KR20140072010A - Continuous casting method for steel and producing method for steel bar and wire rod - Google Patents

Abstract

This continuous casting method is a continuous casting method comprising a drawing step of drawing a cast product in a state of high-liquid coexistence from a cylindrical casting mold and a casting step of casting the cast product in a state of high- And a second pressing down direction perpendicular to both the longitudinal direction and the first pressing down direction of the cast steel is defined as a second pressing down direction, The corner portion of the cast steel in a state of being in a state of being higher than the temperature of the surface portion in a direction perpendicular to the longitudinal direction of the cast steel while rounding down in the first and second pressing down directions is alternately performed, And a second pressing down step of molding.

Description

TECHNICAL FIELD [0001] The present invention relates to a continuous casting method of a steel and a method of manufacturing the same. BACKGROUND ART < RTI ID = 0.0 >

The present invention relates to a continuous casting method for obtaining a cast steel excellent in internal quality with less center segregation, central porosity and internal cracking, and a method of producing crude steel capable of omitting the crushing and rolling process.

The present application claims priority based on Japanese Patent Application No. 2012-183179 filed on August 22, 2012, the contents of which are incorporated herein by reference.

Generally, high-quality (high-quality) coarse steel is produced by casting a casting with a bloom continuous casting machine having a large-sized rectangular mold, crushing the casting, and then performing rolling of the billet. This high-grade steel includes bars and wire rods. In these steels, material characteristics deteriorate due to center segregation or central porosity formed at the end of solidification of the continuous casting slab. Therefore, it is important to cast a cast slab so as not to cause defects such as center segregation and central porosity. As a typical method for reducing the center segregation and the central porosity, there can be cited an uncooled soft-pressing method and a post-complete-pressing method in a continuous casting machine.

For example, Patent Document 1 discloses a method in which, with respect to a round piece having a diameter of 340 mm or less, the roll ratio is 0.1 to 3.0% by one pass with one set of rolls in a state where the solidification rate of the shaft portion is 0.3 to 0.7 Is proposed. However, this technique is applied to a cast steel having a small sectional size of 340 mm or less in diameter. On the other hand, when the cross-sectional size of the cast steel becomes larger, the amount of coagulation shrinkage also increases. Therefore, in order to obtain the above effect by the uncoagulated pressing by one set of rolls, it is necessary to increase the amount of reduction. That is, in order to eliminate the center segregation and the center porosity of the rectangular steel strip, which is a large-scale surface, in one pass, a large amount of reduction is required in the continuous casting machine. However, in such a case, there is a problem that internal cracking occurs in the cast steel at the time of non-coagulation and pressing, and the material characteristics of the crude steel are impaired. As described above, it is difficult to achieve both reduction of center segregation and central porosity of the cast steel and prevention of internal cracking of cast steel.

In Patent Document 2, for example, the equilibrium retention rate in the inside of a cast steel is controlled to 35% or more by controlling the production conditions for a rolled steel piece having a diameter of 180 mm, and the center solidity ratio of the cast steel is 0.25 to 0.35 or 0.60 to 0.90 A technique of applying a reduction of 2.0 to 3.5% to a pair of flat rolls at a position where a range is obtained is proposed. However, in this technique, when the cross-sectional size of the cast steel is large, there is a restriction of the casting condition that the casting speed is lowered more than necessary in order to make the equilibrium constant rate at the section of the cast steel 35% or more. Thereby making it difficult to secure sufficient production capacity. Further, since it is clear that the equilibrium constants in the inside of the cast steel are also affected by the steel composition, there is a limit to the steel types to which this technique can be applied.

In order to improve the material properties of high-quality crude steel, it is important to make both the center segregation and the central porosity of the cast steel to be reduced, and to prevent the occurrence of internal cracks in the cast steel. However, it has not been possible to develop a continuous casting technique that obtains castings having excellent internal quality with less center segregation, central porosity, and internal cracking, including improvement in the production capacity of cast steel.

Japanese Patent Application Laid-Open No. 9-99349 Japanese Patent Laid-Open No. 11-309553

The present invention has been made in view of the above-described circumstances. The present invention can be applied to a wide range of steel types used as crude steel, a cast continuous casting method capable of achieving both reduction of center segregation and center porosity and prevention of internal cracking of cast steel, and a crushing rolling process before rolling And to provide a method of manufacturing crude steel capable of improving productivity by omitting the above-mentioned method.

The gist of the present invention is as follows.

(A) A continuous casting method according to one aspect of the present invention includes: a drawing step of drawing a cast product in a state of high-liquid coexistence from a cylindrical mold; A first pressing down step of performing a pressing down in a first pressing down direction perpendicular to the longitudinal direction of the cast steel in the high-liquid coexisting state after the drawing process; When the pressing down direction orthogonal to both the longitudinal direction and the first pressing down direction of the cast steel is defined as the second pressing down direction and the temperature in the central portion is higher than the temperature of the surface portion , The corner portion is formed into a rounded, annular rectangular shape when viewed in a section perpendicular to the longitudinal direction of the cast steel, while alternately performing the pressing down in the first and second pressing down directions , And a second pressing down step.

