the above manufacturing conditions, the volume change amount V of the unsolidified portion of the slab that is sucked per unit time during drawing of the slab using the above formulas (5) and (6). ₁ (Mm ³ / Sec) and the volume change V of the slab unsolidified portion extruded per unit time ₂ (Mm ³ / Sec), and using the above formulas (3) and (4), the change rate V (mm / sec) of the molten metal surface in the slab during slab drawing and the unsolidified portion in the slab The amount of change S (mm) of the hot water surface was calculated. These results are shown in Table 2.
[0069]
Since the width of the slab (long side length of the slab) hardly changes during the casting and drawing process, the mold width (mold long side length) W ₁ (Mm) can be regarded as the same. Therefore, in Table 2, “V ₁ / W ₁ "And" V ₂ / W ₁ The value of "
[0070]
In order to confirm the effect of the present invention, the occurrence of steel leakage from the final end of the slab, the maximum value of the center segregation of the bottom of the slab determined in the following manner, and after rolling the slab, ultrasonic Inspection and internal quality survey were conducted. Moreover, it evaluated also about the cut-off length of the slab final end part. These evaluation results are also shown in Table 1.
[0071]
The central segregation degree was evaluated by the maximum segregation degree of phosphorus (P). This is cut at a cross section perpendicular to the casting direction at a position 3 m from the final end of the obtained slab, and the specimen is sampled from the central part in the thickness direction, and the surface of the specimen is divided into 200 μm meshes. In each section, the P concentration was measured using an EPMA (Electric Probe Micro Analyzer), and the ratio between the maximum P concentration [Pmax] and the P concentration [Pave] of the mother molten steel ([Pmax ] / [Pave]).
[0072]
[Table 2]

[0073]
The cut-off length at the end of the slab is “small” when the length is less than 500 mm, “medium” when the length is 500 mm or more and less than 1000 mm, and 1000 mm or more. It was described in the table as “Large”.
[0074]
Test Nos. 1 to 5 of the present invention are examples in which the opening method of the bulging roll and the rolling roll is controlled so that the values of the molten metal surface change speed V and the molten metal surface variation amount S are within the scope of the present invention. As shown in Table 2, no leakage steel occurred in Examples 1 to 4 of the present invention, and no defect occurred even in ultrasonic inspection after rolling. However, in test numbers 1 and 3, the rolling roll group was opened, and the slab rolling amount δ after the rolling roll was released δ ₂ Is the slab reduction amount δ ₁ Therefore, the maximum precipitation degree of P was slightly increased to 4.7. Moreover, in the test number 5, since the value of the molten metal surface change amount S is as large as 1193 mm, there was no occurrence of steel leakage, but the amount of round-off at the final end of the slab increased and the yield deteriorated. No problem.
[0075]
In the test numbers 6 to 8 of the comparative examples, any one of the hot water surface change speed V and the hot water surface change amount S is out of the range of the present invention. In Test No. 6, since the value of the molten metal surface change amount S was as small as -9.6 mm, steel leakage occurred. In Test Nos. 7 and 8, since the value of V exceeded the range specified in the present invention, ultrasonic defects due to powder occurred. In particular, in test number 7 in which the value of S exceeded the range specified in the present invention, the cut-off length was 500 mm or more, and the yield was also deteriorated.
[0076]
【The invention's effect】
According to the method of the present invention, not only can the center segregation of the slab be eliminated during the casting of the steady part to improve the quality of the slab, but also quality defects such as powder entrainment at the end of the slab at the end of casting are reduced. be able to. In addition, it is possible to improve the casting yield by minimizing the cut-off amount at the end portion of the slab. Furthermore, troubles during operation such as leakage of steel from the end of the cast slab of unsolidified molten steel at the end of casting can be prevented, and stable operation is possible. Further, the slab to be subjected to the method of the present invention may be a slab or a bloom (billet), but is particularly suitable for continuous casting of a slab which is a material for a thick steel plate.
[0077]
[Brief description of the drawings]
FIG. 1 is a diagram schematically showing an example of an apparatus for carrying out a bulging-reducing continuous casting method.
FIG. 2 is a schematic view showing a roll position and a slab cross section when a bulging-reducing continuous casting method is performed.
FIGS. 3A and 3B are diagrams showing an example of an open state of a bulging roll and a rolling roll in the continuous casting method of the present invention, FIG. The state at the time of one drawing is shown, (c) shows the state where the release of each roll is completed.
FIG. 4 illustrates the above symbols in detail.
FIG. 5 is a diagram showing a constraint condition when opening a bulging roll.
FIG. 6 is a diagram showing an example of a method for opening a bulging roll.
FIGS. 7A and 7B are diagrams showing an opening form of a bulging roll during casting, in which FIG. 7A shows stepped bulging and FIG. 7B shows collective bulging.
[Explanation of symbols]
1. Tundish Molten steel Immersion nozzle 4. 4. Mold Slab
6). Solid phase crater end 7a ~ 7n. Guide roll 8a￣8n. Rolling roll
9. Reduction device 10. Pinch roll

