JP3805708B2 - Horizontal continuous casting method - Google Patents

Description

【００２０】
【表２】

【００２１】
・試験結果
実施例１〜３では、安定して鋳片を引き抜くことができ、健全な鋳片を得ることができた。また、実施例１および３では、停止時間を１秒まで短くしても、割れ等の欠陥は発生しなかった。図２および図３は、それぞれ実施例１および実施例３の鋳片の鋳肌を示す写真であり、オシレーションマークはほとんど傾斜しておらず、安定した連続鋳造が行われたことが実証された。実施例４では、鋳片の引き抜きは可能であったが、鋳片の温度が高いために、二次モールドでの冷却によって若干の変形がみられた。実施例５では鋳片の上下の温度差が大きく、オシレーションマークが傾斜する傾向にあり、上面に品質上許容される範囲ではあるものの微細な割れが認められる場合があった。
【００２２】
なお、オシレーションマークとは、断続的な引き抜きによって鋳肌に生じる縞模様であって、引き抜きによる凝固界面の移動と停止に伴う不連続な界面が、引き抜きストロークに応じたピッチで現れるものであり、一般鋳造品の湯じわあるいは湯境に相当する。水平連続鋳造においては上下の温度差が生じやすく、温度差が小さい場合のオシレーションマークは垂直すなわち引き抜き方向に直交する方向に近くなり、温度差が大きい場合は上側が下側よりも温度が高くなりやすいのでオシレーションマークは引き抜き側に傾斜する。
【００２３】
安定した引き抜きおよび上下に組織差がない材質を得るためには、上下の温度差ができるだけ小さいことが必要であり、したがって、オシレーションマークは垂直が望ましい。また、水平連続鋳造においては、引き抜きにより凝固シェルがスムーズに移動することが望ましいが、凝固シェルが薄いと引き抜きにより凝固シェルがちぎれる場合がある。その場合のオシレーションマークは、引き抜きストロークに対応したピッチになっておらず、乱れが生じる。すなわち、垂直に近く、引き抜きストロークに対応した乱れのない一定ピッチのオシレーションマークが認められれば、健全な連続鋳造が行えた証明となるのである。
【００２４】
さて、比較例１では、一次モールドから排出される初期段階で鋳片の上部に割れが生じた。割れを防止するために停止時間を１０秒と長くしたが割れは改善されず不安定な鋳造が続き、鋳片を２ｍ鋳造した時点で、モールド内で破断に至った。破断の原因は、凝固開始点がタンディッシュの耐火壁に達し、引き抜き抵抗が増大したためと推察された。比較例２では、鋳片の下部の凝固が進行しやすく、図４に示すようにオシレーションマークが大きく傾斜し、この傾斜は停止時間が短いほど顕著であった。また、図５に示すように鋳片の上部表面には割れが生じ、ブレークアウトの危険性が認められた。
【００２５】
比較例３では、引き抜き装置の遊びによって引き抜きストロークが３ｍｍに安定しなかった。また、引き抜き／停止の断続運転のペースが頻繁なために引き抜き装置の駆動系にかかる負担が大きかった。なお、鋳片の品質は実施例２と大差なかった。比較例４では、図６に示すようにオシレーションマークの乱れが大きく不均一であり、また、表面に割れが認められ、引き抜きが不安定であった。
【００２６】
【発明の効果】
以上説明したように、本発明は、固定式の一次モールドと可動式の二次モールドによって水平連続鋳造を行うにあたって一次モールドの長さと鋳片の引き抜きストロークを最適に設定したので、亜共晶鋳鉄の水平連続鋳造方法としてきわめて有望である。
【図面の簡単な説明】
【図１】 本発明の実施例で用いた水平連続鋳造装置の概要を示す側断面図である。
【図２】 実施例１で鋳造された鋳片の側面を示す写真である。
【図３】 実施例３で鋳造された鋳片の側面を示す写真である。
【図４】 比較例２で鋳造された鋳片の側面を示す写真である。
【図５】 比較例２で鋳造された鋳片の上面を示す写真である。
【図６】 比較例４で鋳造された鋳片の側面を示す写真である。
【符号の説明】
１０…一次モールド、２０…二次モールド。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a horizontal continuous casting method in which a molten metal, that is, a molten metal is continuously cooled and a solidified slab is drawn out horizontally, and more particularly to a horizontal continuous casting method effective for hypoeutectic cast iron. .
