KR20200070796A - Nozzle and manufacturing apparatus for metal material - Google Patents

Abstract

The present invention relates to a nozzle and an apparatus for manufacturing a metal material and to a metal material apparatus for cooling a melt supplied to a cooling roll which rotates to manufacture a metal material, which comprises a nozzle including: a nozzle body provided at the upper part of the cooling roll to extend in the direction that the cooling roll extends; and an internal hollow unit penetrating the nozzle body to supply the melt to the cooling roll and formed in the direction that the nozzle body extends, wherein the internal hollow unit has at least some portions formed with different widths with respect to the length direction of the internal hollow unit. The present invention can inhibit thickness deviation in the width direction of the metal material and manufacture the metal material with an overall uniform thickness, thereby enhancing quality and reliability of the metal material.

Description

Nozzle and manufacturing apparatus for metal material

The present invention relates to a nozzle and a metal material manufacturing apparatus, and more particularly, to a nozzle and a metal material manufacturing apparatus capable of manufacturing a metal material having a uniform thickness.

In general, an amorphous alloy (hereinafter referred to as an amorphous alloy) is manufactured by rapidly cooling molten steel in a molten state. Accordingly, in the process of cooling the molten steel, it does not form crystalline and solidifies into a glassy state, that is, an amorphous state.

Amorphous metals have a glassy structure similar to a liquid phase that does not have crystallinity by arranging atoms irregularly, unlike ordinary crystalline metals. Therefore, the amorphous metal does not have a grain boundary, which is a characteristic of the crystalline metal, and there is no crystalline imperfection such as dislocation. In addition, the amorphous metal has characteristics such as superior softness, toughness, corrosion resistance, and superconductivity compared to a crystalline metal having the same composition.

Methods for manufacturing the amorphous metal include die casting/permanent mold casting and melt spinning, among which the melt spinning method is mainly used.

The melt spinning method is also called PFC (Planar Flow Casting), and is a method of manufacturing an amorphous material such as a ribbon or a strip by supplying a melt to a cooling roll rotating at a high speed and rapidly cooling and solidifying it, such as a metal material. When manufacturing a metal material in this way, one of the factors influencing the quality of the metal material is the flow of air generated by rotation of the cooling roll.

This causes the air in the atmosphere to flow into the cooling roll rotating at high speed to oxidize the melt or to destabilize the behavior of the melt accumulated on the cooling roll, that is, the puddle. When the behavior of the puddle becomes unstable due to the flow of air, vibration occurs in the puddle, and thus, a deviation occurs in the amount of melt attached to the cooling roll, and accordingly, there is a problem in that quality is deteriorated due to a large thickness variation of the metal material.

To solve this problem, various methods of controlling the behavior of the puddle during casting have been proposed. Accordingly, the thickness variation in the longitudinal direction of the metal material was greatly reduced. However, there is a problem that the thickness variation in the width direction of the metal material is still large.

KR 1525189 B KR 2013-0077484 A

The present invention provides a method for manufacturing a nozzle and a metal material that can produce a metal material having a uniform thickness.

The present invention provides a nozzle and a metal material manufacturing apparatus that can improve the product quality and productivity.

A nozzle according to an embodiment of the present invention includes a nozzle body extending in one direction; And an inner portion formed through the nozzle body so as to extend along a direction in which the nozzle body extends. The containing portion may have at least some different widths in a longitudinal direction in which the inner portion extends. .

The width of the inner hole in the middle of the longitudinal direction of the inner hole may be formed larger than the width of the inner hole at the edge of the inner hole.

The nozzle body includes a refractory material, and in at least a portion between the edge of the pneumatic portion and the middle of the pneumatic portion, the pneumatic portion has a width greater than or equal to a length that is increased by thermal expansion of the refractory material than the width of the pitting portion at the edge. It can be formed to have.

The width of the inner portion may be formed to gradually increase from the edge of the inner portion to the middle of the inner portion.