Claims (3)

The guide roll is spread over a predetermined range from the position corresponding to the liquid phase crater end of the slab to the position corresponding to the solid phase crater end. This is a continuous casting method in which the rolling is reduced by a considerable amount or less. After the casting is finished, the change rate V (mm / sec) of the unsolidified molten metal surface in the slab during slab drawing is expressed by the following formula (1). Continuously characterized by opening the gap between the guide rolls or the rolling rolls under the condition that the amount of change S (mm) of the unsolidified molten metal surface in the slab that satisfies and satisfies the following formula (2): Casting method.
V ≦ 10… ▲ 1 ▼
S> 0… ▲ 2 ▼
However, V in the above formula (1) is a value obtained from the following formulas (3), (5) and (6), and S in formula (2) is the following formula (4), This is a value obtained from the equations (5) and (6).
V = (V ₁ −V ₂ ) / (t ₁ · W ₁ ) (3)
S = ∫ (V ₁ −V ₂ ) dt / (t ₁ · W ₁ ) (4)
V ₁ = W ₁ · Σ {Ln · α (t)} + W ₁ · Σ {Lm · β (t)} (5)
V ₂ = Vc (t) · δ (t) · W ₁ (6)
The meanings of symbols in the above formulas (3) to (6) are as follows.
V ₁ : Volume change amount (mm ³ / sec) of the slab unsolidified portion sucked per unit time during slab drawing
V ₂ : Volume change amount (mm ³ / sec) of the unsolidified portion of the slab extruded per unit time during slab drawing
t ₁ : Mold thickness (mold short side length) (mm)
W ₁ : mold width (mold long side length) (mm)
Ln: Of the guide roll segments in the bulging zone, the length in the slab direction (mm) of the guide roll segment that is open during slab drawing
n: Number assigned to the guide roll segment in the bulging zone in order from the upstream side Lm: Out of the reduction roll segment in the reduction zone, the length in the slab direction of the reduction roll segment in the range opened during slab drawing (mm)
m: Number α (t) assigned in order from the upstream side for the rolling roll segment in the rolling zone: Release speed (mm / sec) of the guide roll segment
β (t): Reduction speed of the rolling roll segment (mm / sec)
Vc (t): slab drawing speed (mm / sec)
δ (t): Amount of slab reduction by a reduction roll (mm) The continuous casting method according to claim 1, wherein the guide roll or the rolling roll is opened under a condition that the amount of change S (mm) of the unsolidified molten metal surface satisfies the following expression (7).
0 <S ≦ 500… ▲ 7 ▼ 3. The continuous casting according to claim 1, wherein after the slab is drawn, the final end portion of the slab is cut off so that a length L (mm) satisfies the following formula (8): Method.
S ≦ L… ▲ 8 ▼

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