(B) In the continuous casting method described in (A) above, the inner diameter of the mold is 400 mm or more and 600 mm or less; The pulling speed of the cast strip is 0.35 m / min or more and 0.65 m / min or less; The solidification rate of the center portion of the cast steel after the drawing process and before the first pressing process is not less than 0.3 and not more than 0.8; The reduction rate per one time in the first pressing down direction in the first pressing down step is not less than 0.3% and not more than 7.0%; The solidification rate at the center portion of the casting after the first pressing down step and before the second pressing down step is more than 0.8 and the temperature at the center portion of the casting is more than 150 ° C higher than the temperature of the surface portion; Wherein the reduction rate per one time in the first pressure reduction direction in the second pressure reduction step is not less than 1.5% and not more than 7.0%, and the reduction rate per one time in the second pressure reduction direction is not less than 1.5% and not more than 7.0% Or less; The shape of the cross section perpendicular to the longitudinal direction of the cast steel after the second pressing step may be not less than 235 mm and not more than 270 mm and the radius of curvature of the corner portion may be not less than 5 mm and not more than 50 mm.

(C) A method of producing crude steel according to one embodiment of the present invention includes a continuous casting step of obtaining the cast steel by the continuous casting method described in (A) or (B) above; And a rolling step of rolling the cast steel after the continuous casting step.

According to this aspect of the present invention, irrespective of the kind of steel, the uneven solidification step from the casting thickness direction (first descending direction) and the casting strip width direction (second descending direction) I do it. As a result, it is possible to reduce the cross-sectional size of the cast steel to a size corresponding to the size after the fracture rolling while reducing the center segregation and central porosity without causing internal cracking of the cast steel. That is, according to the above-described aspect of the present invention, it is possible to provide a continuous casting method and casting method capable of being applied to a wide variety of steel types used as coarse steel and capable of achieving both reduction of center segregation and central porosity, It is possible to provide a method of producing crude steel capable of improving the productivity by omitting the crushing and rolling step before rolling.

1 is a schematic view for explaining a continuous casting method according to an embodiment of the present invention.
Fig. 2 is a schematic view for explaining the pressing-down form of the cast steel in the continuous casting method according to the above embodiment. Fig.
3 is a diagram showing the relationship between the casting speed and the center segregation in the casting in the continuous casting method according to the above embodiment.
Fig. 4 is a diagram showing the relationship between the temperature difference between the central portion and the surface portion of the cast steel and the ultrasonic inspection result in the continuous casting method according to the above embodiment. Fig.
5 is a diagram showing the relationship between the cumulative rolling reduction and the ultrasonic inspection result in the second pressing step in the continuous casting method according to the above embodiment.

Best Mode for Carrying Out the Invention Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to the configurations of the following embodiments, and various modifications are possible without departing from the spirit of the present invention. In order to facilitate understanding of the features of the present invention, the drawings used in the following description are enlarged and shown as major components for convenience, and the dimensional ratios and the like of the respective components are the same Can not.

In the following description, the thickness direction of the cast steel means the rolling direction (first rolling direction) by the horizontal rolls arranged so that the roll axis direction is parallel to the installation surface of the continuous casting machine and perpendicular to the conveying direction of the cast steel do. The width direction of the cast steel means a downward direction (second downward direction) by a vertical roll arranged so that the roll axis direction is perpendicular to the installation surface of the continuous casting machine. That is, when seen in a section perpendicular to the longitudinal direction of the cast steel, the longitudinal direction of the cast steel and the thickness direction (first press down direction) of the cast steel and the width direction of the cast steel (second press down direction) are orthogonal.

The central portion of the cast steel is defined as an area satisfying the following conditions. Wherein the center of gravity of the central portion coincides with the center of gravity of the cross section and the shape of the contour of the center portion coincides with the shape of the reduced contour of the cross section, Is 50% of the area of the cross section, and the surface portion of the cast steel is defined as an area of 5% from the surface with respect to the cast steel diameter in the depth direction from the peripheral face of the cast steel. Unless otherwise specified in the following description, the section of the cast steel means a section perpendicular to the longitudinal direction of the cast steel.

When the solid phase ratio at the solid phase when the solid phase and the liquid phase are in coexistence is the solid phase rate, the case where the solid phase ratio at the center of the cast steel is 0.3 to 0.8 (30 to 80 volume%) is referred to as " Liquid coexistence state "), and when the solidification rate at the central portion of the cast steel exceeds 0.8 (80% by volume), it is defined as the " completely solidified state ". In a continuous casting machine, a region where the solidification rate at the central portion of the cast steel is 0.3 to 0.8 is defined as a "non-solidification reduction zone", and a region where the solidification rate at the central portion of the cast steel exceeds 0.8 is referred to as " define.

The solid phase ratio can be obtained, for example, as follows. The volume ratio of the solid phase and the liquid phase can be inferred from the alloy state diagram. Specifically, when the steel composition and the temperature are determined, it is possible to uniquely obtain the solid phase ratio from the alloy state diagram. Therefore, from the steel composition and the temperature at the center of the cast steel, the solid phase ratio at the center of the cast steel can be obtained using the alloy state diagram. Further, as the alloy state diagram, a calculation state diagram based on the thermodynamic calculation system may be used.

Hereinafter, a description will be given of a process for obtaining a continuous casting method of steel according to one embodiment of the present invention.

It is effective to continuously cast a cast steel having a large end face, for example, in order to cast a cast steel for high-grade steels excellent in internal quality with little center segregation and central porosity. In other words, since the casting amount per unit time is increased by increasing the section size of the casting, the casting speed can be lowered within a range that does not cause any trouble to the productivity. As a result, the equilibrium constant rate in the section of the cast steel is relatively increased, and the removal efficiency of the floating separation of the inclusions in the molten steel between the reed, tundish, and mold is improved.

However, a cast steel having a large cross-sectional size has a larger amount of coagulation shrinkage than a cast steel having a small cross-sectional size. Therefore, in the case of performing the non-solidification reduction in order to reduce the center segregation of the cast steel having a large sectional size, it is necessary to increase the reduction amount with respect to the cast steel. As a result, internal cracking of the cast steel is likely to occur at the time of non-solidified pressing.

