JP4259232B2 - Slab continuous casting method for ultra-low carbon steel - Google Patents

Description

  The present invention relates to a method for continuously casting slabs of ultra-low carbon steel, and more particularly to a technology for producing a material slab suitable for use in automobile outer plates and the like that require strict surface quality.

  Steel sheets used for applications where deep drawing and other complicated deformation processes such as the outer plate of automobiles are applied require high formability, so the C content has been reduced as much as possible. So-called very low carbon steel (usually C content in the steel is 0.01 mass% or less) is used. Among such extremely low carbon steel plates, in particular, cold-rolled steel plates for automobile outer plates are required to have a beautiful appearance in addition to the paintability.

  By the way, since the process of oxidizing and removing C in molten steel using oxygen in the refining process is indispensable for ultra low carbon steel, oxygen dissolved in the molten steel in this process is further reduced to aluminum, magnesium, titanium, etc. A step of deoxidizing with a deoxidizing agent is required. In this deoxidation step, oxygen in the molten steel combines with a deoxidizer to produce deoxidation products such as alumina, magnesia, titania, etc., which remain as nonmetallic inclusions in the molten steel.

  If such non-metallic inclusions are present in the vicinity of the surface of the slab, when the slab is hot-rolled and cold-rolled to form a thin steel plate, defects such as baldness and blistering occur on the surface of the steel plate, which is not preferable. . In addition to deoxidation products, argon gas supplied to prevent clogging of mold powder added to the molten steel surface in the mold during continuous casting and immersion nozzle for supplying molten steel from the tundish into the mold It is known that even if bubbles in the molten steel are entrained in the molten steel and remain in the molten steel as bubbles alone or in combination with the deoxidized product, the same surface defects as the above deoxidized product are caused. Yes.

Therefore, in the past, unlike a continuous cast slab for a cold-rolled steel sheet in which the surface of the slab is hot-rolled without maintenance, in the case of a slab for an automobile outer sheet, the surface is subjected to about 1 to 4 mm of cutting, etc. After removing the foreign matter causing the steel sheet surface defects after hot rolling such as deoxidation product inclusions, bubbles, mold flux, etc. on the slab surface layer, it is used for hot rolling and cold rolling. It was.
However, such a slab refining process has a problem in that the yield of the slab, which is a raw material, is lowered and the process is retained.
Therefore, attempts have been made to prevent the occurrence of slab surface layer defects that cause surface defects of the steel sheet as described above at the stage of producing slabs in continuous casting equipment.

The basic idea of such an attempt is
(1) The slab has a large cross section (the slab width is restricted during rolling, so it can be handled by increasing the slab thickness) and the casting speed (m / min) is reduced to reduce the mold without sacrificing productivity. Increase the residence time of the molten steel in the inside, thereby gaining time for the deoxidation products, mold powder or bubbles and other foreign matters from the molten steel to rise in the mold,
(2) Casting with a continuous casting machine having a vertical part in order to promote floating and separation of deoxidation products, mold powder or bubbles from molten steel in the mold,
(3) Electromagnetic force provides a horizontal flow in the vicinity of the meniscus to prevent foreign matter floating in the molten steel from being trapped by the solidified shell (cleaning effect).
(4) Reduce mold powder entrainment in molten steel by making mold powder viscosity appropriate.
(5) Optimization of the oscillation (vertical vibration) conditions of the casting mold for continuous casting and generation of claw of the solidified shell formed in the mold (a phenomenon in which a part of the solidified shell falls to the molten steel side due to the oscillation) Reduce the trap amount of deoxidation products, mold powder, bubbles, etc. in this part,
(6) Electromagnetic stirring and electromagnetic brake are added to the molten steel discharge flow supplied from the immersion nozzle into the mold to optimize the flow of the molten steel, and the molten steel discharge flow with deoxidation products is deep in the mold. Prevent entry into position,
Etc. were the mainstream.

For example, in Patent Document 1, when casting a molten steel of C <0.01 wt% with a continuous casting machine having a vertical portion length of 2.0 m (20 m in claims) or more, a slab thickness> 200 mm, a slab width> 900 mm (in the example, thickness: 282 mm, width: 1680 to 1950 mm), 1.0 m / min or more (in the example, a relatively low speed of 1.0 to 1.5 m / min) and 4 ton / min or more (example) (4.0 to 6.4 ton / min), powder viscosity: 1.0 poise or more, inert gas flow rate from immersion nozzle: 1 liter / min or more, below meniscus: 15-40 m of molten steel A method of electromagnetic stirring in the horizontal direction at a flow rate of cm / sec is disclosed.
This technique is mainly directed to the above (1), (2), (3), (4) and (6).

