KR100518314B1 - Apparatus for cooling billet mold of emc - Google Patents

Abstract

The present invention relates to a cooling device for an electromagnetic continuous casting billet mold, the object of which is to uniformly cool the electromagnetic continuous casting billet mold, in which a slit must exist in the mold, and to reduce the rigidity of the mold, It is to provide a cooling function.

Therefore, in order to achieve the above object, the present invention provides a slit 20 in which a magnetic field penetrates into a slab, and is formed in the mold 30 between the slits 20 of the mold 30 for electromagnetic continuous casting machine. A plurality of main passage portions 40 formed, cooling water inlet portion 50 formed in the lower portion of the mold 30 so that the lower portion of each of the main passage portion 40 is integrally communicated with the inlet portion 50 On the upper side of the main passage portion 40 is provided with a cooling water discharge portion 60 is formed in each of the mold 30 so as to communicate individually,

Cooling water formed in the lower portion of the mold 130 so that the plurality of main passage portion 140 formed in the interior of the mold 130 between the slits 120 and the lower portion of each of the main passage portion 140 is integrally communicated with each other. Cooling water discharge unit 160 and the cooling water discharge unit 160 formed on each of the mold 130 so that the main passage 140 is individually communicated to the inlet 150, the upper side of the inlet 150, and Cooling apparatus of the electromagnetic continuous casting billet mold having a shielding tube 180 having a magnetic field shielding function is connected to the discharge end 170 installed below the mold 130 through the outer edge of the mold magnetic field coil 110 in 160 To provide.

Description

Billet Mold Cooling System for Electromagnetic Continuous Casting {APPARATUS FOR COOLING BILLET MOLD OF EMC}

The present invention relates to a cooling apparatus for cooling a billet mold for electromagnetic continuous casting (EMC), and more particularly, to cooling the mold without interfering with a slit (SLIT) of the mold surface for penetration of the coil magnetic field during electromagnetic casting. The present invention relates to a cooling device for a billet mold for continuous electromagnetic casting.

In general, the casting process is to produce a liquid metal in a solid state, for example, the molten steel of the liquid state is cast through ladles, tundish, mold, etc. in the casting factory, and the solidification begins to pass through the mold to be cooled. This is to cast the cast in a solid state (in the solid state), in this case continuous casting is accompanied by repeated vibration of the mold, the cast cast is subjected to the same surface defects (OSILLATION MARK) Is generated.

Therefore, in order to eliminate the surface defects of the cast steel as described above, a separate post-process is required after the present casting, and in order to eliminate the surface defects of the cast steel, the continuous casting using the electromagnetic force, that is, the study on the electromagnetic continuous casting is made come.

On the other hand, when using a high frequency current in the electromagnetic continuous casting as described above, the mold must be formed with a slit (SLIT) to pass the electromagnetic.

However, during continuous casting, in particular during continuous casting of the billet, the cooling tube of the mold was performed during continuous casting of the billet (BILLET) by installing a cooling tube in which a cooling water flows inside the mold. In the case of electromagnetic continuous casting using electromagnetic force to remove the surface defects of the cast steel, a slit must be formed in the mold. Therefore, when the cooling is performed in the tubular cooling structure, a problem occurs that high-pressure cooling water penetrates into the mold along the slit. For this reason, the billet mold for electromagnetic continuous casting requires a cooling structure in which cooling water flows while avoiding such slits.

SUMMARY OF THE INVENTION An object of the present invention is to provide a cooling apparatus for an electromagnetic continuous casting billet mold having a sufficient cooling function while uniformly cooling cooling of an electromagnetic continuous casting billet mold in which a slit must be present in a mold and reducing the rigidity of the mold. Is in providing.

As a technical configuration for achieving the above object, the present invention, the electromagnetic continuous caster mold including a plurality of slits integrally formed in the mold so that the magnetic field of the electromagnetic coil installed in the outer mold penetrates into the mold. A plurality of main passage portion formed in the mold and located between the slits,

Cooling water inlet formed in the lower portion of the mold so that the lower portion of each main passage unit, and

It is provided with a cooling water discharge portion formed in each of the mold so that the main passage portion to the upper side of the inlet,

By providing the cooling device for the electromagnetic continuous casting billet mold configured to perform the cooling of the electromagnetic continuous casting mold as the cooling water flowing through the inlet, the main passage portion, and the discharge portion.