In order to solve the above problems, the inventors of the present invention have conducted intensive studies and found the following knowledge.

(1) When the rectangular casting is pressed down, a pressing force is applied to the entire contact face with the pressing roll, and a bulging deformation extending over the entire non-contact face of the pressing roll is generated, The degree of whether or not pressing down is possible) is lowered. As a result, a large reduction in the amount of pressing is required for suppression of center segregation and compression of center porosity. On the other hand, in the case of a round piece having a circular cross-sectional shape, since the pressing stress is concentrated on the arc surface of the cast steel contacting the rolling roll at the time of pressing the casting piece, the pressing down penetration degree to the center of the cast steel It is possible.

(2) There is a temperature difference between the central portion and the surface portion of the cast steel, and in the continuous casting machine, the central portion is in a high temperature state as compared with the surface portion of the cast steel. As a result, the deformation resistance of the center portion of the cast steel is smaller than the deformation resistance of the surface portion of the cast steel, and it is possible to increase the pressure drop penetration degree to the center portion even with a small reduction amount. Particularly, the cast steel sheet withdrawn from the casting mold is subjected to an unfused / contracted reduction in the thickness direction of the cast steel sheet, and furthermore, since the complete and solidification of the cast steel is repeated a plurality of times from the thickness direction and the widthwise direction, . In this case, it is possible to reduce the center segregation and central porosity while preventing the internal cracking while simultaneously reducing the casting.

(3) In a general crushing rolling, since the casting is sufficiently heated in the casting step heating step before the crushing rolling, the temperature difference between the central portion temperature and the surface portion temperature of the casting at the time of crushing is smaller than the temperature difference in the casting in the continuous casting machine . As a result, the push-down penetration degree to the center portion of the cast steel necessarily becomes smaller, so that the center porosity may not be sufficiently pressed. On the other hand, when the cast steel is pressed down by the continuous casting machine, the pressure drop penetration is improved by the temperature difference between the central portion and the surface portion of the cast steel as described above. Thereby, it is possible to reduce the center segregation and the center porosity and prevent the internal cracking while reducing the size of the cast steel to a size corresponding to the size after the crushing rolling by the continuous casting machine, Can be obtained. In other words, the cast steel cast by the continuous casting machine according to the present embodiment can be directly supplied to the rolling of the billet without performing the crushing to produce crude steel.

Hereinafter, each step of the continuous casting method according to the present embodiment will be described.

<Continuous Casting Method>

Fig. 1 schematically shows a continuous casting machine 10 for carrying out the continuous casting method according to the present embodiment. Fig. 2 schematically shows the pressing-down form of the cast steel in the continuous casting method according to the present embodiment. As shown in Figs. 1 and 2, the continuous casting method according to the present embodiment includes: The molten steel is supplied from the tundish 1 to the mold 2 and the uncoagulated (solid-liquid coexistence) is obtained from the mold 2 having a cylindrical shape (its cross-sectional shape when viewed in section perpendicular to the drawing direction) A drawing step of drawing the cast strip (3) in the state; After the drawing process, the roll axis direction is continuously fed to the continuous casting machine 10 with respect to the cast piece 3 (3a) of the solid-liquid coexisting state drawn from the casting mold 2 and passed through a continuous casting machine roll (support roll) (First pressing roll) 5 arranged parallel to the mounting surface 7 of the cast steel 3 and perpendicular to the conveying direction of the cast steel 3, A first pressing down step of performing a pressing down in a downward direction; When the longitudinal direction of the cast steel 3 and the downward direction perpendicular to both the first downward direction and the second downward downward direction are taken as the cross section perpendicular to the longitudinal direction of the cast steel 3, (First pressing roll) 6a in the first rolling down direction by the horizontal roll (first pressing roll) 6a with respect to the above-mentioned cast steel 3 (3b, 3c) which is in a completely solidified state and in which the temperature of the central portion is higher than the temperature of the surface portion And the corner portion is rounded as viewed in a section perpendicular to the longitudinal direction of the cast strip 3 while alternately performing the pressing down in the second pressing down direction by the vertical roll (second pressing roll) 6b, And a second pressing down step of forming the cast steel 3 in a rectangular ring shape.

(Drawing process)

The drawing process is a process in which the contact surface of the molten steel supplied from the tundish 1 to the mold 2 with the mold 2 is solidified and the cast 3 in the solid- . The cast piece 3 pulled out of the casting mold 2 is supported by the continuous casting machine roll 4 and is conveyed to the next process while maintaining its shape.

Regarding the cross-sectional size of the mold 2 for obtaining the bulb 3, it is preferable that the inner diameter of the mold 2 is 400 mm or more in the case of the cross section perpendicular to the drawing direction, And most preferably 400 mm or more and 460 mm or less. If the cross-sectional size of the casting mold 2 is too small, the distance from the meniscus to the position where the casting mold 3 becomes completely solidified is shortened, so that the casting mold 3 (3a) There is a possibility that a special casting press-down device is required to increase the equipment cost. On the other hand, if the cross-sectional size of the casting mold 2 is excessively large, the position of the casting mold 3 in the completely solidified state exceeds the length of the continuous casting machine 10, There is a possibility that the length of the machine of the continuous casting machine 10 is extended.