Patent Document 2 discloses a method for reducing the claw portion formed in the initial solidification stage of the slab surface layer portion where the inclusion vibration is optimized by optimizing the mold vibration conditions (there is no description of the slab size). (Casting speed: 1.4 to 2.6 m / min, quality improved to 2.0 m / min or less).
This technology is directed to the above (5).

JP-A-5-76993 JP-A-7-155902

However, the above-described conventional technique has the following problems.
That is, as described in Patent Document 1, when the slab has a large cross section, particularly when the thickness is increased, the number of defects such as inclusions in the vicinity of the slab surface is expected as expected under casting conditions where the casting speed exceeds 1.5 m / min. Was not reduced. The reason for this is that even when electromagnetic force is applied in the horizontal direction of the meniscus and the molten steel flow velocity vm is controlled to the optimum value, the throughput increases as the slab thickness increases at the same casting speed (Vc) and the same slab width (W). Since the discharge flow rate vi from the immersion nozzle increases and the variation of the average value of the molten steel flow velocity vm is small, the fluctuation amount is increased, so that the entrainment of the mold flux into the molten steel is promoted. It is. That is, the cleanliness in the vicinity of the slab surface layer is not uniquely determined by the meniscus molten steel flow velocity.

  Moreover, the influence of the molten steel discharge jet from an immersion nozzle becomes remarkable, and the short side shell growth in a casting_mold | template partly delays. In the case of a slab continuous casting facility, a so-called two-hole nozzle is used for the purpose of supplying the molten steel uniformly in the width direction of the casting space in the mold when the molten steel is injected into the mold. Since the width d of the discharge port of the hole nozzle is relatively small with respect to the short side length D (corresponding to the thickness of the slab) in the mold, the flow velocity of the molten steel in the thickness direction is biased, and the short side This is because the growth of the solidified shell in which molten steel having a high flow velocity collides locally is delayed. In addition, the deviation of the molten steel flow velocity in the slab thickness direction also contributes to the fluctuation of the meniscus flow velocity described above.

  Furthermore, if the molten steel within 1.5 m below the meniscus is stirred in the horizontal direction, heat transfer to the solidified shell is promoted, so that the growth of the solidified shell is further inhibited. As a result, slab short-side bulging due to the molten steel static pressure becomes prominent near the mold outlet. In severe cases, breakout occurs due to shell remelting, which hinders stable casting operation. The above problems become more serious when aiming to improve productivity by increasing the casting speed and slab thickness above 1.5 m / min.

Next, in the technique described in Patent Document 2, when the mold stripping condition, in particular, the mold amplitude is reduced and the frequency is increased to control the negative strip time T to a specific condition and improve the surface quality of the slab, It became clear that there were problems like
In other words, when casting ultra-low carbon steel under conditions where the casting speed exceeds 2.0 m / min and the mold frequency exceeds 185 cycles / min, an abnormal phenomenon in which the molten metal surface fluctuates suddenly is rare. Observed. As a result, the mold flux is entrained in the molten steel and bitten into the solidified shell, resulting in a slab surface defect. Therefore, in the case of casting at a casting speed exceeding 2.0 m / min, there has been a problem that surface defects caused by mold flux frequently occur in the product, and a product having good surface quality cannot be stably obtained.

  As is clear from the above, in the production of ultra-low carbon steel slabs used for automotive skins, etc., in the case of high-speed casting exceeding 2.0 m / min, slabs such as cutting are still used. High quality slabs could not be produced stably without the need for care.

  The present invention advantageously solves the above problem, and even when high-speed casting exceeding 2.0 m / min is applied, a slab having excellent surface quality that does not require slab maintenance such as welding is stably obtained. An object of the present invention is to propose a slab continuous casting method of ultra-low carbon steel that can be obtained.

As a result of intensive studies to achieve the above-mentioned object, the inventors have found that the casting speed, the short side length of the casting space in the continuous casting mold, the frequency of the casting mold, the short side length D and the submerged nozzle discharge By appropriately controlling the ratio D / d of the hole lateral width d and effectively utilizing electromagnetic force braking for the molten steel injection flow, the knowledge that the intended purpose is advantageously achieved was obtained. .
The present invention is based on the above findings.

