JPH0929404A - Production of thick steel plate having uniform quality in surface layer and inner part - Google Patents

Abstract

PROBLEM TO BE SOLVED: To stably produce a thick steel plate having uniform quality in the surface layer and the inner part or improved in the characteristic in the inner part of plate thickness without any defect. SOLUTION: In a molten steel 3 supplied into a mold 2 for continuous casting through an immersion nozzle 1, the molten steel fluid is controlled by impressing a static magnetic field with a magnetic field generator 5 near a meniscus part of the molten steel in the mold for continuous casting while continuously forming the solidified shell 4 of this molten steel by conducting the heat in the mold for continuous casting. Further, alloy adjusting agent is added into the molten steel 3 at the lower part of the static magnetic field to cast a slab changing the component composition from the surface layer to the inner part. By this method, e.g. an HIC resistant steel can be made to high strength without deteriorating HIC resistance and hydrogen sulfide stress corrosion crack resistance.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention makes it possible to manufacture a steel sheet having a uniform surface layer portion and an inner material at a high quality and at a low cost by devising a casting method. It relates to the field of steel sheets.

[0002]

2. Description of the Related Art In general, the relationship between the cooling rate and the strength of a thick plate during the manufacture of the thick plate is shown in FIG.
As shown in the case of steel with 1.4% Mn and Ceq = 0.29%, the tensile strength (TS) tends to increase as the cooling rate increases. Regarding this relationship, Setsuo Takagi: No. 141 ・
142nd Nishiyama Memorial Technical Lecture (Edited by Japan Iron and Steel Institute) (1992), p.
1, Omi Miyagawa: Steel Material Science for Mechanical Engineers, p.31
[Asakura Shoten], Tamura, Izumi, Isa: Steel Materials Science, p.83 [Asakura Shoten], Shinichi Amano: 15th Steel Engineering Seminar Text, Japan Iron and Steel Institute (1993), p.170, etc. It is as it is. Therefore, for example, when comparing the cooling rate of the central part of the plate thickness and the surface part when the plate thickness is 20 mm, the cooling rate is 43 ° C / sec at the surface part and about 15 ° C / sec at the central part of the plate thickness. Will greatly affect the strength of the steel sheet. That is, at such a cooling rate, as shown in Fig. 1, the surface TS is 65 kgf / mm ² and the plate thickness T is T.
As the S. can be estimated to be 55 kgf / mm ² , there is a difference in the steel sheet strength between the surface layer portion and the central portion of the steel sheet.

In order to confirm that there is a difference in the strength of the steel sheet between the surface layer portion and the central portion of the steel sheet in this manner,
We tried to measure the strength of a steel plate of about 20 mm (0.04% C, 1.35% Mn, Ceg 0.14), but it is virtually impossible to slice a steel plate of 20 mm in the thickness direction to make a test piece. Therefore, it was not possible to directly measure the strength. Therefore,
Generally, the relationship between strength and hardness is almost one-to-one as shown in FIG.
The hardness distribution of a 20 mm steel plate was measured in the plate thickness direction to estimate the strength distribution in the plate thickness direction. The result is shown in FIG. The strength index in FIG. 3 is greatly reduced in the center portion of the plate thickness, and the hardness difference ΔH _V between the surface layer portion and the center portion in the plate thickness direction is as high as 20. As a result, the estimated strength is 15 kg between the surface layer and the center in the plate thickness direction.
There will be a difference of f / mm ² . The value in Fig. 2 is H _V
Although it is up to 220, the intensity was estimated assuming that the value increased almost linearly. As described above, in the ordinary manufacturing method, it was inevitable that the surface layer portion and the central portion of the steel sheet had different strengths.