The casting speed (drawing speed) of the cast steel 3 is not particularly limited, but is preferably 0.35 m / min or more and 0.65 m / min or less, and more preferably 0.40 m / min or more and 0.60 m / min or less. If the casting speed is too slow, the inside of the casting will be completely solidified until the casting 3 reaches the non-solidified down bar (horizontal roll 5) of the continuous casting machine, There is a possibility that the suppression effect of center segregation may not be obtained. In addition, when the casting speed is excessively slow, the temperature difference between the central portion of the cast steel 3 and the surface portion of the cast steel 3 becomes small in the completely solidified press down load (second pressing down step) There is a possibility that the difference in deformation resistance of the surface portion of the substrate 3 may be small. As a result, the pressure drop penetration into the center portion of the cast steel 3 due to the complete solidification and subsequent pressing is lowered, and there is a fear that the center porosity can not be sufficiently pressed. On the other hand, if the casting speed (drawing speed) of the cast steel 3 is excessively high, the position of the cast steel 3 in the fully solidified state exceeds the length of the machine of the continuous casting machine 10, There is concern that you will not be able to. In addition to this, it is impossible to carry out the press-down (second press-down process) after complete solidification, and the pressurizing effect of the center porosity may not be sufficiently obtained.

Fig. 3 shows the relationship between the pulling speed and the center segregation of the cast steel 3, which is irradiated using the cast steel 3 having a circular cross-sectional shape after drawing and having a diameter of 450 mm. In Fig. 3, the ordinate is the carbon concentration saturation diagram, and the abscissa is the casting speed (drawing speed). Here, the carbon concentration kneading degree is a value obtained by dividing the carbon concentration measurement value at the center of the cast steel 3 by the carbon concentration measurement value of the molten steel supplied from the tundish 1 to the casting mold 2. [ The carbon concentration at the center of the cast steel 3 may be obtained by, for example, chemical analysis by collecting the cut powder from the center of the cast steel 3 by using a drill having a diameter of 5 mm. As shown in Fig. 3, when the drawing speed of the cast steel 3 is 0.35 m / min or more and 0.65 m / min or less, the effect of suppressing center segregation is preferably obtained.

(First pressing down step)

After the drawing step, the first pressing step is performed so that the cast piece 3 (3a) of the uncured state (high-liquid coexistence state) drawn out from the cylindrical mold 2 at the non-solidified pressure lowering stand of the continuous casting machine 10, (First rolling down direction) using a horizontal roll (first rolling down roll) 5, as shown in Fig. Since the rolling force is concentrated on the arc surface of the cast piece 3 contacting the horizontal roll 5 by pressing the cast piece 3 (3a) in an uncoagulated state and having a circular sectional shape, It is possible to increase the degree of penetration into the center of the cast strip 3. In addition, since the deformation resistance at the center portion of the cast steel 3 in the non-solidified state is smaller than the deformation resistance at the surface portion of the cast steel 3, it is possible to increase the degree of push- In other words, the cast steel 3 can be pressed down with a good downward penetration degree by the first pressing step, and the cast steel 3 can be pressed down while both the center segregation and the central porosity are reduced and the internal fracture is prevented.

In the first pressing step, the reduction rate with respect to the cast piece 3 by each horizontal roll 5 is set to be larger than the thickness of the cast piece 3 immediately before entering the horizontal roll 5 (thickness in the first pressing direction) , And not less than 0.3% and not more than 7.0%. That is, it is preferable that the reduction rate per one pressing in the first pressing down direction in the first pressing down step is 0.3% or more and 7.0% or less. In the present embodiment, in the first pressing step, any one of a light-pressing and a pressing-down can be employed. In the present embodiment, when the casting is applied, in the region where the solidification rate at the central portion of the cast steel 3 is around 0.7, the diameter of the non-solidified portion (solid-liquid coexisting portion) It is possible to prevent the residual internal cracks by applying a positive pressure reduction. In the first pressing step, if the reduction rate of each horizontal roll 5 to the cast piece 3 is too small, there is a possibility that the effect of suppressing center segregation may not be sufficiently obtained. In addition, if the rolling reduction rate of each horizontal roll 5 to the cast steel 3 is excessively large, there is a possibility that the surface of the cast steel 3 is cracked. In order to preferably suppress the generation of internal cracks, it is preferable that the reduction ratio of each horizontal roll 5 is set to 0.3% or more and 2.2% or less when the reduction in the first reduction step is limited to a light reduction.

In addition, in the first pressing step, it is preferable that the cumulative rolling reduction by the horizontal rolls 5 to the cast piece 3 is not less than 3.6% and not more than 10%. It is preferable to reduce both the center segregation and central porosity of the cast steel 3 and the occurrence of internal cracks in the cast steel 3 when the accumulated rolling reduction by each horizontal roll 5 is 3.6% or more and 10% or less . In the continuous casting machine 10 shown in Fig. 1, six pairs of horizontal rolls 5 are used.

The cast piece 3 (3a) having an uncoagulated state (solid phase ratio of 0.3 or more and 0.8 or less in the central portion) before being provided to the first pressing step is provided in the first pressing step under the above conditions, The solid phase ratio at the central portion exceeds 0.8). In the present embodiment, in the casting [3 (3b, 3c)] in which the central portion is completely solidified and the temperature of the central portion is higher than the temperature of the surface portion in the second pressing step, And a reduction in the width direction of the cast steel (second downward direction) is alternately performed.

(Second pressing step)

(3b, 3c) which is in a completely solidified state and in which the temperature of the central portion is higher than the temperature of the surface portion in the completely solidified pressure drop zone of the continuous casting machine 10 after the first pressing down step, (First pressing down direction) using the horizontal roll (first pressing down roll) 6a and the second rolling down direction using the vertical roll (second pressing down roll) 6b Direction) by alternately performing a pressing operation. In the present embodiment, by alternately performing the pressing down from the thickness direction of the casting using the horizontal roll 6a and the pressing down from the casting width direction using the vertical roll 6b, the internal cracks 3 (3b, 3c) The center segregation and the center porosity can be reduced. In the case of the cross section perpendicular to the longitudinal direction of the cast strip 3 at the outlet (downstream side machine end) of the continuous casting machine 10, a rectangular cast piece having no corner portion , A rectangle of each circle).