[0002]
[Prior art]
Continuous casting is widely used as a method for mass production of uniform and high-quality metal materials at low cost. As a method, a vertical mold in which the slab is drawn downward and a horizontal mold in which the slab is horizontally drawn are used. The horizontal type is often used because the equipment cost is low. In horizontal continuous casting, generally, molten metal stored in a tundish is cooled while being supplied into a horizontally installed mold, thereby forming a slab in which at least the outer peripheral portion is solidified in the mold. The slab to be discharged is continuously drawn horizontally by a drawing device.
[0003]
The mold used for horizontal continuous casting has a cylindrical shape or a rectangular tube shape, and a cooling jacket is provided on the outer periphery thereof, and the molten metal continuously supplied is cooled to form a solidified shell on the outer peripheral portion. While growing, it functions to stabilize the formation position of the solidified shell, that is, the solidification start position of the molten metal. The material of the mold is usually different for the following reasons when the cast is cast iron and steel.
[0004]
Since cast iron has relatively low toughness, if the friction between the slab and the inner wall of the mold is high, cracks, which are one of surface defects, tend to occur, leading to breakout or slab breakage. Graphite with good lubricity is used. Breakout is a defect in which a crack is generated on the surface of a slab that has come out of a mold, and the crack expands to reach an unsolidified portion inside, and the molten metal leaks or blows out. This refers to the case where the piece is torn off while completely solidified to the inside. When breakout or breakage occurs, the drawing of the slab must be stopped. Cast iron has a characteristic that the solidification shrinkage is relatively small. Therefore, the solidification shrinkage hardly causes a gap between the mold and the solidified shell due to cooling is efficiently obtained by increasing the length of the graphite mold. Growth is planned. Further, in continuous casting of cast iron, there is a case where the solidified shell is grown by performing secondary cooling by applying air or mist-like water to a portion immediately after leaving the mold.
[0005]
On the other hand, in the case of steel, a graphite mold tends to cause melting damage. When the melting damage occurs, the surface property of the cast piece deteriorates, or the melted mold C (carbon) melts into the steel and casts. Since the amount of C in the piece increases, a Cu alloy mold is used. Since steel has a relatively large solidification shrinkage, gaps are easily formed between the steel and the mold, and particularly in horizontal continuous casting, the gaps are concentrated on the upper surface side of the mold due to the influence of gravity. Generation | occurrence | production of this clearance gap reduces the cooling property of the slab cooled by contacting a mold remarkably. Therefore, a method is proposed in which molten metal is supplied to a fixed primary mold to grow a solidified shell, and then a slab is passed through a radially movable secondary mold, and the slab is pressed by this secondary mold to eliminate gaps. Has been. This secondary mold is known, for example, from Japanese Utility Model Laid-Open No. 5-93641. In horizontal continuous casting using such a combination of a primary mold and a secondary mold, the length of the primary mold was 200 mm or more. Further, the slab drawing is generally performed intermittently with 40 to 50 mm as one stroke.
[0006]
The reason why the slab is pulled out intermittently is as follows. The mold has a temperature gradient that gradually decreases from the tundish side toward the drawing direction, and when the slab is drawn continuously, the temperature of the molten metal passes through the solidification start temperature according to the temperature gradient of the mold. In that case, the solidification interface is likely to be disturbed due to uneven temperature. On the other hand, when the slab is pulled out intermittently, the temperature of the molten metal passes through the solidification start temperature at a cooling rate equal to or higher than the temperature gradient of the mold and solidifies all at once. For this reason, a solidification interface is formed stably and a sound slab can be cast.