By the way, in recent years, there has been an increasing demand for steel having high strength in the field of use of thick steel plates. For example,
The HIC resistance steel plate for line pipe (hydrogen induced cracking) resistance and the like are required, the conventional X55~X60 (39~42kgf / mm ²⁾ and which was of the now almost X60 (42kgf / mm ²⁾ is the mainstream It is becoming more and more high grade X80 (56kgf / mm ² ),
Materials of about X100 (70 kgf / mm ² ) are being demanded.

[0005] Steel having only high strength can be manufactured by increasing the cooling rate, adjusting the C equivalent (Ceq), and the like. For example, as shown in FIG. 4, the C equivalent and the strength have a relationship that the higher the C equivalent, the higher the strength. However, in high-grade thick plate materials such as HIC resistant steel, the hardness H _V of the thick plate has an upper limit. The reason is,
The 78th and 79th Nishiyama Memorial Technology Course (Edited by Japan Iron and Steel Institute), p.5
8, Table 7 or PNTuttle, Mater, Performance, vol.13
(1974), No.2, p.42, the hardness H _V is 2
This is because hydrogen-induced cracking and hydrogen sulfide stress corrosion cracking will not occur by limiting the amount to 30 to 240 or less. Therefore, even if an attempt is made to obtain a high strength steel sheet by increasing the cooling rate or the C equivalent as described above, it may not be possible to sufficiently increase the hardness due to the limitation of hardness for HIC resistance.

Therefore, the inventors have noticed that even if the cooling rate or the C equivalent is simply increased, the strength and hardness of the surface layer portion and the central portion of the steel sheet are the same, and the surface layer portion of the steel sheet is not changed. If the strength can be made uniform with the center,
The present invention is conceived to produce a thick steel plate having a uniform material in the surface layer portion and the inside, considering that the strength of the steel sheet can be increased as a whole while maintaining the surface hardness above H _V ≦ 230 to 240. Therefore, we proceeded with research and development.

Up to now, regarding thick steel plates whose surface layer portion and inside are uniform, the composition, the cooling rate during rolling, the time from the start of cooling to the time of cooling, etc. have been optimized.
There has been a method of manufacturing by controlling the structure to be uniform.
The steel plate obtained by such a method has a substantially uniform hardness distribution in the plate thickness direction as shown in FIG. 5 showing the hardness distribution in the plate thickness direction. However, in reality, it is very difficult to manufacture a material having the current strength level by such a manufacturing method. Also, during cooling during rolling, the surface layer was controlled to become a soft ferrite phase, and the strength in the thickness direction was made equal by balancing the strength with the bainite phase and acicular ferrite phase inside. Although there is a method of manufacturing a steel plate, such a manufacturing method cannot be expected to improve strength. Therefore, in order to manufacture a thick steel plate whose material is uniform in the surface layer portion and inside, it is necessary to develop a new material or process.

Therefore, in the present invention, as a new process, a method for producing a thick steel plate in which the surface layer portion and the inside are made of uniform material by casting a slab in which the steel composition changes in the thickness direction during continuous casting Is proposed. The method itself for adding alloy components to the molten steel in the mold during continuous casting is already known. This method is a method in which a wire or the like made of a specific component is put into the molten steel in the mold. However, with such a method, it is difficult to stably obtain a uniform material in the surface layer portion and the inside, and it has not been applied to an actual continuous casting machine.

The reason is that the flow of molten steel in the mold is unstable, so that even if an alloy component is added, it is not uniformly dispersed in the mold. In particular, when a multi-hole nozzle was used as the dipping nozzle and the alloy components were introduced at uneven positions such as one side in the mold, a non-uniform component distribution in the width and depth directions was often generated. Also, by pouring wires etc. from the top of the mold, the surface of the molten metal is extremely disturbed, and defects such as powder entrapment occur very frequently,
As a result, there are no examples of using these technologies at the actual machine level, rather than at the experimental level.

In addition, at present, methods for casting different molten steels by using a magnetic field are disclosed in JP-A-6-304704, JP-A-6-304703, and JP-A-6-335749.
JP-A-6-344080, JP-A-6-30
4705, JP-A-6-304706, JP-A-6-304707, and the like. All these series of publications enable the production of clad steel by separating molten steel from the upper side and the lower side by a magnetic field, and use two tundish and two nozzles in one mold. A method of pouring molten steel is disclosed.