Since the deformation resistance at the center portion of the cast steel 3 is smaller than the deformation resistance at the surface portion of the cast steel 3 when the temperature of the center portion of the cast steel 3 is higher than the temperature of the surface portion, It is possible to increase the push-down penetration degree. In the present embodiment, the temperature of the central portion of the cast steel 3 is preferably 150 占 폚 or higher, more preferably 200 占 폚 or higher than the temperature of the surface portion. The upper limit of the temperature at the center of the cast steel 3 is not particularly limited, but may be the liquidus temperature determined by the steel composition of the cast steel 3.

The temperature of the central portion and the surface portion of the cast steel 3 may be obtained, for example, as follows. It is not easy to obtain the temperature at the center of the cast steel 3 by actual measurement. Therefore, the temperature may be obtained by a cooling simulation (heat transfer calculation model) in which a heat conduction analysis is performed. Concretely, the manufacturing process of the molten steel temperature, the drawing rate, the cross-sectional size of the cast steel 3, the heat exchange heat of the casting 3 and the continuous casting machine 10, the heat radiation amount of the cast steel 3, Based on the conditions, the temperature of the surface portion of the cast steel 3 and the temperature of the center portion may be obtained by cooling simulation. Alternatively, the relationship between the circumferential surface temperature (surface temperature) of the cast steel 3, the temperature of the surface portion, and the temperature of the central portion in each of the above production conditions is obtained in advance by cooling simulation, The temperature of the surface portion of the cast steel 3 and the temperature of the center portion at that time in the production conditions may be inferred by measuring the peripheral surface temperature (surface temperature). In this case, the temperature of the surface portion of the cast steel 3 and the temperature of the center portion can be obtained more accurately.

Fig. 4 shows the temperature difference between the central portion and the surface portion when the rolling of the cast steel 3 to a cumulative rolling reduction of 20% after complete coagulation and the passing rate by ultrasonic inspection (UST: Ultra Sonic Test) . 4, the vertical axis indicates the acceptance rate by the ultrasonic inspection (UST) on the billet, and the horizontal axis indicates the temperature difference between the central portion and the surface portion of the cast steel 3. As shown in Fig. 4, when the temperature of the central portion of the cast steel 3 is higher than the temperature of the surface portion by 150 DEG C or more, the passing rate by the ultrasonic inspection is high, Able to know.

In the second pressing step, the reduction rate with respect to the cast piece 3 (3b) by each horizontal roll 6a is smaller than the thickness of the cast piece 3 (3b) just before entering each horizontal roll 6a Direction is not less than 1.5% and not more than 7.0%. That is, it is preferable that the reduction rate per one time of the reduction in the first downward direction is not less than 1.5% and not more than 7.0%. The reduction ratio of the cast steel 3 (3c) by each vertical roll 6b to the width of the cast steel 3 (3c) just before entering each of the vertical rolls 6b (thickness in the second downward direction) , Preferably not less than 1.5% and not more than 7.0%. That is, it is preferable that the reduction rate per one time of the reduction in the second downward direction is not less than 1.5% and not more than 7.0%. In this embodiment, in the second pressing step, as in the first pressing step, it is possible to adopt any one of a light-pressing and a pressing-down. In the second pressing step of the present embodiment, since the pressure is applied to the cast steel after the complete solidification, internal cracking is unlikely to occur even if the pressure is lowered by the large pressure. If the reduction rate with respect to the cast steel 3 (3b) by each horizontal roll 6a and the reduction rate with respect to the cast steel 3 (3c) by each vertical roll 6b are excessively small in the second pressing step, There is a possibility that the inhibitory effect of the residual central porosity may not be sufficiently obtained. In addition, if the reduction rate with respect to the cast steel 3 (3b) by each horizontal roll 6a and the reduction rate with respect to the cast steel 3 (3c) by each vertical roll 6b are excessively large, There is a fear that bulging deformation that occurs over the entire surface of the cast steel 3 occurs and cracking may occur on the surface of the cast steel 3 that is not in contact with the rolling roll. Further, in order to preferably obtain the above effect while preferably suppressing the occurrence of internal cracks, in the case of limiting the pressing down in the second pressing step to a light pressing, it is preferable to press the horizontal rolls 6a and the respective vertical rolls 6b It is preferable that the rate is 1.5% or more and 3.3% or less.

Fig. 5 shows the relationship between the cumulative rolling reduction in the second rolling down step and the passing ratio in the ultrasonic inspection after the rolling of the rolling pieces. 5, the vertical axis indicates the acceptance rate in the ultrasonic inspection (UST) after the rolling of the billet, and the horizontal axis indicates the cumulative value of the rolling reduction by each roll.

The center segregation and the central porosity of the cast steel 3 can be preferably reduced when the cumulative rolling reduction by the second pressing step is 75% or more. In the continuous casting machine 10 shown in Fig. 1, seven pairs of horizontal rolls 6a and seven pairs of vertical rolls 6b are used.

In the case where the shape of the cast piece 3 after the second pressing step is a section perpendicular to the longitudinal direction, it is preferable that the corner portion is a rounded, annular rectangular shape. The shape of the cast strip 3 after the second pressing step is rounded by the corner portion, so that generation of cracks starting from the corner portion at the time of rolling the slab is preferably suppressed.