[0007]
[Problems to be solved by the invention]
By the way, in recent years, a continuous cast material of hypoeutectic cast iron has attracted attention as a free-cutting cast iron having a high Young's modulus and strength, or as a material for semi-melt molding. However, since this eutectic cast iron has a wider solid-liquid coexistence temperature range than cast iron and steel, the growth of the solidified shell is slow, and therefore the solidified shell is prone to cracking. In some cases, the solidified structure hindered the supply of molten metal. Further, since the solidified shell was easily chilled, the toughness was low, and cracking was likely to occur in the solidified shell. Further, since the solidification shrinkage is relatively large, a gap is easily generated between the slab and the mold, so that it was not possible to expect efficient growth of the solidified shell. For these reasons, even if the movable secondary mold described above is used, breakout and breakage are likely to occur, continuous casting is difficult, and development of an effective continuous casting method has been desired.
[0008]
Accordingly, an object of the present invention is to provide a horizontal continuous casting method capable of stably performing horizontal continuous casting of hypoeutectic cast iron without causing breakout or fracture.
[0009]
[Means for Solving the Problems]
In the present invention, the molten metal is passed through the primary mold and then cooled while passing through the movable secondary mold so as to press the slab, and the slab discharged from the secondary mold is intermittently pulled out with a predetermined drawing stroke. In the horizontal continuous casting method of hypoeutectic cast iron, the length of the inner wall of the primary mold is set to 100 to 180 mm, and the drawing stroke is set to 5 to 10 mm.
[0010]
In the present invention, a solidified shell is generated in a primary mold, and a solidified shell is grown in a secondary mold. The inventor conducted a horizontal continuous casting test of hypoeutectic cast iron using a primary mold made of graphite and a movable secondary mold made of Cu alloy. The position is about 20 mm from the end surface on the tundish side of the primary mold, and the position at which a gap is formed between the slab and the mold by solidification shrinkage is about 100 mm from the start point of solidification (from the end surface on the tundish side of the primary mold). About 120 mm). And even if the secondary cooling by the secondary mold was started from about 20 mm before the position where the gap was generated (about 100 mm from the end surface on the tundish side of the primary mold), no breakout was caused. On the other hand, when the gap is generated, the cooling of the upper side of the slab is delayed, so that an oscillation mark to be described later tends to be inclined and a crack is likely to occur on the upper side. And as a maximum length of the primary mold which a crack does not generate | occur | produce on the upper side of a slab, it was about 180 mm. These behaviors did not correlate with the diameter of the slab (inner diameter of each mold) and were almost constant.
[0011]
Therefore, the length of the inner wall of the primary mold was set to 100 to 180 mm, which is shorter than the conventional one. If the molten metal temperature cannot be controlled with high accuracy, the molten metal temperature may increase when the molten metal is replenished. In that case, the solidification start position is shifted by about 30 mm in the drawing direction of the primary mold. On the other hand, the position where the inclination of the oscillation mark hardly occurs was about 160 mm from the end face on the tundish side of the primary mold. Therefore, the length of the primary mold is more preferably 130 to 160 mm.
[0012]
In addition, the secondary mold requires strong cooling ability to promote the growth of the solidified shell. This secondary mold should be installed at a position as close as possible to the primary mold, and a position where the solidification of the cast piece proceeds to some extent in the primary mold and a gap between the mold and the mold starts to be generated by solidification shrinkage is desirable. This secondary mold is divided around the slab so as to be in close contact with the outer peripheral surface of the slab and efficiently cooled, and these divided bodies are movable in the radial direction. What acts so that a slab may be pressed with biasing means, such as a spring, is used.
[0013]
With regard to the drawing stroke, hypoeutectic cast iron has a relatively low toughness, so in order to prevent breakout due to cracking of the solidified shell, it is set to 5 to 10 mm shorter than the conventional 40 to 50 mm, and the stop time is appropriately set. Set. The reason for shortening the stroke to 5 to 10 mm is as follows. Since the mold has a temperature gradient so that the temperature decreases from the tundish side toward the drawing direction, the cooling conditions differ depending on the temperature at each position between strokes. The larger the stroke, the greater the temperature difference at each position between the strokes, so that the solidification interface is likely to be disturbed. When the stroke is 10 mm or less, the temperature difference at each position is small, the solidification interface is stable, and a sound slab can be cast. However, if it is 5 mm or less, it is necessary to shorten the stop time. However, since the pace of the intermittent operation of the extraction / stop is frequent, the load on the drive system of the extraction device is large and difficult to control.