A metal material manufacturing apparatus according to an embodiment of the present invention is a metal material device for manufacturing a metal material by cooling a melt supplied to a rotating cooling roll, extending along a direction in which the cooling roll extends on top of the cooling roll It includes a nozzle body provided so as to include a nozzle including an inner portion formed along a direction in which the nozzle body extends and penetrates the nozzle body to supply a melt to the cooling roll, wherein the inner portion is the inner portion At least some of the lengths may have different widths.

The inner portion may be formed in a slit shape having a length and width, and the length of the inner portion may be larger than the width of the inner portion.

The width of the inner hole in the middle in the longitudinal direction of the inner hole may be formed larger than the width of the inner hole at the edge of the inner hole.

The nozzle includes a refractory material, and at the temperature of the melt, at least a portion between the edge of the pitting portion and the middle of the pitting portion, the pitting portion increases with thermal expansion of the refractory material over a width at the edge of the pitting portion. It may be formed to have a greater width than the length.

The inner portion may be formed to have the largest width in the middle of the inner portion in the longitudinal direction of the inner portion.

The width of the inner portion may be formed to gradually increase from the edge of the inner portion to the middle of the inner portion.

When the width of the inner portion at the edge of the inner portion is 1, the width of the inner portion in the middle in the longitudinal direction of the inner portion may be 1.2 to 1.4 times.

The nozzle body is disposed in the longitudinal direction of the cooling roll so as to form the inner hole therein, and includes long sides facing each other and short sides disposed at both ends of the long sides and facing each other, wherein the long sides are at least part of the inner surface. It may include a concave groove recessed to the outside of the long side.

The nozzle body is disposed in the longitudinal direction of the cooling roll so as to form the inner hole therein, and includes long sides facing each other, short sides disposed at both ends of the long sides, and facing each other, wherein the long sides are the long sides on the inner surface. It may include an inclined surface toward the outside.

According to the embodiment of the present invention, the thickness of the metal material can be uniformly formed. In particular, the thickness in the width direction of the metal material can be uniformly formed. That is, it is possible to uniformly supply the melt in the longitudinal direction of the cooling roll by suppressing a phenomenon in which the width of the inner hole of the nozzle decreases due to thermal expansion of the nozzle body generated by casting by changing the shape of the inner hole of the nozzle. Therefore, it is possible to suppress the occurrence of thickness variations in the width direction of the metal material, and to manufacture a metal material having a uniform thickness as a whole, thereby improving the quality and reliability of the metal material.

In addition, since the nozzle does not need to be replaced due to a change in the width of the inner hole, the service life of the nozzle can be extended, thereby reducing the cost of nozzle replacement.

1 is a view schematically showing a cross-sectional structure of a typical metal material manufacturing apparatus.
FIG. 2 is an enlarged view showing main structures of the metal material manufacturing apparatus shown in FIG. 1.
Figure 3 is a bottom view of the nozzle for showing the shape of the inner hole of the nozzle applied to a typical metal material manufacturing apparatus.
Figure 4 is a bottom view of the nozzle applied to the metal material manufacturing apparatus according to an embodiment of the present invention.
5 is a bottom view of the nozzle showing a modified example of the inner hole.
6 is a graph showing the thickness variation in the width direction of the metal material according to the width of the inner hole in the middle in the longitudinal direction of the nozzle inner hole.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and the scope of the invention to those skilled in the art is completely It is provided to inform you.

Before describing the present invention, a general metal material manufacturing apparatus will be described. The metal material manufacturing apparatus is for manufacturing an amorphous product in which a molten material is rapidly cooled and solidified in a glassy state before it forms crystalline. The amorphous product manufactured by the metal material manufacturing apparatus may include metal materials such as ribbons and strips manufactured to have a thickness of about 15 to 40 μm and a width of about 30 to 250 mm.

1 is a view schematically showing a cross-sectional structure of a typical metal material manufacturing apparatus, FIG. 2 is an enlarged view showing a main structure of the metal material manufacturing apparatus shown in FIG. 1, and FIG. 3 is a general metal material manufacturing apparatus. It is a bottom view of the nozzle for showing the shape of the inner hole of the applied nozzle.