It is preferable that the cast piece 3 after the second pressing step is a rectangular ring having a curvature radius of 5 mm or more when viewed in a section perpendicular to the longitudinal direction. When the radius of curvature of the corner portion is 5 mm or more, generation of a crack starting from the corner portion at the time of rolling the steel strip is more preferably suppressed. The upper limit of the radius of curvature of the corner portion is not particularly limited, but is preferably 50 mm or less.

The casting 3 after the second press-down process is compared with the cross-section (corresponding to the cross-sectional size of the casting 2) of the casting 3 before the first press- By area, preferably 58% or less, and more preferably 44% or less. Concretely, it is preferable that the long side of the cast piece 3 after the second pressing step is 235 mm or more and 270 mm or less. When the long side of the cast steel 3 is lowered to less than 235 mm in the continuous casting machine 10, there is a fear that surface cracks due to a decrease in the ductility of the surface portion due to a decrease in the temperature of the surface portion of the cast steel 3 . On the other hand, when the long side of the cast steel 3 exceeds 270 mm, the roll mill load at the time of rolling the steel billet becomes excessive in the method of producing crude steel, which will be described later, and a large-scale rolling roll apparatus may be required. In addition, there is a possibility that the crushing and rolling step may be omitted.

Further, in the continuous casting method according to the present embodiment, the casting 3 may be subjected to secondary cooling by cooling water after the drawing step and before the first pressing down step and as the cooling step. Regarding the secondary cooling condition, it is preferable that the secondary cooling rate is in the range of 0.10 L / kg-steel to 0.55 L / kg-steel. When the secondary cooling rate is less than 0.10 L / kg-steel, the secondary cooling rate becomes too small to maintain the cooling spray shape. On the other hand, when the secondary cooling rate is more than 0.55 L / kg-steel, the cooling strength for the cast steel 3 becomes locally excessive, and the thermal amplitude at the time of cooling and during the heat recovery becomes large, There is a fear that surface cracks may occur in the surface layer 3.

The continuous casting method according to the present embodiment is applicable as a continuous casting method for various steel types such as carbon steel or alloy steel. The cast steel 3 obtained by the continuous casting method according to the present embodiment is a cast steel having a substantially rectangular shape in cross section without a corner portion (rounded corners, rectangular rings), less central segregation and central porosity, (3) which is excellent in internal quality with suppressed cracking. Further, by the continuous casting method according to the present embodiment, the cross section perpendicular to the longitudinal direction of the cast steel 3 can be reduced to a size corresponding to the size after crushing rolling. That is, as described below, when the cast steel 3 is produced using the casting 3 obtained by the continuous casting method according to the present embodiment, the crushing and rolling step can be omitted.

In the above-described continuous casting method, as an example, the first downward pressing roll 5 (6a) for performing the downward pressing in the first downward direction is disposed horizontally with respect to the installation face 7 of the continuous casting machine 10 And the second down roll 6b for pushing down in the second downward direction is disposed perpendicular to the installation face 7 of the continuous casting machine 10. [ 5 (6a)] and the second downwardly-pushing roll 6b, as long as the first push-down direction and the second push-down direction are orthogonal to each other in the case of the section perpendicular to the longitudinal direction of the cast piece 3, In the continuous casting machine 10 is not particularly limited. However, when the conveying direction (advancing direction) of the cast strip 3 is partially curved like the continuous casting machine 10 shown in Fig. 1, the first pushing roll 5 (6a) is arranged so that its roll axis direction is parallel to the installation surface (7) of the continuous casting machine (10) and perpendicular to the conveying direction of the cast (3) It is preferable to dispose the push roll 6b perpendicularly to the mounting surface 7 of the continuous casting machine 10. [

The continuous casting method according to the present embodiment described above will be summarized below.

The continuous casting method according to the present embodiment is a continuous casting method according to the present embodiment, which comprises a drawing step of drawing a cast steel 3 in a state of high-liquid coexistence from a cylindrical mold 2 and a casting step 3) in a first downward direction which is perpendicular to the longitudinal direction of the cast piece (3), and a second pressing step of pressing the cast piece (3) in both the longitudinal direction and the first downward direction (3) in a completely solidified state and in a state in which the temperature of the central portion is higher than the temperature of the surface portion, after the first pressing down step, when the orthogonal pressing down direction is the second pressing down direction, And a second pressing down step of forming the corner portion in a rounded, annular rectangular shape when viewed in a section perpendicular to the longitudinal direction of the cast piece (3) while alternately performing the pressing in the second pressing down direction.

In the continuous casting method according to the present embodiment, the inner diameter of the casting mold 2 is preferably 400 mm or more and 600 mm or less, and the drawing speed of the casting casting 3 is 0.35 m / min or more and 0.65 m / The solidification ratio of the center portion of the cast steel (3) after the drawing process and before the first pressing process is preferably 0.3 or more and 0.8 or less, and in the first pressing down direction in the first pressing down direction Is preferably 0.3% or more and 7.0% or less, and the solidification ratio of the center portion of the cast steel (3) after the first pressing step and before the second pressing down step is more than 0.8, Further, it is preferable that the temperature at the central portion of the cast piece (3) is higher than the temperature of the surface portion by at least 150 DEG C, and in the second pressing step, It is preferable that the lowering rate is not less than 1.5% and not more than 7.0%, and furthermore, the reduction rate per one time of the downward pressing in the second downward direction is not less than 1.5% and not more than 7.0% The length of the long side is not less than 235 mm and not more than 270 mm, and the radius of curvature of the corner portion is not less than 5 mm and not more than 50 mm.

Hereinafter, a method for producing crude steel according to one embodiment of the present invention will be described.

