KR20140140802A - Methods for manufacturing coil - Google Patents

Abstract

A coil manufacturing method is disclosed. According to an embodiment of the present invention, the method includes the steps of taking out ingot steel through continuous casting mold; measuring heat flux of a long side unit and a short side unit in the mold; calculating a difference in the heat flux from the long side unit and the short side unit; and controlling a provision condition of cooling water in at least one from the long side unit and the short side unit by comparing the difference in heat flux with a predetermined value.

Description

[0001] METHODS FOR MANUFACTURING COIL [0002]

The present invention relates to a coil manufacturing method.

The molten iron produced in the blast furnace is subjected to a steelmaking process. The steelmaking process produces molten steel through pre-treatment of molten iron, conversion steelmaking, and secondary refining. Molten steel that has undergone steelmaking process is formed into a steel semi-finished product through continuous casting process. In the continuous casting process, molten steel continuously injected into the performance mold is cooled in the performance mold, thereby forming a steel semi-finished product such as a slab. The slab is rolled and formed into a final product such as a rolling coil.

The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 10-2012-0074370 (2012.07.06, Continuous Casting Method and Apparatus).

Embodiments of the present invention are directed to a coil manufacturing method for controlling a supply condition of cooling water supplied to a performance mold in accordance with a heat flux deviation in a performance mold.

According to one embodiment of the present invention, there is provided a method of casting molten steel, Measuring a heat flux of the long side portion and a heat flux of the short side portion of the mold; Calculating a heat flux deviation from a difference between a heat flux of the long side portion and a heat flux of the short side portion; And comparing the heat flux deviation with a predetermined value to control a supply condition of cooling water in at least one of the long side portion and the short side portion.

Wherein the step of controlling the supply condition of the cooling water includes the step of supplying the cooling water in at least one of the long side portion and the short side portion until the heat flux deviation becomes the predetermined value or less when the heat flux deviation exceeds the predetermined value And changing the condition.

The step of changing the supply condition of the cooling water may include a step of changing the supply amount of the cooling water in at least one of the long side portion and the short side portion.

In the step of changing the supply amount of the cooling water, the supply amount of the cooling water at the long side portion may be gradually decreased by 100 l / min, and the supply amount of the cooling water at the short side portion may be increased by 100 l / min .

Wherein the step of changing the supply condition of the cooling water further comprises the step of changing the supply temperature of the cooling water in at least one of the long side and the short side and the step of changing the supply temperature of the cooling water in at least one of the long side and the short side If the supply quantity of the cooling water in at least one of the long side and the short side is equal to or more than the maximum supply quantity of the cooling water when the supply quantity is less than the maximum supply quantity of the cooling water, The step of changing the supply temperature of the cooling water can be performed.

The step of changing the supply temperature of the cooling water may reduce the supply temperature of the cooling water at the short side step by 1 DEG C / min step by step.

The molten steel has a carbon content of 0.02 parts by weight to 0.09 parts by weight based on 100 parts by weight of the total amount, and the predetermined value may be 0.1 MW / m ² .

According to the embodiments of the present invention, it is possible to predict the corner defect crack index of the slab formed through the performance mold by comparing the heat flux deviation in the performance mold with a preset value, and accordingly, By controlling the conditions and the cooling water supply conditions of the short sides, it is possible to reduce the corner defect crack index of the slab to within the allowable range.

1 is a flow chart illustrating a method of manufacturing a coil according to an embodiment of the present invention;
2 is a view showing a coil manufacturing apparatus.
Fig. 3 is a view showing a performance mold cut in a horizontal plane. Fig.
Fig. 4 is a vertical view of the performance mold. Fig.
FIG. 5 is a graph schematically showing a change in the edge portion crack defect index of a rolling coil according to a heat flux deviation; FIG.
6 is a view showing a corner crack defect of a slab in a case where a heat flux deviation exceeds 0.1 MW / m ² ;
7 is a view showing a slab in a case where the heat flux deviation is 0.1 MW / m ² or less;

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Hereinafter, various embodiments of a coil manufacturing method according to the present invention will be described in detail with reference to the accompanying drawings. In the following description, the same or corresponding components are denoted by the same reference numerals, The description will be omitted.

1 is a flowchart showing a method of manufacturing a coil according to an embodiment of the present invention.