Referring to FIG. 1, the metal material manufacturing apparatus includes a container 100 that provides a space for accommodating a melt therein, and a nozzle 110 provided at a lower portion of the container 100 to discharge the melt, It may include a cooling roll 120 spaced apart from the lower portion of the nozzle 110 so as to be rotatable and solidify the melt to produce a metal material. Here, the melt may include molten steel.

The container 100 may be formed in a hollow shape in which the upper part is opened so that a melt can be charged therein. In addition, an outlet 102 (see FIG. 2) capable of discharging the melt may be formed at the bottom of the container 100, for example, at the bottom.

The cooling roll 120 may be provided below the container 100 to be spaced apart from the container 100. The cooling roll 120 may be formed in a cylindrical shape extending in one direction. At this time, the cooling roll 120 may have a length greater than at least the width of the metal material to be manufactured. The cooling roll 120 may have an outer circumferential surface facing the container 100 so that a melt is supplied to the outer circumferential surface, and may be disposed in parallel with the nozzle 110. Hereinafter, a direction in which the cooling roll 120 extends from the cooling roll 120 is referred to as a longitudinal direction of the cooling roll 120. And in the direction in which the cooling roll 120 extends, that is, in a direction crossing the longitudinal direction of the cooling roll 120, the rotation direction of the cooling roll 120 is called forward with respect to the rotation direction of the cooling roll 120, and vice versa. The direction is called rear.

The cooling roll 120 may have a flow path capable of moving the cooling medium therein, and the cooling roll 120 may maintain a relatively low temperature by the cooling medium. And the cooling roll 120 may be provided to be rotatable at high speed. At this time, the cooling roll 120 may rotate at a rate of about 90 to 110 km per hour. Accordingly, the melt is attached to the surface of the rotating cooling roll 120 and is rapidly cooled to be made of a metal material having a thin thickness such as a ribbon or a strip.

The nozzle 110 includes a bore portion 114 formed on a lower portion of the container 100, that is, a nozzle body 112 provided on a bottom surface and a nozzle body 112 communicating with an outlet 102 of the container 100. It can contain.

The nozzle body 112 may be provided to extend in the direction in which the cooling roll 120 extends, that is, in the longitudinal direction of the cooling roll 120. The nozzle body 112 is connected to the lower portion of the container 100 so as to be spaced apart from the cooling roll 120, and can form a space where the melt can be discharged between the nozzle body 112 and the cooling roll 120. have. In addition, the inner hole 114 penetrates the nozzle body 112 and may be formed along a direction in which the nozzle body 112 extends. The inner hole 114 may be formed in a slit shape having a length, width and height. At this time, the length of the inner hole 114 may be formed in a size similar to or equal to the width of the metal material to be manufactured. In addition, the width of the inner hole 114 may be formed to be much smaller than the length of the inner hole 114, and may be changed according to the thickness of the metal material to be manufactured. The inner hole 114 may be disposed in parallel with the cooling roll 120 to supply the melt in the longitudinal direction of the cooling roll 120 to the cooling roll 120. Hereinafter, the direction corresponding to the longitudinal direction of the cooling roll 120 or the width direction of the metal material in the inner hole 114 is referred to as the longitudinal direction of the inner hole 114, and the direction of rotation of the cooling roll 120 or the metal material The direction corresponding to the longitudinal direction is referred to as the width direction of the inner hole 114. Through this configuration, the nozzle 110 may supply melt to a space formed between the nozzle body 112 and the cooling roll 120.