[0014]
The characteristics required for the primary mold in the present invention are excellent in resistance to melting, lead the melt to the inside without solidifying it, and do not break the solidified shell generated at the solidification start point by seizure. Includes a graphite-based material having a melt resistance containing 30 to 50% by volume of silicon carbide, boron carbide, aluminum nitride or the like. On the other hand, the material of the secondary mold is preferably a Cu alloy because it requires a strong cooling ability as described above. That is, in the present invention, it is preferable that the main component of the material constituting the inner wall of the primary mold is graphite and the main component of the material constituting the inner wall of the secondary mold is a Cu alloy.
[0015]
In addition, when the slab cast by this invention is a cylinder, the diameter, ie, the internal diameter of a primary mold and a secondary mold, is effective when it is 150 mm or less, and it is especially effective when it is 30-100 mm.
[0016]
【Example】
Hereinafter, the present invention will be described in more detail with reference to specific examples.
FIG. 1 shows a horizontal continuous casting apparatus connected to a tundish refractory wall 1 in which a melt of hypoeutectic cast iron is stored. This apparatus is cylindrical and has its axial direction installed horizontally. A primary mold 10 and a secondary mold 20 and a drawing device (not shown) are provided. The primary mold 10 is made of a graphite-ceramic composite, and is hermetically joined to the molten metal outlet of the fire wall 1, and a water cooling jacket 11 is provided on the outer periphery thereof. The secondary mold 20 includes a plurality of divided bodies 20a made of a Cu alloy that is divided in the circumferential direction and set to be movable in the radial direction, and each divided body 20a includes a fluid pressure cylinder or a spring (not shown). The biasing member is biased inward. A water cooling jacket 21 is provided on the outer periphery of each divided body 20a.
[0017]
The molten metal is supplied from the inside of the tundish into the primary mold 10 by its own weight, and is cooled, whereby a solidified shell is generated and formed into a slab. And this slab passes the secondary mold 20, and each division body 20a is pressed against a slab so that the clearance gap between a slab and each division body 20a may be eliminated in that case. The slab is drawn out by a drawing device installed on the downstream side of the secondary mold 20, whereby continuous casting is performed.
[0018]
The lengths L1 and L3 of the inner walls of the primary mold 10 and the secondary mold 20 shown in FIG. 1, the length L2 of the water cooling jacket of the primary mold 10, and the inner diameters of the primary mold and the secondary mold are set as shown in Table 1. Thus, continuous casting apparatuses of Examples 1 to 5 and Comparative Examples 1 to 4 were produced. In Comparative Example 1, no secondary mold was used. On the other hand, hypoeutectic cast irons having the components of Examples 1 to 5 and Comparative Examples 1 to 4 shown in Table 2 were prepared, and these hypoeutectic cast irons were placed in the tundish to which the corresponding continuous casting apparatus was connected. Thus, the molten metal was maintained at 1400 to 1420 ° C. And about these Examples 1-5 and Comparative Examples 1-4, the continuous casting test which pulls out the slab discharged | emitted from a secondary mold horizontally with the conditions of the drawing stroke and stop time shown in Table 1 was conducted. It was.
[0019]
[Table 1]

[0020]
[Table 2]

[0021]
-Test result In Examples 1-3, the slab could be extracted stably and the sound slab could be obtained. In Examples 1 and 3, no defects such as cracks occurred even when the stop time was shortened to 1 second. FIGS. 2 and 3 are photographs showing the casting surfaces of the slabs of Example 1 and Example 3, respectively, and the oscillation mark is hardly inclined, and it has been demonstrated that stable continuous casting was performed. It was. In Example 4, the slab could be drawn, but due to the high temperature of the slab, some deformation was observed due to cooling with the secondary mold. In Example 5, the temperature difference between the upper and lower sides of the slab was large, and the oscillation mark tended to be inclined. In some cases, fine cracks were observed on the upper surface although it was within the allowable range in quality.