Referring to FIG. 1, a method of manufacturing a coil according to an exemplary embodiment of the present invention includes steps of (S100) tapping molten steel into a performance mold, measuring a heat flux of a long side portion and a short side portion of a performance mold (S200) (S300) of calculating a heat flux deviation between the long side and the short side, and controlling the supply condition of the cooling water supplied to the performance mold (S400).

First, molten steel produced through a steelmaking process is introduced into a performance mold (S100).

FIG. 2 is a view showing a coil manufacturing apparatus, FIG. 3 is a drawing showing a performance mold cut to a horizontal plane, and FIG. 4 is a drawing showing a performance mold cut to a vertical plane.

2, the molten steel 10 is temporarily stored in the tundish 100 and supplied to the performance mold 200 through the immersion nozzle.

Referring to FIG. 3, a casting space having a rectangular horizontal cross section is formed in the performance mold 200 so as to correspond to a cross section of a slab, which is a semi-manufactured steel product, in which the molten steel 10 solidifies and is formed. That is, the playing mold 200 includes a relatively long side portion 210 and a relatively short side portion 220. Cooling water for cooling the molten steel (10) is supplied to the long side portion (210) and the short side portion (220) through the cooling water supply lines (211, 221). As a result, the solidifying shell 11 is formed from the portion adjacent to the performance mold 200 of the molten steel 10.

4, it can be observed that as the molten steel 10 passes down the performance mold 200, the thickness of the solidifying shell 11 gradually increases. As a result, the molten steel 10 can be formed into a slab.

The mold powder is supplied to the molten steel 10 for the purpose of lubrication with the performance mold 200. The mold powder forms a mold powder layer 13 between the solidification shell 11 and the performance mold 200. [

Next, the heat flux of the long side portion and the heat flux of the short side portion are respectively measured in the performance mold (S200).

Heat flux means the amount of heat transferred per unit time through a unit area, and a unit of W / m ² is used. In the present embodiment, the heat flux means the amount of heat transferred from the molten steel 10 to the cooling water supply lines 211 and 221 per unit time through the unit area of the playing mold 200. The heat flux can be measured by an average heat flux divided by the total area of the playing mold 200 from the molten steel 10 to the cooling water supply lines 211 and 221 through the entire area of the playing mold 200. That is, the heat flux of the long side portion 210 is a value obtained by dividing the heat amount moving from the molten steel 10 to the cooling water supply line 211 per unit time by the inner side area of the long side portion 210, The heat flux is a value obtained by dividing the heat capacity of the molten steel 10 by the amount of heat transferred to the cooling water supply line 221 by the inner area of the short side portion 220 per unit time. The amount of heat transferred from the molten steel 10 to the cooling water supply lines 211 and 221 per unit time can be indirectly measured from the difference between the cooling water supply amount in the cooling water supply lines 211 and 221 and the cooling water supply temperature and the discharge temperature .

Next, the heat flux deviation is calculated from the difference between the heat flux at the long side and the heat flux at the short side (S300).

The heat flux deviation of the long side portion 210 is always the difference between the heat flux of the long side portion 210 and the heat flux of the short side portion 220. However, The heat flux of the long side portion 210 can be calculated by subtracting the heat flux of the short side portion 220 from the heat flux of the long side portion 210. [ The occurrence of the heat flux deviation means that the molten steel in contact with the long side portion 210 and the molten steel in contact with the short side portion 220 are cooled at different speeds. When the molten steel contacting the long side portion 210 and the molten steel contacting the short side portion 220 are cooled at different speeds, they are formed adjacent to the solidification shell and the short side portion 220 formed adjacent to the long side portion 210 The solidification shells may be formed to have different thicknesses. That is, when the heat flux of the long side portion 210 is greater than the heat flux of the short side portion 220, the solidified shell formed adjacent to the long side portion 210 is formed as a solidified portion formed adjacent to the short side portion 220, It can be formed thicker than the shell. As a result, in the solidification shell formed adjacent to the long side portion 210, a large contractile force is formed as compared with the solidification shell formed adjacent to the short side portion 220, so that the corner portion of the slab, which is formed through the performance mold 200, A crack defect may occur. Crack defects at the corner of the slab may cause cracks at the edge of the rolled coil where the slab is formed through the rolling rollers. Therefore, the heat flux deviation in the performance mold 200 may be an element related to whether or not an edge crack defect occurs in the rolled coil as a final product. Therefore, it is possible to predict whether or not an edge crack defect occurs in the rolled coil have.