That is, the gist configuration of the present invention is as follows.
1. When producing an ultra-low carbon steel slab having a C content of 0.01 mass% or less using a continuous casting facility,
The short side length of the casting space in the mold of the above continuous casting equipment: 150 to 240 mm, casting speed: over 2.0 m / min, mold frequency: 185 cycle / min Using a submerged nozzle satisfying the ratio D / d of the submerged nozzle discharge hole width d of 1.5 to 3.0, the long side width of the mold near the lower end of the mold with respect to the molten steel injection flow in the casting space in the mold of the continuous casting equipment. A slab continuous casting method for ultra-low carbon steel, characterized in that a static magnetic field is applied over the entire area of the steel plate, and braking is applied by electromagnetic force to perform casting.
2. When producing an ultra-low carbon steel slab having a C content of 0.01 mass% or less using a continuous casting facility,
The short side length of the casting space in the mold of the above continuous casting equipment: 150 to 240 mm, casting speed: over 2.0 m / min, mold frequency: 185 cycle / min An immersion nozzle having a ratio D / d of the immersion nozzle discharge hole width d of 1.5 to 3.0 is used, and with respect to the molten steel injection flow in the casting space in the mold of the continuous casting equipment, on the outlet side of the immersion nozzle discharge hole A slab continuous casting method for ultra-low carbon steel, characterized in that casting is performed by applying braking by electromagnetic force applied with a static magnetic field.

3 . 3. The slab continuous casting method of ultra-low carbon steel according to 1 or 2 above, wherein the casting speed is 2.4 m / min or more.

4 . Very low according to any of the above 1 to 3, wherein the ratio D / d of the short side length D and the immersion nozzle discharge port width d is cast using an immersion nozzle which satisfies 2.1 to 2.9 Carbon steel slab continuous casting method.

5. The ultra-low carbon steel slab, slab continuous casting method of the ultra low carbon steel according to any one of the above 1 to 4, characterized in that a material for a cold rolled steel sheet for automobile exterior panels.

According to the present invention, the short side length of the casting space in the mold (slab thickness when it becomes a slab) is 150 to 240 mm, which is smaller than the conventional one, while the casting speed exceeds 2.0 m / min, which is larger than the conventional one. (Preferably 2.4 m / min or more), the flow speed of the molten steel along the long side in the mold is increased, and even without applying a horizontal flow speed by electromagnetic force,
1) Inclusions and bubbles that are trapped in the long-side solidified shell generated in the mold are washed (cleaning effect),
2) Even if the long side solidified shell itself becomes thin and some inclusions and bubbles are trapped in this shell, it is effectively removed together with the scale during slab heating before hot rolling,
3) Further, when the casting speed exceeds 2.0 m / min, sudden fluctuation of the molten metal surface, which is feared to occur due to resonance between mold vibration and molten metal surface vibration, is prevented.
Although it has been reported that a cleaning effect can be seen by increasing the casting speed, the effect is said to be saturated at a casting speed of about 1.6 to 1.8 m / min. It is estimated that the more effective improvement of the cleanness of the slab surface layer when the speed exceeds 2.0 m / min is largely due to the effects of 2) and 3) above.

As a result, according to the present invention, it is possible to stably manufacture an optimum slab as a material for an extremely low carbon steel sheet having extremely severe surface quality, such as a cold-rolled steel sheet for an automobile outer plate.
Even if the casting speed is high, the short side length is small, so that the thickness of the solidified shell on the short side can be prevented from being uneven, and short side bulging can be prevented.
Furthermore, in the present invention, not only can the entrainment of mold powder be reduced by reducing the collision flow velocity to the short side by adding braking by electromagnetic force to the molten steel injection flow in the casting space in the mold, Unevenness of the short side solidified shell thickness, which causes short side bulging, can be more effectively prevented.

Hereinafter, the present invention will be specifically described.
The steel type targeted by the present invention is a so-called ultra-low carbon steel having a C content of 0.01 mass% or less. Components other than C are not particularly specified, but are preferably suitable for deep drawing applications such as automobile outer plates. The present invention intends not to include inclusions, etc. in a thickness range that does not scale off under the surface layer of the slab, especially for steel grades for applications that dislike inclusion defects, and as a deoxidation product such as alumina in the refining process The ultra-low carbon steel that easily generates non-metallic inclusions enjoys the benefits of the present invention most.
Incidentally, the typical composition of ultra-low carbon steel other than C is as follows.
Si: 0.01 to 0.04 mass%, Mn: 0.08 to 0.20 mass%, P: 0.008 to 0.020 mass%, S: 0.003 to 0.008 mass%, Al: 0.015 to 0.060 mass%, Ti: 0.03 to 0.080 mass%, Nb: 0.002 to 0.017 mass%, B: 0 to 0.0007 mass%.