The melt supplied to the cooling roll 120 may form a melt pool, aka a puddle, by interfacial tension. The puddle may be shaped by flow due to the self-viscosity of the melt and interfacial tension between the nozzle 110 and the cooling roll 120. Here, the flow due to the viscosity of the melt is determined by the temperature of the melt and the rotation speed of the cooling roll 120. At this time, since the gap between the nozzle 110 and the cooling roll 120 is very small, the stability of the behavior of the puddle and the length of the puddle can be determined by the interfacial tension of the melt and air. Puddle between the nozzle 110 and the cooling roll 120 should be formed to have a predetermined length in the front and rear of the direction of rotation of the cooling roll 120 based on the inner hole 112, a metal material such as a ribbon or strip It can be manufactured stably.

Meanwhile, the thickness of the metal material is affected by the flow of the puddle. Accordingly, various methods of controlling the flow of the puddle in order to uniformly form the thickness of the metal material have been proposed. Although the flow of the puddle is controlled in order to uniformly form the thickness of the metal material, thickness variation in the width direction of the metal material is still occurring. Such a phenomenon may occur for various reasons, and one of them may include thermal deformation of the nozzle 110 due to high temperature molten steel and continuous contact when manufacturing a metal material.

The nozzle 110 has high temperature strength and is formed of refractory materials such as SiAlON, BN, ZrO ₂ and MgO, which have low wettability with a melt. The nozzle 110 is formed using a refractory material having good high-temperature strength, but when it comes into contact with high-temperature molten steel, a thermal deformation, for example, thermal expansion occurs.

In addition, the metal material is manufactured to have a thickness of about 15 to 40㎛, and a width of about 30 to 250mm, the inner hole 114 of the nozzle 110 to supply the melt in the longitudinal direction of the cooling roll 120 is It may be formed to have a length similar to the width of the metal material. In addition, the width of the inner hole 114 may be formed to have a width greater than the thickness of the metal material, for example, about 300 to 700 μm. In this way, the inner portion 114 may be formed to have a very long length compared to the width.

For this reason, when the nozzle 110 is thermally deformed, the edge region of the inner hole 114 is supported by the nozzle body 112 so that the width change amount of the inner hole 114 is not large. However, as it goes to the middle of the inner hole 114, the amount of change in the width of the inner hole 114 increases.

FIG. 3(a) shows the state of the nozzle 110 before manufacturing the metal material, and FIG. 3(b) shows that the molten material is supplied through the nozzle 110, that is, during the manufacturing of the metal material, or After manufacturing, the state of the nozzle 110 is shown. Hereinafter, the width of the inner hole at the edge in the longitudinal direction of the inner hole 114 is called the edge width, and the width of the inner hole at the middle in the longitudinal direction of the inner hole 114 is called the middle width. At this time, the middle of the inner hole 114 may mean a point located at the same distance from both edges of the inner hole 114, that is, the center in the longitudinal direction of the inner hole 114.

Referring to (a) of FIG. 3, the inner hole 114 may be manufactured such that the edge width W _S0 and the middle width W _CO have the same size (W _CO =W _S0 ). However, in the process of manufacturing a metal material, if the nozzle body 112 comes into contact with a hot melt, it may be heated by the melt. Accordingly, the nozzle body 112 is thermally expanded, thereby reducing the width of the inner hole 114. At this time, as shown in Figure 3 (b), the width of the inner hole 114 is reduced as a whole along the longitudinal direction of the inner hole 114. In particular, as the width decreases from the edge to the middle in the longitudinal direction of the inner hole 114 increases, the intermediate width W _C1 decreases much more than the edge width W _S1 (W _C1 <W _S1 ). In addition, the edge width W _S1 of the inner hole 114 after casting may have a size similar to the edge width W _S0 before casting (W _S0 ≒W _S1 ).

When the width of the inner hole 114 decreases, the amount of melt discharged through the inner hole 114 decreases. In particular, the amount of melt discharged in the middle of the inner portion 114, the width of the inner portion 114 is reduced the most, the largest decrease. Accordingly, a difference occurs in the amount of melt discharged from the edge region of the inner hole 114 and the intermediate region of the inner hole 114. This affects the thickness of the metal material in the width direction, and the metal material produced therein has a thickness variation in the width direction.