However, since these methods are aimed at producing a clad steel in which the boundary between the surface layer component and the center component is clear, it is essentially different from the object of the present invention. To do. The object of the present invention is to make the inside have a uniform strength, and it is necessary to exclude that the strength can be graded. Not only that, with such a method, it is difficult to operate in the initial stage of casting, and it is not possible to determine from which casting length the clad steel is made. In addition, since the mold has two nozzles, the molten metal surface is likely to be cooled, and depending on the position of the nozzle, the molten metal surface may not be heated and defects such as deckle may occur. Furthermore, the economical efficiency is poor because two nozzles and tundish are used. It is also very difficult to control the flow rate of molten steel during casting and the ratio of the thickness of the casting shell outside and inside the slab of the molten steel clad.

Further, in Japanese Laid-Open Patent Publication No. 3-20295, a method of separating molten steel on the upper side and the lower side by a magnetic field to enable production of clad steel is described. A method of adding a metal component with a wire has been proposed. Similarly, the method disclosed in Japanese Patent Application Laid-Open No. 3-20295 is a method for producing a clad steel in which the boundary between the surface layer component and the central component is clear, and therefore the object of the present invention. Is essentially different from. Further, in this method, since no control measures regarding molten steel flow are taken, it is not possible to stably obtain a steel sheet having uniform material for the surface layer portion and the inside, and moreover, defects such as powder entrainment easily occur. . Therefore, it is not suitable for manufacturing thick plates and the like.

Further, in JP-A-7-51801 and JP-A-7-51802, particularly, regarding a method for producing a multi-layer steel sheet in which an alloy layer is formed on the surface layer, molten steel is injected into a continuous casting mold together with gas. Disclosed is a method of producing a multi-layer steel sheet by applying a static magnetic field above the position to divide the molten steel in the mold into two parts, adding an alloy component to the molten steel above this, and making the alloy steel by levitation stirring of the injected gas. Has been done. But,
In these methods, since wire addition is performed without applying a static magnetic field on the upper surface of the mold, defects such as powder entrainment due to disturbance of the molten metal surface occur as in the method described above. Further, in this method, since the nozzle discharge port is attached downward below the part where the static magnetic field is applied, the bubbles do not have buoyancy to float and stir the molten steel, and the solidification shell remelts due to the discharge flow. There is a risk that it will occur and in the worst case break out. In the case of casting in which floating and stirring is performed by the lift-up effect of bubbles without breakout, the throughput becomes extremely small, and the cost cannot be met.

[0014]

As described above, in the past, it has not been possible to stably manufacture a thick steel plate whose material is uniform in the surface layer portion and inside. Therefore, the present invention enables stable production by a new method of casting a slab in which the steel component composition changes in the plate thickness direction during continuous casting. The purpose is to propose a manufacturing method.

[0015]

The gist of the present invention comprises:
It is as follows. The molten steel supplied to the continuous casting mold through the dipping nozzle is deheated in the continuous casting mold to continuously form a solidified shell of the molten steel, and a static magnetic field near the molten steel meniscus portion in the continuous casting mold. Is applied to control the flow of molten steel, and an alloy modifier is added to the molten steel below this static magnetic field to cast a slab whose composition changes from the surface layer to the inside. And a method for manufacturing a thick steel plate having a uniform material (first invention).

In the first invention, a method of manufacturing a thick steel plate having a uniform material for the surface layer portion and the inside is characterized in that a static magnetic field is applied to the molten steel at the position of the discharge hole of the immersion nozzle (second invention).

In the first invention or the second invention, a static magnetic field is applied to the molten steel below the discharge holes of the immersion nozzle. Third invention). In the second invention or the third invention, a method for producing a thick steel plate having uniform surface layer parts and internal parts, characterized in that casting is performed using a single-hole straight nozzle as the immersion nozzle (fourth invention).