  The continuous casting equipment targeted by the present invention is a steel slab continuous casting equipment, which may be any of a vertical continuous casting equipment, a vertical bending continuous casting equipment, and a curved continuous casting equipment, but considering productivity and quality. The vertical bending type continuous casting equipment is then particularly advantageous.

The mold is a mold for so-called slab continuous casting, and the short side length (corresponding to the slab thickness when the slab is formed) needs to be 150 to 240 mm as defined in the present invention. The long side length (corresponding to the slab width when it becomes a slab) is not particularly limited, and may be a length for a normal cold-rolled steel sheet (especially a cold-rolled steel sheet for automobiles). It is preferable to be about ~ 2200 mm.
The height in the vertical direction of the mold is not specified, but even when casting at a casting speed of more than 2.0 m / min, a solidified shell with a thickness that does not bulge the slab that has passed through the mold is generated. Since it is necessary, the thickness is preferably about 800 mm to 1000 mm.

An immersion nozzle is used as a nozzle for supplying molten steel from the tundish to the casting space in the mold. The material of the immersion nozzle is preferably alumina-graphite, which is generally used, but is not limited to this.
Further, as the shape of the immersion nozzle, a cylindrical nozzle (so-called straight nozzle) or a two-hole nozzle in which a tip is closed and a substantially circular discharge port is provided in both short side directions can be generally used. The cross-sectional shape of the discharge port is not limited to a round shape, a square shape, a rectangular shape (horizontally long or vertically long), and the maximum width d only needs to meet the conditions of the present invention.
Furthermore, the casting speed needs to be over 2.0 m / min for the reasons described later. More preferably, it is 2.4 m / min or more.

In the case of applying braking by electromagnetic force to the molten steel injection flow in the casting space in the mold of the continuous casting facility, a static magnetic field is applied over the entire area of the mold long side width as described in JP-A-2-284750. applying a method of, as described in JP-a-57-17356, to use any method of applying a static magnetic field only in the ejection position of the molten steel.

Next, regarding the phenomenon that occurs in the mold when casting is performed under the conditions of the short side length of the casting space in the mold (slab thickness): 150 to 240 mm and the casting speed: more than 2.0 m / min according to the present invention. The new findings will be described. Hereinafter, inclusions and bubbles are referred to as foreign matters.
(1) Decrease in the number of foreign matter trapping sites By setting the casting speed Vc to more than 2.0 m / min, preferably 2.4 m / min or more, the formation of meniscus initial solidified shells, so-called “nails” is remarkably suppressed. This is because the solidified shell thickness at the same depth below the molten metal surface becomes thinner as Vc increases, so the force pressed against the mold side due to the influence of the molten steel static pressure is due to the heat shrinkage of the shell depending on the solidified shell thickness. This is because the nail becomes larger than the force of the nail to fall down. In addition, as the slab thickness decreases, the absolute value of shell shrinkage in the thickness direction (= slab thickness x temperature difference x linear expansion coefficient) decreases, so that the collapse to the molten steel side is further suppressed. The fall-suppressing effect becomes even more pronounced.
Fig. 1 shows the effect of casting speed on the claw depth. When the casting speed is> 2.0 m / min and the short side length of the casting space in the mold (slab thickness) ≤ 240 mm, the claw depth is 1 mm or less. Become. In addition, when the casting speed is 2.4 m / min or more, the nail depth is 0.7 mm or less.

(2) Suppression of foreign matter adsorption Along with solidification, a gradient of interfacial tension occurs due to segregation of solute concentrated at the solidification interface, and this force causes a phenomenon that foreign matter is easily attracted and trapped at the solidified shell interface. . For this reason, attempts have been made to reduce the concentration of S, Ti, etc., which have a particularly large influence as a solute element that increases the force for attracting and capturing foreign matter. However, there is a problem that manipulating the components leads to cost increase (lower S) and material deterioration (Ti reduction).
In the present invention, by increasing the casting speed Vc, it is possible to suppress an increase in the force for sucking / capturing foreign matter into the solidified shell. That is, in the high-speed casting as in (1), the amount of solidification of the meniscus portion is further reduced, so that the amount of segregation is also reduced, and hence the interfacial tension gradient that is a suction force for foreign matters is also reduced. As a result, the amount of foreign matter adsorbed and captured on the solidified shell side is also suppressed.