Accordingly, in the embodiment of the present invention, the shape of the inner hole is changed so that the melt can be uniformly discharged in the longitudinal direction of the inner hole even if the nozzle is thermally deformed during casting. In particular, the width of the inner portion can be compensated for by decreasing the width of the inner portion of the inner portion of the inner portion of the inner portion where the thermal deformation occurs most frequently during casting. Therefore, it is possible to manufacture a metal material having a uniform thickness by reducing the thickness variation in the width direction of the metal material.

Figure 4 is a bottom view of the nozzle applied to the metal material manufacturing apparatus according to an embodiment of the present invention, Figure 5 is a bottom view of the nozzle showing a modified example of the inner hole.

Referring to Figure 4 (a), the metal material manufacturing apparatus according to an embodiment of the present invention, the nozzle body 202 provided on the upper portion of the cooling roll 120, along the longitudinal direction of the cooling roll 120 The nozzle 200 includes a nozzle 200 including an inner portion 204 formed through the nozzle body 202 to supply a melt, and the inner portions 204 are at least partially in relation to the longitudinal direction of the inner portion 204. It can be formed to have a different width. In particular, the bore portion 204 is the width of the _bore portion in the middle of the bore portion 204 greater than the width of the _bore portion, for example, the edge width W _{S0 at the} edge of the bore portion with respect to the longitudinal direction of the cooling roll 120, For example, it may be formed to have an intermediate width W _C2 (W _S0 <W _C0 ).

The nozzle body 202 may include a pair of long sides arranged in the longitudinal direction of the cooling roll 120 and facing each other, and a pair of short sides arranged in a direction crossing the long sides at both ends of the long sides and facing each other. have. At this time, the long side and the short side may be formed by dividing each other, or may be formed as one structure connected to each other. Through this configuration, the nozzle body 202 may be formed with an inner portion 204 extending in the longitudinal direction of the cooling roll 120.

The nozzle body 202 may be made of at least one refractory material among SiAlON, ZrO ₂ and MgO. Each of these refractories may have a different coefficient of thermal expansion, and may have an amount of thermal expansion corresponding to the coefficient of thermal expansion. For example, in the case of BN, it may have a thermal expansion coefficient of 0.6×10 ⁻⁶ /K to 3.5×10 ⁻⁶ /K depending on the crystal phase. When the thermal expansion coefficient of BN is 3.5×10 ⁻⁶ /K, when the temperature of the melt is 1400° C., a thermal expansion amount of about 0.0049% may be exhibited. In other words, during the casting of the metal material, the nozzle 200 for supplying the melt to the cooling roll 120 is heated by the hot melt to cause thermal expansion. At this time, the inner side of the nozzle body 202 directly in contact with the melt, that is, the inside of the nozzle body 202 because the temperature difference occurs on the inner side of the inner portion 204 and the outer side of the nozzle body 202 that does not directly contact the melt And the amount of thermal expansion on the outside may be different. The amount of thermal expansion referred to herein may mean the amount of thermal expansion inside the nozzle body 202 that is in direct contact with the melt.

When casting starts, the nozzle body 202 is heated while the melt moves through the inner hole 204, thereby causing the nozzle body 202 to thermally expand. Accordingly, the width of the bore portion 204 formed inside the nozzle body 202 may be reduced to at least a degree corresponding to the amount of thermal expansion determined according to the thermal expansion coefficient of the refractory material forming the nozzle body 202. In other words, the width of the bore 204 can be reduced to the extent that the nozzle body 202 is extended by thermal expansion. At this time, since the long side of the nozzle body 202 forming the longitudinal direction of the bore portion 204 is formed in a pair, the amount by which the width of the bore portion 204 decreases is substantially the length of the nozzle body 202 extended by thermal expansion It can be about twice as large.

Therefore, the inner portion 204 is at least partially between the edge of the inner portion 204 and the middle of the inner portion 204 according to the amount of thermal expansion determined according to the thermal expansion coefficient of the refractory material at the temperature of the melt rather than the edge width W _S0 . It may be formed to have a medium width (W _C2 ) greater than or equal to twice the length of the elongation.