&Lt; Production method of crude steel >

A method of producing crude steel according to the present embodiment is a continuous casting process for obtaining a cast steel having a shape of a rounded corners, a rectangular ring and a high internal quality by the continuous casting method described above, A rolling process (rolling process of steel strip) for rolling the cast steel to obtain a steel bar or a wire rod as raw steel.

As described above, in the method of manufacturing crude steel according to the present embodiment, it is possible to omit the conventionally required crushing and rolling step, and it is possible to improve the productivity. Besides, the quality of the obtained crude steel is also excellent. That is, by the above-described continuous casting method of steel, the center segregation and the center porosity can be appropriately reduced and the first and second pressing down steps are performed while appropriately preventing the internal cracking, So that the internal quality of the steel obtained by the rolling process is also excellent. Thus, the method of producing crude steel according to the present embodiment is sufficiently applicable to the production of high-quality (high-quality) crude steel.

[Example 1]

The effects of one embodiment of the present invention will be described in more detail by way of examples. However, the conditions in the embodiment are examples of conditions employed to confirm the feasibility and effect of the present invention, and the present invention is not limited to this conditional example. The present invention can adopt various conditions as long as the object of the present invention is achieved without departing from the gist of the present invention.

Table 1 below shows the cast steel grade used in the examples. The grade of steel was two levels of A and B.

Each of the steels shown in Table 1 was pulled out by using a mold having an inner diameter of 450 mm in the case of a section perpendicular to the drawing direction (drawing step). The drawn cast was cooled to a secondary cooling rate of 0.15 to 0.20 L / kg-steel as required. The casting speed (drawing speed) of the casting was 0.30 to 0.60 m / min. Under the above-mentioned injection conditions, the uncooled pressure lowering zone is in the region of 17 to 32 m in the conveying direction of the casting, with the meniscus as the reference, the area in the range of more than 32 to 45 m in the conveying direction of the casting, .

Table 2 below shows the continuous casting conditions for each of the present invention and the comparative example. Further, in the present invention, a slab press-down (first press-down process) was carried out using six pairs of horizontal rolls in the non-solidified press down zone. In addition, the slab pressure reduction (second pressure reduction step) was performed using seven pairs of horizontal rolls and seven pairs of vertical rolls at the completely solidified pressure lowering stand. That is, the press-down in the casting thickness direction (the first press-down direction) and the press-down in the cast strip width direction (the second press-down direction) were alternately performed seven times so that the cross- . In addition, as shown in Table 2, the casting speed (drawing speed) is changed for each of the present invention and each comparative example. When the casting speeds were 0.50 m / min and 0.60 m / min, it was possible to reduce by the six pairs of horizontal rolls in the above-mentioned non-solidified pressure drop zone. However, in the case of Test Nos. 6 and 8, in which the casting speed is 0.30 m / min, the casting speed is too slow, so that it is not possible to carry out the non-solidification reduction in the non-solidification /

In Table 2, Test Nos. 1 to 4 are examples. In Test Nos. 1 to 4, the cast steel having the solid phase ratio (solid phase ratio) at the central portion of 0.30 or more and 0.80 or less in the non-solidified downfalling zone was measured for the thickness of the cast steel Thickness), a reduction in the reduction rate of 0.6% or 1.6% was given by each horizontal roll. Further, in the completely solidified press-down zone, for a cast steel having a solid phase ratio of more than 0.80 at the central portion and a temperature at the center portion of the cast steel of at least 150 ° C (temperature difference between the inside and outside of the cast steel) The thickness of the cast steel (thickness in the first descending direction) is set to be 5.7%, and the width of the cast steel just before entering each of the vertical rolls (the thickness in the second descending direction ) Was applied to each of the vertical rolls at a reduction rate of 5.7%. And alternating between horizontal rolls and vertical rolls. The final shape of the cast steel was 270 mm long, and the radius of curvature of the corner was 10 mm.

Test Nos. 5 to 8 are comparative examples. In Test Nos. 5 and 7, the conditions of the secondary cooling rate and the casting speed are the same as in the present invention. However, the reduction rate of the non-solidified pressure reduction is small in comparison with the same steel type of the present invention example, and the complete solidification post-reduction is carried out only in the thickness direction of the cast steel (first downward direction) This is an example. In Test Nos. 6 and 8, the condition of the secondary cooling rate is the same as in the present invention. However, since the casting speed is too slow, uncoagulated pressure reduction is not performed in the non-solidified pressure reduction bed, and only the complete solidification is carried out in the thickness direction of the cast steel (the first pressure drop direction) ) Is an example not done.

The difference between the inside and outside temperature of the cast steel, which is the difference between the center temperature of the cast steel and the surface temperature, was measured by a calorimetric calculation model and a method of measuring the cast steel surface temperature by a contact type thermocouple.

In addition, the solidification rate at the center of the cast steel was calculated by the heat transfer calculation model using the alloy state diagram.

For each obtained cast steel, the quality of the central segregation, the central porosity and the internal cracking was evaluated. Further, crude steel was produced by rolling the steel slab using each of the obtained cast slabs, and the presence or absence of formation of Cr carbide was evaluated. Further, the obtained crude steel was subjected to a drawing process, and a quality evaluation was made with respect to the presence or absence of occurrence of a chevron crack after the drawing process.