[0022]
The oscillation mark is a striped pattern generated on the casting surface by intermittent drawing, and the discontinuous interface accompanying the movement and stop of the solidification interface by drawing appears at a pitch according to the drawing stroke. It corresponds to a hot water wrinkle or hot water boundary of a general casting product. In horizontal continuous casting, the temperature difference between the top and bottom is likely to occur. When the temperature difference is small, the oscillation mark is close to the vertical, that is, the direction perpendicular to the drawing direction. When the temperature difference is large, the upper side is higher than the lower side. The oscillation mark is inclined to the extraction side.
[0023]
In order to obtain a material that is stable and has no difference in structure between the upper and lower sides, the temperature difference between the upper and lower sides needs to be as small as possible. Therefore, the oscillation mark is preferably vertical. In horizontal continuous casting, it is desirable that the solidified shell move smoothly by drawing, but if the solidified shell is thin, the solidified shell may be broken by drawing. In this case, the oscillation mark does not have a pitch corresponding to the drawing stroke, and is disturbed. In other words, if an oscillation mark having a constant pitch that is close to the vertical and corresponds to the drawing stroke is recognized, it is a proof that sound continuous casting has been performed.
[0024]
Now, in Comparative Example 1, a crack occurred in the upper part of the slab at the initial stage of being discharged from the primary mold. In order to prevent cracking, the stop time was increased to 10 seconds. However, cracking was not improved and unstable casting continued, and when the slab was cast for 2 m, it broke in the mold. The cause of the breakage was presumed to be that the solidification start point reached the fire wall of the tundish and the pulling resistance increased. In Comparative Example 2, solidification of the lower part of the slab easily proceeds, and the oscillation mark is greatly inclined as shown in FIG. 4, and this inclination becomes more prominent as the stop time is shorter. Further, as shown in FIG. 5, the upper surface of the slab was cracked, and the risk of breakout was recognized.
[0025]
In Comparative Example 3, the drawing stroke was not stabilized at 3 mm due to play of the drawing device. In addition, since the pace of intermittent operation of extraction / stop is frequent, the burden on the drive system of the extraction device is large. The quality of the slab was not much different from Example 2. In Comparative Example 4, as shown in FIG. 6, the oscillation mark was greatly disturbed and non-uniform, cracks were observed on the surface, and the extraction was unstable.
[0026]
【The invention's effect】
As described above, in the present invention, when performing horizontal continuous casting using a fixed primary mold and a movable secondary mold, the length of the primary mold and the drawing stroke of the slab are optimally set. It is very promising as a horizontal continuous casting method.
[Brief description of the drawings]
FIG. 1 is a side sectional view showing an outline of a horizontal continuous casting apparatus used in an embodiment of the present invention.
FIG. 2 is a photograph showing a side surface of a slab cast in Example 1.
3 is a photograph showing a side surface of a slab cast in Example 3. FIG.
4 is a photograph showing a side surface of a slab cast in Comparative Example 2. FIG.
5 is a photograph showing an upper surface of a slab cast in Comparative Example 2. FIG.
6 is a photograph showing a side surface of a slab cast in Comparative Example 4. FIG.
[Explanation of symbols]
10 ... primary mold, 20 ... secondary mold.

Claims (2)

Hypoeutectic cast iron in which the molten metal is passed through the primary mold, then cooled while passing through the movable secondary mold so as to press the slab, and the slab discharged from the secondary mold is intermittently drawn at a predetermined drawing stroke. In the horizontal continuous casting method, the length of the inner wall of the primary mold is 100 to 180 mm, and the drawing stroke is 5 to 10 mm. The horizontal continuous casting method according to claim 1, wherein a main component of a material constituting the inner wall of the primary mold is graphite, and a main component of a material constituting the inner wall of the secondary mold is a Cu alloy. .

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