In addition, another aspect of the present invention, in the mold for electromagnetic continuous casting machine including a plurality of slits integrally formed in the mold so that the magnetic field of the electromagnetic coil installed in the permeate into the mold into the mold, the inside of the mold A plurality of main passage portions formed between the slits and positioned between the slits,

Cooling water inlet is formed in the lower portion of the mold so that the lower portion of each of the main passage portion,

Cooling water discharge portion formed in each of the upper portion of the mold so that the main passage through the upper portion of the inlet, and

The shielding pipe having a magnetic field shielding function is connected to the discharge end installed at the lower side of the mold through the mold magnetic field coil from the cooling water discharge unit,

By providing a cooling apparatus of the billet mold for electromagnetic continuous casting, characterized in that the cooling water flows through the main passage portion, the inlet portion and the discharge portion and the shielding pipe.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a first embodiment of a cooling device for an electromagnetic continuous casting billet mold according to the present invention, Figure 2 is a schematic structural diagram showing a first embodiment of a cooling device for an electromagnetic continuous casting billet mold according to the present invention. .

1 and 2 show a first embodiment of the cooling device 1 of the billet mold for electromagnetic continuous casting according to the present invention, in which the magnetic field of the electromagnetic coil 10 largely penetrates the cast steel. The main passage portion 40 is formed between the slits 20 arranged in the vertical direction of the mold 30 so as to be formed inside the mold 30, and the lower portion of each of the main passage portions 40 is integrally formed. Cooling water inlet 50 formed in the mold 30 so as to pass through, and the cooling water discharge portion 60 is formed in the mold 30 so that the main passage portion 40 is individually communicated to the upper side of the inlet 50 Divided by)

In addition, the slit 20 is integrally formed in the vertical direction along the four sides of the mold 30, the electromagnetic coil 10 for applying an electromagnetic force to the slab on the upper side of the mold 30 is the mold ( 30 is fixed in a form that integrally wraps, and a plurality of clamps 32 are fixed to the outer and outer directions of the mold 30.

Meanwhile, the lower portion of the mold 30 is located between the slits 20 so that the plurality of main passage portions 40 formed in the mold 30 and the lower portions of the main passage portions 40 are integrally communicated with each other. The mold may be formed through the coolant inlet part 50 formed therein and the coolant outlet part 60 respectively formed in the mold 30 so that the main passage part 40 separately communicates with the upper part of the inlet part 50. High pressure coolant flows for cooling.

At this time, the partition wall portion 42 is installed in each of the main passage portions 40 formed in the mold 30 between the slits 20 so as to increase the cooling efficiency by providing a reverse U-shaped flow of cooling water. do.

That is, the inner wall of the mold 30 is excavated to form the main passage part 40, and then the partition wall part 42 is installed, and then the cover of the excavated part of the mold 30 is attached to the cooling water as described above. It is to enable the flow of.

In addition, the cooling water inlet 50 is formed at each side of the mold 30, that is, at the center of the lower side of each side part, so that the supply pipe 52 is connected to each other, and through each of the main passages 40. Discharge pipes 62 are respectively connected to discharge portions 60 formed alternately adjacent to each side of the mold 30.

Therefore, the coolant flowing at a time through the inlet part 50 below the mold 30 flows up from the inlet part 50 to each main passage part 40 while flowing upward from the bottom of the mold 30 and then partition wall part. The upper part of the mold 42 is discharged again through the discharge part 60 and the discharge pipe 62 at the lower side of the mold 30, and the cooling of the low mold 30 is performed by the flow of such coolant repeatedly.

In this case, the reason why the cooling water flows from the bottom up is that, when pores are generated in the cooling water, the pores try to flow from the bottom up, and when the cooling water flows down from the top, the generated pores are not easily discharged.