(3) Decrease in trapping thickness of foreign matter FIG. 2 shows the relationship between the trapping depth h of the foreign matter from the slab surface in the slab surface layer and the number of trapped pieces. Also, in FIG. 3, the trapped depth h from the slab surface is converted into a distance L from the meniscus (molten surface) (h = k (L / Vc) ^1/2 , Vc: casting speed, solidification constant k = 20 mm. (Min ^-0.5 o'clock) shows the relationship between the distance L from the meniscus and the number of captures.
As can be seen from FIGS. 2 and 3, the foreign matter is trapped by the shell within 20 mm below the molten metal surface. As the casting speed increases, the trapping depth becomes shallower, and when the casting speed Vc> 2.0 m / min, the trapping depth h from the slab surface becomes 1 mm or less.
Below this depth, even if the foreign matter is trapped by the shell, the foreign matter is dropped and removed together with the oxide scale on the surface of the slab in the process of becoming a product through the subsequent hot rolling → cold rolling process. Therefore, it is possible to obtain a defect-free product without performing slab maintenance. Note that when the casting speed is 2.4 m / min or more, the claw depth is 0.7 mm or less, that is, the foreign matter capturing thickness h is also less, so the casting speed is more preferably 2.4 m / min or more.

(4) Decrease in foreign matter trapping probability The residence time of the solidified shell within 20 mm below the molten metal surface where foreign matter is easily trapped by the solidified shell becomes shorter as the casting speed increases. Therefore, even if the amount of foreign matter floating in the molten steel is the same, the probability of being trapped by the solidified shell is reduced. For example, in the case of Vc = 3.0 m / min, the probability of trapping foreign matter is halved compared to the case of Vc = 1.5 m / min.

(5) Optimum mold frequency to prevent sudden melt level fluctuation When casting speed Vc exceeds 2.0 m / min, the solidified shell in the mold becomes thinner as described above. It occurs even though the so-called bulging phenomenon that is pressed against the mold side under the influence of the static pressure of molten steel is small. This bulging phenomenon is such that, in the case of a steel type such as an extremely low carbon steel whose shell is high in temperature and whose shell strength is smaller than that of other steel types, the speed of expansion (pressed against the mold) becomes larger than the mold vibration speed. Generally, when a mold with a taper for compensating for volume shrinkage due to solidification shrinkage or heat shrinkage is vibrated up and down, the solidified shell swells following the mold lowering (bulging amount: δb), while the mold is rising In this case, the shell in which the mold swells is pushed (pressing amount: δp≈δb). The amount of volume change caused by this change in the molten metal surface is as small as less than 1 mm in calculation. However, it has been found that if such a process is repeated, an abnormal phenomenon in which the molten metal surface vibration and the mold vibration resonate and the molten metal surface suddenly varies greatly occurs. Since this phenomenon occurs at the crack of the mold, it is difficult to detect with a normal overflow type molten metal level meter, and the present inventors found for the first time by investigating the change over time in the oscillation mark disturbance of the slab. It is a phenomenon. In particular, when the casting speed exceeds 2.0 m / min and the mold frequency is as high as 185 cycles / min, such a phenomenon is easy to observe, and as a result, the mold flux is entrained in the molten steel and applied to the solidified shell. Biting occurs, resulting in a slab subsurface defect. For this reason, in the case of casting exceeding 2.0 m / min, the occurrence of surface defects due to mold flux in the product suddenly increases, and the surface defects cannot be reduced stably.
However, in this regard, when the mold frequency is set to 185 cycles / min or less from the relationship between the ratio of the flux system defects in all defects and the mold frequency as an index of the frequency of sudden phenomena, It has been found that such a phenomenon can be effectively prevented even when the casting speed Vc exceeds 2.0 m / min.