On the other hand, the width of the bore portion 204 does not change to the same size in the longitudinal direction of the bore portion 204, so that the amount of change increases from the edge of the bore portion 204 to the middle in the longitudinal direction of the bore portion 204 do. At this time, since the edge of the inner hole 204 is supported by the nozzle body 202, the edge width of the inner hole 204 is reduced to the extent of thermal expansion of the refractory. However, as the distance from the edge of the inner portion 204 increases, that is, toward the middle of the inner portion 204, the amount of decrease in the width of the inner portion 204 gradually increases, and in general, the middle width of the inner portion 204 is the largest. Will decrease.

Accordingly, the inner portion 204 may be formed to have the largest width in the middle of the inner portion 204 in the longitudinal direction of the inner portion 204. For example, the intermediate width W _C2 of the inner hole 204 may be formed to be 1.2 to 1.4 times or less when the edge width W _S0 of the inner hole 204 is 1. This may be changed depending on the type of refractory material forming the nozzle body 202. When the intermediate width W _C2 of the inner portion 204 is too small, there is a problem in that it is difficult to compensate for the reduction in the middle width of the inner portion 204 due to thermal expansion of the nozzle body 202. The metal material thus manufactured may have a thickness variation in the width direction that is greater than that of the edge region, and thus may have a large thickness variation in the width direction. On the other hand, if the intermediate width W _C2 of the inner hole 204 is too large, the nozzle body 202 thermally expands, so that the intermediate width of the inner hole 204 decreases, but the width is too large than the edge width of the inner hole 204 Can have The manufactured metal material may have a thickness variation in the width direction that is greater than that of the edge region, and thus may have a large thickness variation in the width direction. In addition, as a large amount of melt is discharged through the intermediate region of the bore portion 204, the flow of the puddle may be affected, thereby causing a thickness variation of the metal material.

FIG. 4B is a view showing a change in width of the inner hole 204 during or after casting. When the nozzle body 202 is thermally expanded by the hot melt, the width of the inner hole 204 is reduced than when it was first processed. At this time, the intermediate width W _C3 of the inner hole 204 is reduced from the initial intermediate width W _C2 (W _C2 >W _C3 ). However, the intermediate width (W _C3 ) of the inner hole 204 is formed in a size similar to the edge width (W _S0 , W _S1 ) (W _C3 ≒W _S1 ), and the inner hole 204 has a constant width along the longitudinal direction. Have it.

The nozzle body 202 may be formed to have various shapes capable of forming the intermediate width of the inner hole 204 in the longitudinal direction of the inner hole 204 larger than the edge width.

The nozzle body 202 forming the inner hole 204, that is, the long side may include a concave groove recessed outwardly of the nozzle body 202 over the entire inner surface as shown in FIG. At this time, the long side may be formed in a form in which the edge of the inner portion 204 and the middle of the inner portion 204 are curvedly connected.

5 shows various modified examples of the nozzle body 202.

5 (a), the long side of the nozzle body 202 may be formed to include an inclined surface toward the outside of the nozzle body 202 on the inner surface. That is, the long side may be formed in a form in which the edges and the middle of the inner hole 204 are connected in a straight line.

And referring to Figure 5 (b) and Figure 5 (c), the long side of the nozzle body 202 may include a concave groove that is recessed to the outside of the nozzle body 202 on at least a portion of the inner surface. At this time, the concave groove may be formed over a predetermined area including the middle in the longitudinal direction of the inner hole 204. The concave groove may be formed in a square shape as shown in FIG. 5(b), or may be formed to have a curved surface as shown in FIG. 5(c).

Then, between the concave groove and the edge of the inner hole 204 is formed to have the same width as the edge width of the inner hole 204, or to have a width greater than the length of the refractory due to thermal expansion than the edge width of the inner hole 204 It can also form.