Accordingly, according to the first cooling device 1 of the billet mold for electromagnetic continuous casting according to the present invention, it has a U-shaped cooling water flow to improve the cooling rate of the mold 30, while the main passage formed in the mold 30. Supplying and discharging is made along the portion 40, the more uniform cooling of the mold 30 is performed, which is to increase the cooling function without lowering the rigidity of the mold.

Next, Figure 3 is a perspective view showing a second embodiment of the cooling device of the electromagnetic continuous casting billet mold, Figure 4 is an internal structural view showing a second embodiment of the cooling device of the electromagnetic continuous casting billet mold. .

That is, the cooling device 100 of the second embodiment of the electromagnetic continuous casting billet mold of the present invention is located between the slit 120 and a plurality of main passage portion 140 formed inside the mold 130 and The cooling water inlet 150 is formed in the lower portion of the mold 130 so that the lower portions of the main passages 140 are integrally communicated with the main passages 140. Cooling water discharge unit 160 formed on each of the mold 130 so as to pass through, and the discharge end 170 provided below the mold 130 through the outer edge of the mold magnetic field coil 110 in the cooling water discharge unit 160 Can be connected to the shielded tube 180 having a magnetic shielding function can be divided.

In addition, the basic configuration of the slit 120 and the mold 130 is the same as the configuration of the first embodiment, the same as the configuration of the main passage portion 140 formed in the mold 130, the operation description thereof will be omitted.

On the other hand, the cooling device 100 according to the second embodiment of the present invention also forms a cooling water inlet 150 in the lower portion of the mold 130 so that the lower portion of the main passage portion 140 is integrally connected to each of the main passage portions ( 140 is formed to enable separate cooling water flow.

At this time, in the first and second embodiments, after forming the inlet portion 50, 150 to be integrally connected to the lower portion in the malt 30, 130, the main passage portion 40, 140 through the individual The reason why it is formed so that the incoming coolant should be initially introduced through one side of the molds 30 and 130 at a time is uniformly supplied to each of the main passage portions 40 and 140, so that the mold, It is to be able to cool more uniformly.

On the other hand, the coolant flowing upward from the bottom of the mold through the main passage portion 140 in the mold 130 is discharged through the discharge portion 160 formed on the upper portion of each of the main passage portion 140, wherein the discharge portion ( Each of the shielding pipes 180, that is, the discharge end 170 installed on each side of the lower side of the mold 130 to the outside of the electromagnetic coil 110 surrounding the mold 130 in the discharge unit 160, is provided. The shield pipe 180 is connected to the.

Therefore, the cooling water flows inside the shielding tube 180 as well as the shielding effect of the electromagnetic coil 110.

As a result, substantially cooling water flows along each shielding pipe 180 of the inlet 150, the main passage 140, and the outlet 160 through the supply pipe 152 connected to the inlet 150. Although the cooling system 100 of the second embodiment of the present invention has a complicated piping structure, the cooling device 100 may increase the cooling efficiency of the mold 30 by acting as a shield at the same time as the cooling operation of the mold 30.

On the other hand, through the inlet pipe 152 and the inlet 150, the main passage 140 and the discharge unit 160 and the shielding pipe 180 connected to it, and at the same time the discharge end of the shielding end 180 is collected Cooling water flow is made through the 170 and the discharge pipe 162 connected thereto.

Next, in FIG. 5, another embodiment of the cooling device 100 of the billet mold for electromagnetic continuous casting according to the second embodiment of the present invention, that is, the shield pipe 180 does not extend downward from the upper part of the mold and extends in the horizontal direction to form a mold ( 130) It is characterized in that it is connected to the cooling tube 190 installed on the outside, in this second embodiment can be used for the cooling tube 190 installed on the outside of the conventional continuous casting mold, the entire mold cooling apparatus The structure is extremely simple, reducing the manufacturing and installation costs.

Accordingly, the present invention, the first and second cooling device (1) 100, the cooling properties of the mold 30, 130 while avoiding interference with the slit 20, 120 affecting the electromagnetic force applied to the cast steel Improved cooling is achieved evenly, the mold can maintain a sufficient cooling function.