(6) Prevention of short side bulging (reason for upper limit on short side length of casting space in mold)
Even if an immersion nozzle in which the ratio D / d of the short side length (slab thickness) D of the casting space in the mold defined in the present invention and the horizontal width d of the immersion nozzle satisfies the appropriate range is used, the short side length is If the thickness is too thick, when the casting speed Vc exceeds 2.0 m / min, a slab shape defect or breakout due to short side bulging occurs. In this regard, when the short side thickness is small or Vc is small, bulging due to the molten steel static pressure on the short slab after exiting the mold is suppressed, and the risk of occurrence of breakout is low.
However, as shown in FIG. 4, when the short side length (ie, the slab thickness) exceeds 240 mm, even if the casting speed is 2.4 m / min, the increase in the molten steel jet velocity from the immersion nozzle discharge hole due to the increase in the slab thickness Due to the increase of the secondary flow velocity due to braking, it becomes difficult to suppress the delay of the short-side shell growth, the short-side bulging at the bottom of the mold becomes prominent, and the risk of breakout (bulging amount ≥ 10 mm) increases. .
If the short side length (ie, slab thickness) exceeds 240mm, the reverse flow or secondary flow from the short side of the molten steel jet will promote disturbance of the molten metal surface for the same reason as above. Flux entrapment and biting are also likely to occur, and the increase in slab thickness tends to cause stagnation of molten steel especially in the vicinity of the immersion nozzle at the meniscus portion, so as shown in FIG. Defects and product defects are increased.

(7) Reason for the lower limit of the short side length of the casting space in the mold If the short side length (slab thickness) D of the casting space in the mold is less than 150 mm, it is not preferable for the following reasons.
That is, if the slab cross-sectional area becomes too small, the amount of fluctuation of the molten metal surface becomes large for the same variation of casting amount due to the problem of molten metal surface controllability, and the nail depth of 1 mm or more caused by the water wrinkles The occurrence frequency of (1) cannot be obtained. In addition, the mold flux is likely to be caught and bitten due to the fluctuation of the molten metal surface (see FIG. 5). Furthermore, the outer diameter of a general immersion nozzle is determined by the wall thickness (20 mm or more) determined from durability, throughput: 5.4 t / min (150 mm thickness, 2200 mm width, Vc: 2.1 m / min or more) to 14.5 t / min ( 240 mm thickness, 2200 mm width, Vc: ~ 3.5 m / min) is determined by the sum of the inner diameters (70 to 130 mm) determined from the viewpoint of ensuring. Here, if the short side length (slab thickness) D is too small, the distance between the outer wall of the immersion nozzle and the long side solidified shell becomes too narrow (<20 mm), the flow between them becomes uneven, and vertical cracks occur. Cause. In extreme cases, the solidified shell contacts and adheres to the nozzle, leading to breakout. Therefore, the short side length (slab thickness) D is 150 mm (inner diameter: 70 mm + outer wall total thickness: 40 mm (20 × 2) + distance between the outer wall of the immersion nozzle and the long side solidified shell: 40 mm (20 × 2)) or more. There is a need. The slab width is not limited for the above reason.

(8) Optimization of the ratio D / d between the short side length D of the casting space in the mold and the horizontal width d of the submerged nozzle discharge hole The molten steel ejected from the submerged nozzle discharge port widens before colliding with the short side shell. The speed distribution of the molten steel jet colliding with the mold short side shell depends on the slab width W, the casting speed Vc and the D / d ratio. If the immersion nozzle discharge port width d is too small (D / d is too large) with respect to the short side length (slab thickness) D of the casting space in the mold, it collides with the short side shell as D, Vc, and W increase. Since the ratio of the region width of the large jet flow velocity to the slab thickness (short side width) decreases, the growth of the solidified shell is uneven and easily inhibited, and if the solidified shell becomes extremely thin, breakout occurs. On the other hand, if the submerged nozzle discharge port d is too large (D / d is too small) with respect to the short side length (slab thickness) D of the casting space in the mold, the long side side before the jet collides with the short side. If the solidified shell collides with the shell and the growth of the solidified shell on the long side is inhibited, transverse cracks and oblique cracks occur, and the solidified shell becomes extremely thin, it will also lead to a breakout. In either case, there is almost no influence of the slab width.
Further, when the D / d ratio deviates from the optimum value when the flow after the collision on the short side flows along the long side side molten metal after rising, if the molten steel flow rate is biased in the slab thickness direction, the meniscus flow rate fluctuation This also increases the amount of mold flux entrained.