As described above, in order to manufacture steel in which the properties in the plate thickness direction, that is, the surface portion and the central portion are made uniform by the conventional casting method, the alloy is added to the molten steel in the mold by a wire or the like. It is possible to change the compositional characteristics in the mold in the width direction of the steel sheet.However, because of the turbulence of the molten metal surface and the non-uniform flow of molten steel in the mold, after all, a steel sheet with uniform characteristics in the thickness direction is It was impossible to manufacture.
It is also difficult to perform casting with two sets of tundish and nozzle while applying a magnetic field, from the various points such as the dummy bar start method, determining the casting length of the clad steel, the difficulty of solidification shell control, etc. and the economy. Met.

Therefore, in the present invention, a substance for improving alloy and material by a wire or a minute block in the mold while controlling the molten steel flow by applying a static magnetic field in the vicinity of the molten steel meniscus in the continuous casting mold. Add. 6 (a) and 6 (b) schematically show an example of a cross section near the continuous casting mold during the continuous casting operation to which the present invention is applied.
In the figure, reference numeral 1a is an immersion nozzle, 2 is a casting mold for continuous casting, and 3 is molten steel injected into the casting mold 2 for continuous casting through the immersion nozzle 1a. On the back surface of the long side member of the continuous casting mold 2, electromagnets as the magnetic field generator 5 are arranged at the meniscus height of the molten steel 3 in the mold, and a static magnetic field is applied to the meniscus region of the molten steel 3 in the mold. Has become. This static magnetic field is preferably applied over the entire width of the slab to be cast. Further, in order to add the alloy below the molten steel meniscus, the alloy additive is charged into the molten steel by the wire 6.

Thus, when the molten steel 3 is injected into the continuous casting mold 2 through the immersion nozzle 1a to form the solidified shell 4, a static magnetic field is applied to the molten steel 3 in the mold 2, so that the wire 6 Even when the alloy is added by the above method, the disorder of the molten metal surface does not occur, and it is possible to prevent defects such as powder entrainment. Not only that, the molten steel flow in the mold is controlled, and specifically, there is a downflow at the center and a fast downflow on the short side. Under such a circumstance, since the alloy modifier is added to the molten steel in the mold, the molten steel descends at a slow flow in the center of the inside, so the concentration is high, and the short side has a high flow velocity, so the concentration is low. In the obtained slab, the component composition distribution in which the concentration of the component composition inside is higher than that on the surface can be stably obtained.
Therefore, even if there is a factor that causes a difference in strength between the surface layer portion and the central portion, such as a difference in cooling rate, it is possible to form a component composition distribution that cancels out the difference in strength. Thus, a steel sheet having uniform strength between the inside and the inside can be obtained.

As described above, the application of the static magnetic field in the vicinity of the molten steel meniscus according to the present invention not only prevents the fluctuation of the molten metal surface and the powder entrainment, but also provides a good distribution of the slab whose composition changes in the thickness direction according to the present invention. It is also important for stable casting in the situation.

A specific example of the alloy additive for making the surface layer portion and the center portion have the same strength is as follows.
i, Mn, B, V, Mo, Ni, Cu, etc. Further, as a means for introducing the alloy additive, there are a wire, a minute block, a pellet and the like. In the present invention, in order to obtain a slab whose composition changes from the surface layer portion to the central portion in a favorable distribution state, it is desirable to melt in the central portion. Therefore, for example, in the case of a wire, the thickness material, feed rate, etc. are specified in advance so that the sheath melts in the central portion,
Since the pellets and the like are introduced into the central portion, it is preferable to use a ceramic tube or the like. Regarding the position of the wire tip, in the case of the two-hole nozzle shown in FIG. 6, the structure is such that the wire is not melted at the nozzle discharge port and is sufficiently heated and melts vertically below the nozzle. Desirable for obtaining homogeneous material steel.