Thus, according to the cooling device of the electromagnetic continuous casting billet mold of the present invention, the cooling of the electromagnetic continuous casting billet mold, which must have a slit in the mold, is uniform, and the rigidity of the mold is reduced, and the cooling function is provided sufficiently. It is an excellent effect.

While the invention has been shown and described with respect to specific embodiments thereof, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit or scope of the invention as set forth in the claims below. I would like to know that those who have knowledge of this can easily know.

1 is a perspective view showing a first embodiment of a cooling apparatus of an electromagnetic continuous casting billet mold according to the present invention

Figure 2 is a schematic structural diagram showing a first embodiment of a cooling apparatus of the present invention billet mold for continuous casting

Figure 3 is a perspective view showing a second embodiment of the present invention the cooling device of the billet mold for electromagnetic continuous casting

Figure 4 is an internal structural view showing a second embodiment of the cooling device of the present invention continuous casting billet mold

5 is a schematic view showing another discharge structure in the second embodiment of the present invention, the cooling device of the billet mold for electromagnetic continuous casting

Explanation of symbols on the main parts of the drawings

1,100, .... Mold chiller 10,110 .... Electromagnetic coil

20,120 .... Slit 30,130 .... Mold

40,140 .... main passage 42 .... bulkhead

50,150 .... inlet 52,152 .... supply line

60,160 .... outlet 62,162 .... outlet

170 .... discharge stage 172 .... discharge line

180 .... shielded tube

Claims (6)

In the mold 30 for electromagnetic continuous casting machine comprising a plurality of slits 20 integrally formed in the mold so that the magnetic field of the electromagnetic coil 10 installed on the outside penetrates into the mold into the mold, A plurality of main passage parts 40 formed in the mold 30 and positioned between the slits 120; and Cooling water inlet 50 is formed in the lower portion of the mold 30 so that the lower portion of each of the main passage 40 in one piece; And, And a cooling water discharge part 60 formed in each of the molds 30 so that the main passage part 40 passes through the inlet part 50 separately. The electromagnetic continuous casting billet mold, characterized in that configured to perform the cooling of the electromagnetic continuous casting mold 30 as the cooling water flowing through the inlet 50, the main passage portion 40 and the discharge portion (60). Chiller According to claim 1, wherein each of the main passage portion 40 formed in the mold 30 between each of the slits 20 to partition the partition wall portion 42 is installed to increase the cooling efficiency by flowing the coolant in double Cooling apparatus for electromagnetic continuous casting billet mold, characterized in that further provided According to claim 1, wherein the cooling water inlet 50 is formed on each side of the mold 30, the inlet 50 is connected to the supply pipe 52 for supplying the cooling water, Each of the cooling water discharge parts 60 are alternately adjacent to each side of the mold, and the discharge pipes 62 for discharging the cooling water to the outside are connected to each other. In the mold 130 for electromagnetic continuous casting machine including a plurality of slits 120 are integrally formed through the mold so that the magnetic field of the electromagnetic coil 110 installed on the outside penetrates into the mold. A plurality of main passage parts 140 formed in the mold 130 and positioned between the slits 120; and Cooling water inlet 150 is formed in the lower portion of the mold 130 so that the lower portion of each of the main passage 140, and, Cooling water discharge unit 160 formed on the mold 130, respectively, so that the main passage 140 through the inlet portion 150, respectively; and, And a shielding tube 180 connected to the discharge end 170 installed below the mold 130 through an outer portion of the mold magnetic field coil 110 in the cooling water discharge unit 160 and having a magnetic shielding function. Cooling apparatus of the billet mold for electromagnetic continuous casting, characterized in that the cooling water flows through the main passage 140, inlet 150, outlet 160 and shielding pipe 180 The method of claim 4, wherein the cooling water inlet 150 is formed on each side of the mold 30, the inlet 150 is connected to the supply pipe 152 for supplying cold water, Cooling apparatus of the electromagnetic continuous casting billet mold, characterized in that the discharge pipe 172 for discharging the cooling water passed through each shielding pipe 180 integrally at each of the cooling water discharge end 170. The apparatus of claim 4, wherein the shielding tube 180 is connected to the cooling tube 190 horizontally on the upper portion of the mold 130 to discharge the cooling water.