Since the long side portion 210 has a longer length than the short side portion 220, the long side portion 210 has a longer length than that of the solidification shell formed adjacent to the short side portion 220 in the solidification shell formed adjacent to the long side portion 210 A large length deformation occurs. As a result, the mold powder layer formed in the space between the cross-section 220 and the adjacent solidifying shell is formed thicker than the mold powder layer formed in the space between the long side 210 and the solidifying shell adjacent thereto . The mold powder layer adjacent to the short side 220 formed to be relatively thick may act as a resistance to obstruct heat transfer through the short side 220 to lower the heat flux of the short side 220. Therefore, the thickness difference of the mold powder layer formed at the long side portion 210 and the short side portion 220 may cause the heat flux difference between the long side portion 210 and the short side portion 220 to be caused.

Next, the heat flux deviation is compared with the predetermined value, and the supply condition of the cooling water in at least one of the long side portion and the short side portion is controlled (S400).

The step of controlling the supply condition of the cooling water (S400) may compare the heat flux deviation with a predetermined value of 0.1 MW / m ² (S410) and branch to the two steps S420 and 430 according to the result .

5 is a graph schematically showing a change in the edge portion crack defect index of the rolling coil due to the heat flux deviation.

Referring to FIG. 5, the heat flux deviation is proportional to the edge crack crack index of the rolling coil, and when the heat flux deviation is 0.1 MW / m ² or less, the edge crack crack index of the rolling coil becomes the critical defect index, 10. ≪ / RTI > That is, when the heat flux deviation is controlled to be 0.1 MW / m ² or less, the edge crack defect index of the rolled coil can be reduced to the limit defect index. Therefore, the predetermined value to be used as a criterion for determining whether the rolling coil is defective may be 0.1 MW / m < ² >. Here, the molten steel is a low carbon steel having a carbon content of 0.02 parts by weight to 0.09 parts by weight based on 100 parts by weight of the total amount. The critical defect index means a reference value for judging whether or not the rolled coil is defective and can be determined according to the quality control standard of the rolling coil.

If the heat flux deviation is 0.1 MW / m ² or less, the continuous casting process of the slab is performed while maintaining the supply condition of the cooling water (S420). That is, the supply amount and the supply temperature of the cooling water supplied through the cooling water supply lines 211 and 221 are kept constant.

If the deviation exceeds the heat flux 0.1MW / m ^2, and the heat flux variations that change the condition of the cooling water supply in at least one of, a long side portion and the short side portions until less than 0.1MW / m ² (S430).

The step of changing the supply condition of the cooling water (S430) may compare the supply amount of the cooling water with the maximum supply amount of the cooling water (S431), and branch to two steps S432 and S433 described later.

There is a maximum supply amount which is the maximum upper limit in the supply amount of the cooling water supplied through the cooling water supply lines 211 and 221. [ Therefore, it is effective to increase the supply amount of the cooling water more efficiently than to lower the supply temperature of the cooling water. However, if the supply amount of the cooling water reaches the maximum supply amount, the supply amount of the cooling water can not be further increased. The supply temperature must be lowered. The maximum amount of cooling water to be supplied can be determined according to the pump capacity, the piping size, and the like.

If the supply amount of the cooling water in at least one of the long side portion and the short side portion is less than the maximum supply amount, the supply amount of the cooling water in at least one of the long side portion and the short side portion is changed (S432).

The heat flux of the long side portion 210 is formed to be larger than the heat flux of the short side portion 220, as described above. Therefore, in order to reduce the heat flux difference between the long side portion 210 and the short side portion 220, the supply amount of the cooling water is reduced in the cooling water supply line 211 passing through the long side portion 210, It is possible to increase the supply amount of the cooling water in the cooling water supply line 221 passing through.

The supply quantity of cooling water can be decreased or increased stepwise by 100 l / min. If the supply amount of cooling water is rapidly changed in order to lower the heat flux deviation to 0.1 MW / m ² or less, discontinuity may be caused along the casting direction, resulting in a defect in the final product, the rolling coil. As a result of comparing the heat flux difference with the predetermined value by measuring the heat flux at the long side portion 210 and the short side portion 220 again after decreasing or increasing the supply amount of the cooling water by 100 l / min, the heat flux deviation is 0.1 MW / m ² , the step S420 of performing continuous casting while maintaining the supply condition of the cooling water is performed. If the heat flux deviation is still higher than 0.1 MW / m < ² >, the step S430 of changing the supply condition of the cooling water is performed again.