7 (a) and 7 (b) are sectional views showing an example of the second invention. FIG. 7 shows a case where the immersion nozzle is a single-hole straight nozzle 1b, and a static magnetic field is applied to the molten steel at the position of the discharge hole of the single-hole straight nozzle 1b by an electromagnet 7 provided on the back surface of the mold. Has become. Thus, as in the first invention, it is possible to suppress the fluctuation of the molten metal surface caused by the addition of the alloy modifier into the molten steel in the mold and the powder entrainment by applying the static magnetic field to the molten steel meniscus portion and controlling the molten steel flow. Instead, the molten steel flow becomes a diffused flow by the application of a static magnetic field to the discharge hole position, and the downward flow becomes a uniform flow. Therefore, since the alloy modifier can be injected along the downward flow of the molten steel discharged into the mold, the alloy has the effect of being melted in the molten steel and spread by diffusion. Further, when the alloy adjusting agent is introduced by a wire, the position of the tip of the wire is preferably below the nozzle outlet and the magnetic field applied to the outlet. When the dipping nozzle is a single-hole straight nozzle as shown in FIG. 7, the flow is more uniform than that of the two-hole nozzle as shown in FIG. 6, and uniform diffusion is possible. is there.

8 (a) and 8 (b) are sectional views showing an example of the third invention. In FIG. 8, the immersion nozzle is a two-hole nozzle 1
A static magnetic field is applied to the molten steel below the discharge hole of the immersion nozzle, which is shown as a, by the electromagnet 7 provided on the back surface of the mold. Thus, the static magnetic field in the meniscus portion prevents the fluctuation of the molten metal surface, and the flow of the unsolidified molten steel is suppressed by the static magnetic field in the meniscus portion and the static magnetic field below the discharge hole of the immersion nozzle. A uniform downward flow occurs below the static magnetic field. By introducing the alloy modifier into such a region of uniform downward flow, since the composition of the composition in which the central portion of the slab has a high concentration can be easily and stably obtained,
It is possible to manufacture a thick steel plate having more uniform strength between the surface layer portion and the inside.

The static magnetic field below the discharge hole of the immersion nozzle is preferably applied over the entire width of the slab to be cast, in order to obtain a uniform downward flow. Further, the shape of the immersion nozzle is not limited to the two-hole nozzle as shown in FIG. 8, but may be a single-hole straight nozzle as shown in FIG.

[0026]

BEST MODE FOR CARRYING OUT THE INVENTION In Examples 1 and 2 to be described later, the case of manufacturing HIC resistant steel among thick plates has been described, but the present invention is not limited to the manufacture of such steel, and is not limited to the surface layer portion and the inside. As long as the material is a thick steel plate, it can be applied when manufacturing other materials. In this example, only one place is used as a method of introducing the alloy modifier, but in order to achieve high speed casting and high concentration,
You can put more than one.

[0027]

【Example】

Example 1 A continuous casting operation was performed using a two-strand continuous casting apparatus. At this time, the method according to the present invention was used for one strand, and the usual casting method was applied to the other strand. The operating conditions are as follows.

Steel type C: 0.040 to 0.042 wt%, Si: 0.30 to 0.31 wt%, Mn: 1.
39 to 1.40 wt%, P: 0.003 wt% or less, S: 0.0015 wt%
Below, Al: 0.025 to 0.035 wt%, TO: 20 ppm or less Tundish molten steel temperature Tt: 1558 to 1563 ° C Continuous casting equipment 260 ton / ch in two consecutive mold shapes: thickness 220 mm, width 2200 mm vertical bending continuous casting machine: vertical part 3m immersion nozzle: 2 holes nozzle, nozzle diameter: 70mmφ, discharge hole diameter: rectangle 70mm × 80mm discharge hole downward angle: horizontal

Strand according to the present invention Magnetic flux density: 0.3 T Magnetic field application type: length 300 mm, width 2400 mm and the following two conditions 1) Static magnetic field application only on the molten metal surface 2) Static at the molten metal surface and the lower end of the mold (600 mm from the molten metal surface) Magnetic field application Addition of alloy modifier: Boron is introduced by wire so that it is located at a position of 500 mm from the meniscus.