  In addition, the maximum discharge port width d determined from the viewpoint of securing throughput: 5.4 to 14.5 t / min is set to be equal to or smaller than the inner diameter of the immersion nozzle (70 to 130 mm) from the viewpoint of durability of the immersion nozzle. Is preferred. Therefore, the D / d ratio takes into consideration the short side length (slab thickness) D (150 to 240 mm) and the discharge port width d (70 to 130 mm) of the optimum casting space in the mold determined from (6) and (7). There is a need to. If long casting (300 minutes or more) is assumed, the outer wall thickness of the nozzle should be 25 mm x 2 = 50 mm or more, and the distance between the mold and nozzle should be 40 mm or more to ensure more stable quality ( In other words, the required thickness excluding the inner diameter of the nozzle is 50 + 40 × 2 = 130 mm. On the other hand, in the case of a short time, the outer wall thickness of the nozzle is 20 mm × 2 = 40 mm, and the distance between the mold and the nozzle is about 20 mm The required thickness excluding the nozzle inner diameter is 40 + 20 × 2 = 80mm).

Table 1 shows the results of investigation on the influence of the D / d ratio on product quality.
As shown in the table, the range of D / d is 1.5 to 3.0, but in addition to the product quality, the range of 2.1 to 2.9 is taken into account when considering the optimal slab thickness, immersion nozzle durability and required flow rate. Is more preferred.

(9) Flow braking by electromagnetic force At casting speed Vc ≥ 2.4 m / min or throughput: 7 ton / min or more, even if the slab thickness and D / d are optimized, there is a slight increase in product defect rate.
Therefore , it is necessary to add flow braking by electromagnetic force, and more stable operation and improvement in quality can be achieved by this flow braking.
As the flow braking method by such an electromagnetic force, that you use the method described in JP and Sho 57-17356 Patent Publication No. Hei 2-284750 are as described above.

As described above, in (5), (6) and (8) above, mold flux entrainment is prevented as much as possible, and even if the flux is entrained or the inclusions float in the molten steel, (2), (4) suppresses the trapping of foreign matter in the solidified shell, and further prevents the defect from being trapped even if trapped, so that the solidified shell is trapped by (1), (3) above. By making the depth from the surface shallower, removal and removal of foreign substances from the slab surface layer are promoted until the product is manufactured, particularly in the slab heating process.
Such an effect can be stably achieved under the high productivity by the above (6), (7), (8), (9).

With continuous casting machine, the short side length (slab thickness) of the casting space in the mold is 110 mm (test continuous casting machine), 200, 215, 220, 235, 260 mm (above production casting of vertical bending type) Slab widths of 400 mm (test continuous casting machine) and 900-2200 mm (above are vertical bending type production continuous casting machines), respectively, were cast under the conditions shown in Table 2. At this time, the mold height was 900 mm (production continuous casting machine), 700 mm (test continuous casting machine), the immersion nozzle used was alumina graphite, the wall thickness was 25 mm, and the shape of the discharge port was square (slab thickness) : When 220 mm or less) or round shape (when slab thickness exceeds 220 mm), the discharge angle was constant at 20 ° downward. A mold flux having a solidification temperature of 1000 ° C., a viscosity of 0.05 to 0.2 Pa · s (0.5 to 2.0 poise) (1300 ° C.), and basicity (CaO / SiO ₂ ) = 1.0 was used. Moreover, the molten steel superheat degree in the tundish was 10-30 degreeC. Furthermore, the molten steel components are C: 0.0005 to 0.0090 mass%, Si <0.05 mass%, Mn <0.50 mass%, P <0.035 mass%, S <0.020 mass%, Al: 0.005 to 0.060 mass%, Ti <0.080 mass. %, Nb <0.050 mass%, and B <0.0030 mass%.

The maximum short side bulging amount, the maximum nail depth value, the maximum number of slab surface layer defects, and the presence or absence of breakout occurrence of each slab thus obtained are also shown in Table 2.
Table 2 shows cold rolled steel sheets obtained by subjecting each of the above slabs to slab heating at 1100 to 1200 ° C. for 2 to 2.5 hours, followed by hot rolling, cold rolling, and finish annealing according to conventional methods. The results of examining the surface defect occurrence rate (plate thickness: 0.8 mm) are also shown.
Furthermore, in FIG. 6, the result of having investigated about the influence of the casting speed on the slab surface layer defect and the cold-rolled sheet surface defect is arranged and shown.