The central segregation of the state was evaluated as follows. A cut powder was sampled from a center portion of a cross section perpendicular to the longitudinal direction of the cast steel after the second pressing step using a 5 mm drill to measure the carbon concentration value. The carbon concentration value of the molten steel sample collected from the inside of the reed during the heat casting was measured. Then, the ratio of the carbon concentration value of the flue to the carbon concentration value of the molten steel was evaluated as the carbon concentration saturation degree. The degree of carbon segregation was 1.10 or less. In Table 2, the case where the carbon concentration saturation degree is 1.10 or less is represented as 1, the case where the carbon concentration saturation degree is 1.10 or more and 1.15 or less is defined as 2, and the case where the carbon concentration saturation degree is 1.15 or more is described as 3 .

The center porosity of the cast steel was subjected to ultrasonic inspection by using the cast steel after the second press-down process, and was examined. A case in which the internal defect is 0.3 mm or less is regarded as acceptable. In Table 2, the case where the internal defect is 0.3 mm or less is denoted by 1, the case where the internal defect is more than 0.3 mm and 0.9 mm or less is denoted by 2, and the case where the internal defect is more than 0.9 mm is denoted by 3.

The internal breakage of the cast steel was evaluated as follows. The casting after the second pressing step is used to cut along the longitudinal direction of the cast steel and along the casting strip width direction perpendicular to the casting direction so as to include the core portion of the cast steel and the obtained cross section is subjected to the sulfur printing It was judged whether there was an internal breakage.

In general, the Cr carbide of crude steel is produced in the region where the concentrated grains remain in the cast steel when the degree of center segregation is high. The presence or absence of formation of Cr carbide in the crude steel was examined by observing with a microscope a section parallel to the longitudinal direction of the crude steel after the rolling of the slab. Then, it was determined that no Cr carbide was identified on this cross section.

The chevron cracks after the drawing process were subjected to a tensile test of the sample after the drawing process and were examined. Then, it was determined that the tensile fracture section does not follow the V seam.

The center segregation and central porosity were evaluated in three stages as described above. And, 1 is accepted, 2 is the level that can be used if the purpose of use is limited, and 3 is rejected.

The evaluation results are shown in Table 2. As is clear from Table 2, the cast steel of the present invention had a rating of center segregation and central porosity of 1 and a good internal quality, as compared with the cast steel of the comparative example. On the other hand, in the comparative example, the internal qualities were low as compared with the inventive examples together with the respective evaluation items. That is, it is presumed that the suppression of center segregation is insufficient and the lack of compression of central porosity is estimated. This is considered to be attributed to the shortage of the amount of reduction in the non-solidified cast steel, the decrease in the push-down penetration degree to the center of the cast steel due to the small difference in the temperature inside and outside the cast steel, and the shortage of the total solidified steel product.

Further, in the present invention, the casting size can be reduced to a size corresponding to the size after the crushing rolling at the outlet (downstream machine end) of the continuous casting machine, and the crushing rolling step at the time of producing the crude steel can be omitted. On the contrary, in the comparative example, since the complete coagulation post-pressurization from the cast strip width direction (second downward descending direction) is not applied, the cast size can not be sufficiently reduced and the casting rolling process can be omitted There was no.

&Lt; Industrial applicability >

According to the above-described aspect of the present invention, it is possible to provide a casting continuous casting method which can be applied to a wide variety of steel types used as coarse steel, capable of reducing center segregation and central porosity and preventing internal cracking of cast steel, It is possible to provide a method of producing crude steel capable of improving the productivity by omitting the crushing and rolling process. As a result, there is a high possibility of industrial use.

1: Tundish
2: Mold
3: Casting
3a: Cast steel whose center portion is in a non-solidified state
3b, 3c: Fully coagulated slabs
4: Continuous casting roll (support roll)
5: Press-down roll (horizontal roll, first press-down roll)
6: Rolling-down roll of the complete solidification depressor
6a: horizontal roll (first push-down roll)
6b: vertical roll (second push-down roll)
7: Installation face of continuous casting machine
10: Continuous casting machine

Claims (3)

A drawing step of drawing a cast product in a state of high-liquid coexistence from a cylindrical mold,
A first pressing down step of performing a pressing down in a first pressing down direction perpendicular to a longitudinal direction of the cast steel in the high-liquid coexisting state after the drawing process;
When the pressing down direction orthogonal to both the longitudinal direction and the first pressing down direction of the cast steel is defined as the second pressing down direction and the temperature in the central portion is higher than the temperature of the surface portion , The corner portion is formed into a rounded, annular rectangular shape when viewed in a section perpendicular to the longitudinal direction of the cast steel, while alternately performing the pressing down in the first and second pressing down directions , And a second pressing step. The mold according to claim 1, wherein the mold has an inner diameter of 400 mm or more and 600 mm or less,
Min and a drawing speed of 0.35 m / min or more and 0.65 m / min or less,
The solidification rate of the center portion of the cast steel after the drawing process and before the first pressing process is not less than 0.3 and not more than 0.8;
The reduction rate per one time in the first pressing down direction in the first pressing down step is not less than 0.3% and not more than 7.0%;
The solidification rate at the center portion of the casting after the first pressing down step and before the second pressing down step is more than 0.8 and the temperature at the center portion of the casting is 150 ° C or more higher than the temperature of the surface portion,
Wherein the reduction rate per one time in the first pressure reduction direction in the second pressure reduction step is not less than 1.5% and not more than 7.0%, and the reduction rate per one time in the second pressure reduction direction is not less than 1.5% and not more than 7.0% Or less,
Wherein the shape of the cross section perpendicular to the longitudinal direction of the cast steel after the second pressing down step is 235 mm or more and 270 mm or less on the long side and the radius of curvature of the corner portion is 5 mm or more and 50 mm or less. Way. A continuous casting process for obtaining the cast steel by the continuous casting method according to claim 1 or 2,
And a rolling step of rolling the cast steel after the continuous casting step.

Images