The composition distribution in the plate thickness direction of the continuously cast slab thus obtained is shown in FIG. 10 based on the hardenability index. The composition distribution based on the quenching index is compared to the comparative example cast by a more usual method, the conforming example 1),
In 2), the concentration is high in the central part and low at both ends.

Next, the slab cast by these methods was controlled-cooled and rolled to obtain a product. The rolling conditions are as follows: the furnace is discharged at 1200 ° C., the rolling time is 90 sec, the idle time is 1100 sec, the rolling finishing temperature is 830 ° C., and the product sheet thickness is 23 mm. The TS of all the obtained products were 70 kgf / mm ² and satisfied the prescribed strength. For these products, the hardness distribution in the plate thickness direction was examined, and the results are shown in FIG. From FIG. 11, in the conformity examples 1) and 2) according to the method of the present invention, the hardness does not decrease in the central portion in the plate thickness direction as in the comparative example, and the hardness is uniform in the plate thickness direction. It is clear, in other words, it is clear that the strength is uniform in the plate thickness direction.

Example 2 Next, the shape of the immersion nozzle was changed to carry out a continuous casting operation. This operation was performed using a two-strand continuous casting facility, one strand was subjected to the method of the present invention, and the other was subjected to a conventional casting method for casting. The experimental conditions are as follows.

Steel type C: 0.039 to 0.041 wt%, Si: 0.29 to 0.31 wt%, Mn: 1.
4 to 1.41 wt%, P: 0.002 wt% or less, S: 0.0012 wt% or less Al: 0.028 to 0.038 wt%, TO: 15 ppm or less Tundish molten steel temperature Tt: 1560 to 1563 ° C Continuous casting equipment 270 ton / ch doubled Mold shape: thickness 220 mm, width 2200 mm Vertical bending continuous casting machine: vertical part 3 m Immersion nozzle 1) 2-hole nozzle, nozzle diameter: 70 mmφ, discharge hole diameter: 70 mm ×
80mm □ 2) Single hole nozzle, nozzle diameter: 70mmφ

Strand according to the present invention Magnetic flux density: 0.3 T Magnetic field application type: length 2400 mm, width 300 mm, the following two conditions 3) Static magnetic field application at the molten metal surface and the lower end of the nozzle 4) The molten metal surface and the lower end of the mold (500 mm from the molten metal surface) ) Apply static magnetic field Add alloy adjuster: Mn as a block of small amount, put into a position 800 mm below the meniscus by a ceramic tube

FIG. 12 shows the composition distribution in the plate thickness direction of the continuously cast slab thus obtained, based on the hardenability index. Composition distribution based on the quenching index, compared to the comparative example cast by a more conventional method, conforming example 3),
In 4), the concentration is high in the center and low at both ends.

Next, the slab cast by these methods was rolled by controlled cooling to obtain a product. This rolling condition is the furnace temperature 17
00 ℃, rolling time 85sec, idle time / 1000sec, finish rolling temperature 850 ℃, product thickness is 30mm. The TS of all the obtained products were 70 kgf / mm ² and satisfied the prescribed strength. The hardness distribution of these products in the plate thickness direction was examined, and the results are shown in FIG. From FIG. 13, it is clear that in the conformity examples 3) and 4) according to the present invention, the hardness is not reduced in the central portion in the plate thickness direction as in the comparative example, and the hardness is uniform in the plate thickness direction. In other words, it is clear that the strength is uniform in the plate thickness direction.