Note that the maximum number of slab surface layer defects is 1 mm cutting of slab surface layer → # 1000 emery paper polishing → bubbles (≧ 0.2 mmφ), alumina clusters (≧ 500 μm φ) observed after mixed acid solution corrosion of hydrochloric acid and hydrogen peroxide. ), The number of slag (including mold flux (≧ 0.5 mmφ)) per unit area (pieces / m ² ).
Further, the surface defect rate of the cold-rolled sheet is defined as a percentage of the total number of defects caused by casting defects such as linear wrinkles and lashes on the front and back surfaces per 1000 m of the cold-rolled sheet.
Furthermore, whether or not a breakout occurred was defined as “Yes” when a breakout occurred even once during casting under the conditions.
“Type 1” described as an electromagnetic brake means that a static magnetic field is applied (EMBR) to the entire width of the mold near the lower end of the mold, and “Type 2” means that a static magnetic field is applied (EMLS) on the outlet side of the submerged nozzle. The techniques described in JP-A-2-284750 and JP-A-57-17356 are applied respectively.
The negative strip time tn is one characteristic value that defines the mold vibration condition, and means the time during which the mold lowering speed exceeds the slab lowering speed.

  As can be seen from Table 2 and FIG. 6, when the slab was cast according to the present invention, even if the casting speed was higher than 2.0 m / min, the surface layer defects of the obtained slab were slight, and There were no surface defects in the rolled steel sheet products, and there were few surface defects.

As is clear from the above examples, according to the present invention,
(1) While increasing the relative pressing force against the mold wall due to the molten steel static pressure of the shell solidified near the molten metal surface in the mold,
(2) Suppressing the adsorption phenomenon of foreign matter to the solidified shell interface and reducing the capture probability,
(3) By optimizing the operating conditions so that the trapping thickness of foreign matter in the solidified shell is as small as possible, high speed casting with a casting speed exceeding 2.0 m / min can be performed without slab maintenance. While maintaining productivity and stable operation, it is possible to supply slabs for cold-rolled steel sheets for automobile outer sheets with high quality.

It is a figure which shows the relationship between casting speed and claw depth. It is a figure which shows the relationship between the capture depth h from a slab surface layer, and the capture | acquisition number by making casting speed into a parameter. It is a figure which shows the relationship between the distance L from a meniscus, and the capture | acquisition number by making a casting speed into a parameter. It is a figure which shows the influence of the slab thickness and the casting speed which have on the short side bulging amount. It is a figure which shows the influence of the slab thickness which acts on the surface defect rate of a product. It is a figure which shows the influence of the casting speed which has on the surface defect rate of a product.

Claims (5)

When producing an ultra-low carbon steel slab having a C content of 0.01 mass% or less using a continuous casting facility,
The short side length of the casting space in the mold of the above continuous casting equipment: 150 to 240 mm, casting speed: over 2.0 m / min, mold frequency: 185 cycle / min Using a submerged nozzle satisfying the ratio D / d of the submerged nozzle discharge hole width d of 1.5 to 3.0, the long side width of the mold near the lower end of the mold with respect to the molten steel injection flow in the casting space in the mold of the continuous casting equipment. A slab continuous casting method for ultra-low carbon steel, characterized in that a static magnetic field is applied over the entire area of the steel plate, and braking is applied by electromagnetic force to perform casting. When producing an ultra-low carbon steel slab having a C content of 0.01 mass% or less using a continuous casting facility,
The short side length of the casting space in the mold of the above continuous casting equipment: 150 to 240 mm, casting speed: over 2.0 m / min, mold frequency: 185 cycle / min An immersion nozzle having a ratio D / d of the immersion nozzle discharge hole width d of 1.5 to 3.0 is used, and with respect to the molten steel injection flow in the casting space in the mold of the continuous casting equipment, on the outlet side of the immersion nozzle discharge hole A slab continuous casting method for ultra-low carbon steel, characterized in that casting is performed by applying braking by electromagnetic force applied with a static magnetic field. The slab continuous casting method for ultra-low carbon steel according to claim 1 or 2, wherein the casting speed is 2.4 m / min or more. The electrode according to any one of claims 1 to 3, wherein the casting is performed using an immersion nozzle in which a ratio D / d of the short side length D and the immersion nozzle discharge hole width d satisfies 2.1 to 2.9. Low carbon steel slab continuous casting method. The ultra-low carbon steel slab, slab continuous casting method of the ultra low carbon steel according to any one of claims 1 to 4, characterized in that a material for a cold rolled steel sheet for automobile exterior panels.

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