Further, although not shown, a plurality of concave grooves may be formed in the longitudinal direction of the inner hole 204. At this time, the concave groove formed in the intermediate region in the longitudinal direction of the plurality of concave grooves may be formed to have the deepest depth.

Hereinafter, an example of an experiment for verifying a thickness variation in a width direction of a metal material manufactured using a metal material manufacturing apparatus according to an embodiment of the present invention will be described.

6 is a graph showing the thickness variation in the width direction of the metal material according to the width of the inner hole in the middle in the longitudinal direction of the nozzle inner hole.

For the experiment, a plurality of nozzles having intermediate widths of the inner holes as shown in Table 1 below were manufactured. At this time, the nozzles were manufactured using BN.

Edge width of inner hole (㎛) Middle width of inner hole (㎛) Metallic
Manufacturing status Comparison example 500 500 Bad Example 1
500 550 Good Example 2 600 Very good Example 3 700 Very good Example 4 750 Great

Referring to Table 1, the nozzle of Comparative Example 1 was manufactured to have an intermediate width of the same size as the edge width of the inner hole. And the nozzles of Examples 1 to 5 were manufactured to have an intermediate width greater than the edge width.

A metal material having a target thickness of 25 μm was manufactured using the nozzles thus manufactured, and the thickness of the metal material was measured. At this time, the thickness of the metal material was measured at a plurality of points in the width direction of the metal material, respectively. And the difference between the measured thickness of the metal material and the target thickness is calculated and is shown in FIG. 6.

Referring to FIG. 6, in the case of the comparative example in which the middle width of the inner hole is the same as the edge width of the inner hole, the thickness variation of the metal material tends to increase from the edge toward the middle in the width direction of the metal material. At this time, although the thickness variation of the edge region of the metal material is within ±2 μm, the thickness variation in the middle region of the metal material is shown to exceed −6 μm. This may mean that the thickness of the intermediate region in the width direction of the metal material is much thinner than the edge region. In addition, it was determined that the manufacturing condition of the metal material was very poor because the thickness of the intermediate region of the metal material was too thin.

On the other hand, in the case of Examples 1 to 4 in which the intermediate width was formed larger than the edge width, it can be seen that the thickness variation of the metal material was smaller than the thickness variation of the metal material produced by the comparative example.

In particular, in the case of Examples 2 and 3 in which the intermediate width of the inner portion is formed to be 1.2 to 1.4 times larger than the edge width of the inner portion, the thickness variation of the produced metal material is calculated within ±2 μm along the width direction of the metal material. It was judged that the manufacturing condition of the metal material was very excellent. And the thickness of the middle region of the metal material is thicker than that of the comparative example, and the deviation from the thickness of the edge region of the metal material is significantly reduced. This is because as the nozzle body thermally expands, the width of the inner hole is formed constant in the longitudinal direction of the inner hole, so that the melt is constantly supplied in the longitudinal direction of the cooling roll.

On the other hand, in the case of Example 1 in which the intermediate width of the inner hole was slightly increased compared to the comparative example, the thickness variation of the metal material was decreased than the thickness variation of the metal material produced by the comparative example, and thus it was determined that the manufacturing condition is good. However, the thickness variation of the metal material in the middle region in the width direction of the metal material exceeds 2 μm.

Further, in the case of Example 4 in which the intermediate width of the inner hole was formed to exceed 1.4 times the edge width of the inner hole, the variation in thickness of the produced metal material showed a similar tendency to Examples 2 and 3, and the production of the metal material It was judged that the condition was excellent. This may mean that as the nozzle body is thermally expanded, the width of the inner hole is formed constant in the longitudinal direction of the inner hole, so that the melt is constantly supplied in the longitudinal direction of the cooling roll. However, in some regions in the width direction of the metal material, the thickness variation of the metal material is outside 2 μm at this time, but it does not deviate to such an extent that significantly affects the quality of the metal material. Here, it is presumed that the reason for the variation in the thickness of the metal material outside the set range is that the intermediate width of the inner portion is formed somewhat larger, and a relatively large amount of melt is supplied to the cooling roll, thereby affecting the flow of the puddle.