The above-mentioned products were further subjected to an HIC test to measure the area defect rate (the defect area projected by the ultrasonic flaw detection method from the front surface to the back surface of the plate to determine the total area of the front or back surface of the plate. Then, the value obtained by dividing the area of the defect was calculated. The results are summarized in Fig. 14. From this result, it is clear that the steel sheets obtained by the method of the present invention have very few defects as compared with the HIC characteristics of the steel sheets produced by the conventional methods of Examples 1 and 2.

[0038]

According to the present invention, by adding an additive while applying a static magnetic field to the meniscus portion of the molten steel in the mold, a thick steel sheet having a uniform material in the surface layer portion and the inside or in the inside of the plate thickness Can be manufactured stably and without defects. For example, in the case of HIC resistant steel, high strength can be achieved without deteriorating HIC resistance and hydrogen sulfide stress corrosion cracking resistance. Therefore, its industrial effect is great.

[Brief description of drawings]

FIG. 1 is a diagram showing a relationship between a cooling rate and a strength of a thick plate when manufacturing the thick plate.

FIG. 2 is a diagram showing a relationship between strength and hardness of a thick plate.

FIG. 3 is a diagram showing a hardness distribution of a general thick plate in a plate thickness direction.

FIG. 4 is a diagram showing a relationship between C equivalent and strength in steel.

FIG. 5 is a diagram showing a hardness distribution in a plate thickness direction for a steel plate having a uniform strength in the plate thickness direction according to a conventional method.

FIG. 6 is a schematic view showing an example of a cross section in the vicinity of a continuous casting mold during a continuous casting operation to which the present invention is applied.

FIG. 7 is a schematic view showing another example of the cross section in the vicinity of the continuous casting mold during the continuous casting operation to which the present invention is applied.

FIG. 8 is a schematic view showing another example of the cross section in the vicinity of the continuous casting mold during the continuous casting operation to which the present invention is applied.

FIG. 9 is a schematic view showing another example of the cross section in the vicinity of the continuous casting mold during the continuous casting operation to which the present invention is applied.

FIG. 10 is a view showing a composition distribution in a plate thickness direction of a continuously cast slab based on a hardenability index.

FIG. 11 is a diagram showing a hardness distribution in a plate thickness direction of a thick steel plate in an example.

FIG. 12 is a diagram showing a composition distribution in a plate thickness direction of a continuously cast slab based on a hardenability index.

FIG. 13 is a diagram showing a hardness distribution in the plate thickness direction of a thick steel plate in an example.

FIG. 14 is a diagram showing the results of an HIC test of thick steel plates in Examples.

[Explanation of symbols]

 1a, 1b Immersion nozzle 2 Continuous casting mold 3 Molten steel 4 Solidification shell 5 Magnetic field generator 6 Wire

Continuation of front page (51) Int.Cl. ⁶ Identification code Office reference number FI technical display location B22D 11/04 311 B22D 11/04 311J

Claims (4)

[Claims] 1. A molten steel meniscus in the continuous casting mold while continuously removing the molten steel supplied to the continuous casting mold through an immersion nozzle in the continuous casting mold to continuously form a solidified shell of the molten steel. Characterized by applying a static magnetic field near the part to control the molten steel flow, and adding an alloy modifier to the molten steel below this static magnetic field to cast a slab whose composition changes from the surface layer to the inside. A method of manufacturing a thick steel plate in which the material of the surface layer and the inside is uniform. 2. The method for producing a thick steel plate according to claim 1, wherein a static magnetic field is applied to the molten steel at the position of the discharge hole of the immersion nozzle, wherein the surface layer portion and the inside are made of uniform material. 3. The method for producing a thick steel plate according to claim 1, wherein a static magnetic field is applied to the molten steel below the discharge holes of the immersion nozzle, wherein the surface layer portion and the inside are made of uniform material. . 4. The method for producing a thick steel plate according to claim 2, wherein the immersion is performed by using a single-hole straight nozzle as the immersion nozzle, and the material of the surface layer portion and the inside is uniform.