If the supply amount of the cooling water in at least one of the long side portion and the short side portion is not less than the maximum supply amount, the supply temperature of the cooling water in at least one of the long side portion and the short side portion is changed (S433).

The heat flux of the long side portion 210 is formed to be larger than the heat flux of the short side portion 220, as described above. Therefore, in order to reduce the heat flux deviation between the long side portion 210 and the short side portion 220, the supply temperature of the cooling water can be reduced in the cooling water supply line 221 passing through the short side portion 220.

The supply temperature of the cooling water can be decreased stepwise by 1 ° C / min. If the supply temperature of the cooling water is rapidly changed in order to lower the heat flux deviation to 0.1 MW / m ² or less, discontinuity may be given along the casting direction, resulting in a defect in the final product, the rolling coil. A feed temperature of the coolant decreases after 1 ℃ / min again to measure the heat flux in the long side portion 210 and short side portion 220 compares the heat flux variations and the predetermined value a result, the heat flux variation is 0.1MW / m ² or less (S420) of continuously casting while maintaining the supply condition of the cooling water, and changing the supply condition of the cooling water (S430) when the heat flux deviation still exceeds 0.1MW / m < ^{2 &} gt ;.

6 is a heat flux variation is a view showing a corner portion of the slab cracking defects in the case of excess of 0.1MW / m ^2, Figure 7 is a view showing the slab in the case where the heat flux variation less than 0.1MW / m ^2.

6, when the heat flux deviation exceeds 0.1 MW / m ² , the solidification shell 11 is formed to have a thickness greater than that of the short side portion 220 at the long side portion 210, It can be confirmed that a crack defect 21 is generated at the corner of FIG.

7, when the heat flux deviation is controlled to 0.1 MW / m ² or less, the solidifying shell 11 is formed to have a similar thickness at the long side portion 210 and the short side portion 220, It is confirmed that a crack defect does not occur at the corner portion.

In Figs. 6 and 7, the arrow indicates the contracting force generated in the solidifying shell. In Fig. 6, it can be seen that the magnitude of the contraction force is different between the long side and the short side.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

10: molten steel
11: Solidification shell
13: mold powder layer
100: Tundish
200: mold
210: long side
211: Cooling water supply line
220: Short side
221: Cooling water supply line

Claims (7)

Pouring molten steel into a performance mold;
Measuring a heat flux of the long side portion and a heat flux of the short side portion of the mold;
Calculating a heat flux deviation from a difference between a heat flux of the long side portion and a heat flux of the short side portion; And
And comparing the heat flux deviation with a predetermined value to control a supply condition of cooling water in at least one of the long side portion and the short side portion.
The method according to claim 1,
Wherein the step of controlling the supply condition of the cooling water comprises:
And changing the supply condition of the cooling water in at least one of the long side portion and the short side portion until the heat flux deviation becomes equal to or less than a predetermined value if the heat flux deviation exceeds a predetermined value .
3. The method of claim 2,
Wherein the step of changing the supply condition of the cooling water comprises:
And changing the supply amount of the cooling water in at least one of the long side portion and the short side portion.
The method of claim 3,
Wherein the step of changing the supply amount of the cooling water comprises:
Wherein the supply amount of the cooling water at the long side portion is gradually decreased by 100 l / min, and the supply amount of the cooling water at the short side portion is increased step by step at a rate of 100 l / min.
The method of claim 3,
Wherein the step of changing the supply condition of the cooling water comprises:
Further comprising changing the supply temperature of the cooling water in at least one of the long side portion and the short side portion,
The step of changing the supply amount of the cooling water when at least one of the long side portion and the short side portion is supplied with the cooling water is less than the maximum supply amount of the cooling water, Wherein the step of changing the supply temperature of the cooling water is performed when the supply amount of the cooling water is equal to or more than the maximum supply amount of the cooling water.
6. The method of claim 5,
Wherein the step of changing the supply temperature of the cooling water comprises:
Wherein the supply temperature of the cooling water in the short side portion is stepwise decreased by 1 占 폚 / min.
The method according to claim 1,
Wherein the molten steel has a carbon content of 0.02 parts by weight to 0.09 parts by weight based on 100 parts by weight of the total amount, and the predetermined value is 0.1 MW / m ² .

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