Through this, if the width of the inner hole is appropriately changed in the longitudinal direction of the inner hole, the width of the inner hole can be kept constant even if the nozzle body thermally expands due to thermal shock. Therefore, it is possible to uniformly supply the melt in the longitudinal direction of the cooling roll, thereby manufacturing a metal material having a uniform thickness in the width direction.

As described above, the present invention has been described with reference to the above-described embodiments and the accompanying drawings, but the present invention is not limited thereto and is limited by the claims below. Therefore, it will be appreciated by those of ordinary skill in the art that the present invention can be variously modified and modified without departing from the technical spirit of the claims below.

100: container 110, 200: nozzle
112, 202: nozzle body 114, 204, bore
120: cooling roll

Claims (13)

A nozzle body extending in one direction; And
It includes; an inner portion formed through the nozzle body to extend along the direction in which the nozzle body extends;
The inner hole is a nozzle having a different width at least partly with respect to the longitudinal direction in which the inner hole extends. The method according to claim 1,
In the middle of the longitudinal direction of the inner hole, the width of the inner hole is greater than the width of the inner hole at the edge of the inner hole. The method according to claim 2,
The nozzle body includes a refractory material,
In at least a portion between the edge of the bore and the middle of the bore, the bore is formed to have a width greater than or equal to a length that increases with thermal expansion of the refractory than the width of the bore at the edge. The method according to any one of claims 1 to 3,
The width of the inner hole is a nozzle formed to gradually increase from the edge of the inner portion toward the middle of the inner portion. A metal material device for manufacturing a metal material by cooling a melt supplied to a rotating cooling roll,
A nozzle body provided to extend along a direction in which the cooling roll extends on an upper portion of the cooling roll, and an inner portion passing through the nozzle body to supply a melt to the cooling roll and formed along a direction in which the nozzle body extends It includes a nozzle comprising a,
The inner portion is at least a portion of the longitudinal direction of the inner portion of the metal material manufacturing apparatus having a different width. The method according to claim 5,
The inner portion is formed in a slit shape having a length and width,
The length of the inner portion is larger than the width of the inner portion of the metal material manufacturing apparatus. The method according to claim 6,
A metal material manufacturing apparatus in which the width of the inner hole in the middle in the longitudinal direction of the inner hole is formed larger than the width of the inner hole at the edge of the inner hole. The method according to claim 7,
The nozzle includes a refractory material,
At the temperature of the melt, at least in part between the edge of the inner portion and the middle of the inner portion, the inner portion is formed to have a width greater than a length that increases with thermal expansion of the refractory material than the width at the edge of the inner portion. Metal material manufacturing equipment. The method according to claim 8,
The inner hole is a metal material manufacturing apparatus formed to have the largest width in the middle of the inner hole in the longitudinal direction of the inner hole. The method according to claim 9,
The metal material manufacturing apparatus is formed so that the width of the inner hole gradually increases from the edge of the inner hole to the middle of the inner hole. The method according to claim 10,
When the width of the inner hole is 1 at the edge of the inner hole,
A metal material manufacturing apparatus in which the width of the inner hole in the middle of the longitudinal direction is 1.2 to 1.4 times. The method according to any one of claims 4 to 11,
The nozzle body includes long sides disposed in the longitudinal direction of the cooling roll so as to form the inner hole therein and facing each other, and short sides disposed at both ends of the long sides and facing each other,
The long side is a metal material manufacturing apparatus including a concave groove recessed to the outside of the long side on at least a portion of the inner surface. The method according to any one of claims 4 to 11,
The nozzle body includes long sides disposed in the longitudinal direction of the cooling roll so as to form the inner hole therein and facing each other, and short sides disposed at both ends of the long sides and facing each other,
The long side is a metal material manufacturing apparatus including an inclined surface toward the outside of the long side on the inner surface.

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